als – -Translation – Keybot Dictionary

  Pressemitteilung | Helm...  

Show textShow cached sourceOpen source URL	Fischer als Arbeitgeber
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	FISCHER als werkgever
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	FISCHER kui tööandja
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	FISCHER kaip darbdavys
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	FISCHER jako pracodawca
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	Вакансии в FISCHER
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	Bir işveren olarak FISCHER
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	FISCHER kā darba devējs

  Industrielle Messtechni...  

Show textShow cached sourceOpen source URL	Durch ihre sehr gute Beständigkeit gegenüber hohen Temperaturen und chemischen Substanzen eignen sich Emailschichten hervorragend als Korrosionsschutz für Kessel und Behälter in der chemischen und pharmazeutischen Industrie.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	Because it is impervious to high temperatures and chemically reactive substances, vitreous enamel makes an excellent anti-corrosion barrier for the boilers and tanks used in the chemical and pharmaceutical industries. But this protection is only guaranteed if the coating is 100% continuous and has no pores, cracks, or other defects that could allow exchange between the equipment and its contents. This requires a reliable porosity test.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	Because it is impervious to high temperatures and chemically reactive substances, vitreous enamel makes an excellent anti-corrosion barrier for the boilers and tanks used in the chemical and pharmaceutical industries. But this protection is only guaranteed if the coating is 100% continuous and has no pores, cracks, or other defects that could allow exchange between the equipment and its contents. This requires a reliable porosity test.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	Because it is impervious to high temperatures and chemically reactive substances, vitreous enamel makes an excellent anti-corrosion barrier for the boilers and tanks used in the chemical and pharmaceutical industries. But this protection is only guaranteed if the coating is 100% continuous and has no pores, cracks, or other defects that could allow exchange between the equipment and its contents. This requires a reliable porosity test.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	Because it is impervious to high temperatures and chemically reactive substances, vitreous enamel makes an excellent anti-corrosion barrier for the boilers and tanks used in the chemical and pharmaceutical industries. But this protection is only guaranteed if the coating is 100% continuous and has no pores, cracks, or other defects that could allow exchange between the equipment and its contents. This requires a reliable porosity test.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	Because it is impervious to high temperatures and chemically reactive substances, vitreous enamel makes an excellent anti-corrosion barrier for the boilers and tanks used in the chemical and pharmaceutical industries. But this protection is only guaranteed if the coating is 100% continuous and has no pores, cracks, or other defects that could allow exchange between the equipment and its contents. This requires a reliable porosity test.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	Because it is impervious to high temperatures and chemically reactive substances, vitreous enamel makes an excellent anti-corrosion barrier for the boilers and tanks used in the chemical and pharmaceutical industries. But this protection is only guaranteed if the coating is 100% continuous and has no pores, cracks, or other defects that could allow exchange between the equipment and its contents. This requires a reliable porosity test.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	Because it is impervious to high temperatures and chemically reactive substances, vitreous enamel makes an excellent anti-corrosion barrier for the boilers and tanks used in the chemical and pharmaceutical industries. But this protection is only guaranteed if the coating is 100% continuous and has no pores, cracks, or other defects that could allow exchange between the equipment and its contents. This requires a reliable porosity test.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	Because it is impervious to high temperatures and chemically reactive substances, vitreous enamel makes an excellent anti-corrosion barrier for the boilers and tanks used in the chemical and pharmaceutical industries. But this protection is only guaranteed if the coating is 100% continuous and has no pores, cracks, or other defects that could allow exchange between the equipment and its contents. This requires a reliable porosity test.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	Because it is impervious to high temperatures and chemically reactive substances, vitreous enamel makes an excellent anti-corrosion barrier for the boilers and tanks used in the chemical and pharmaceutical industries. But this protection is only guaranteed if the coating is 100% continuous and has no pores, cracks, or other defects that could allow exchange between the equipment and its contents. This requires a reliable porosity test.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	Because it is impervious to high temperatures and chemically reactive substances, vitreous enamel makes an excellent anti-corrosion barrier for the boilers and tanks used in the chemical and pharmaceutical industries. But this protection is only guaranteed if the coating is 100% continuous and has no pores, cracks, or other defects that could allow exchange between the equipment and its contents. This requires a reliable porosity test.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	Because it is impervious to high temperatures and chemically reactive substances, vitreous enamel makes an excellent anti-corrosion barrier for the boilers and tanks used in the chemical and pharmaceutical industries. But this protection is only guaranteed if the coating is 100% continuous and has no pores, cracks, or other defects that could allow exchange between the equipment and its contents. This requires a reliable porosity test.

  Industrielle Messtechni...  

Show textShow cached sourceOpen source URL	Schrauben, Muttern und Bolzen halten unsere Welt zusammen, aber einige von ihnen haben einen deutlich härteren Job als andere, z. B. wenn sie in rauen Umgebungen wie Off-Shore-Anlagen eingesetzt werden.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	Screws, nuts, washers and bolts can be found everywhere holding our world together, but some of them lead a much harder life than others, especially those used in harsh environments like offshore installations. Because nobody ever wants to dismantle a wind turbine or oil rig just to replace the fasteners, special corrosion-resistant alloys of stainless steel are used for them. This enables the supplier to guarantee a much longer service life, but that, in turn, requires clear and rigorous supervision of the material composition.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	Screws, nuts, washers and bolts can be found everywhere holding our world together, but some of them lead a much harder life than others, especially those used in harsh environments like offshore installations. Because nobody ever wants to dismantle a wind turbine or oil rig just to replace the fasteners, special corrosion-resistant alloys of stainless steel are used for them. This enables the supplier to guarantee a much longer service life, but that, in turn, requires clear and rigorous supervision of the material composition.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	Screws, nuts, washers and bolts can be found everywhere holding our world together, but some of them lead a much harder life than others, especially those used in harsh environments like offshore installations. Because nobody ever wants to dismantle a wind turbine or oil rig just to replace the fasteners, special corrosion-resistant alloys of stainless steel are used for them. This enables the supplier to guarantee a much longer service life, but that, in turn, requires clear and rigorous supervision of the material composition.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	Screws, nuts, washers and bolts can be found everywhere holding our world together, but some of them lead a much harder life than others, especially those used in harsh environments like offshore installations. Because nobody ever wants to dismantle a wind turbine or oil rig just to replace the fasteners, special corrosion-resistant alloys of stainless steel are used for them. This enables the supplier to guarantee a much longer service life, but that, in turn, requires clear and rigorous supervision of the material composition.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	Screws, nuts, washers and bolts can be found everywhere holding our world together, but some of them lead a much harder life than others, especially those used in harsh environments like offshore installations. Because nobody ever wants to dismantle a wind turbine or oil rig just to replace the fasteners, special corrosion-resistant alloys of stainless steel are used for them. This enables the supplier to guarantee a much longer service life, but that, in turn, requires clear and rigorous supervision of the material composition.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	Screws, nuts, washers and bolts can be found everywhere holding our world together, but some of them lead a much harder life than others, especially those used in harsh environments like offshore installations. Because nobody ever wants to dismantle a wind turbine or oil rig just to replace the fasteners, special corrosion-resistant alloys of stainless steel are used for them. This enables the supplier to guarantee a much longer service life, but that, in turn, requires clear and rigorous supervision of the material composition.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	Screws, nuts, washers and bolts can be found everywhere holding our world together, but some of them lead a much harder life than others, especially those used in harsh environments like offshore installations. Because nobody ever wants to dismantle a wind turbine or oil rig just to replace the fasteners, special corrosion-resistant alloys of stainless steel are used for them. This enables the supplier to guarantee a much longer service life, but that, in turn, requires clear and rigorous supervision of the material composition.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	Screws, nuts, washers and bolts can be found everywhere holding our world together, but some of them lead a much harder life than others, especially those used in harsh environments like offshore installations. Because nobody ever wants to dismantle a wind turbine or oil rig just to replace the fasteners, special corrosion-resistant alloys of stainless steel are used for them. This enables the supplier to guarantee a much longer service life, but that, in turn, requires clear and rigorous supervision of the material composition.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	Screws, nuts, washers and bolts can be found everywhere holding our world together, but some of them lead a much harder life than others, especially those used in harsh environments like offshore installations. Because nobody ever wants to dismantle a wind turbine or oil rig just to replace the fasteners, special corrosion-resistant alloys of stainless steel are used for them. This enables the supplier to guarantee a much longer service life, but that, in turn, requires clear and rigorous supervision of the material composition.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	Screws, nuts, washers and bolts can be found everywhere holding our world together, but some of them lead a much harder life than others, especially those used in harsh environments like offshore installations. Because nobody ever wants to dismantle a wind turbine or oil rig just to replace the fasteners, special corrosion-resistant alloys of stainless steel are used for them. This enables the supplier to guarantee a much longer service life, but that, in turn, requires clear and rigorous supervision of the material composition.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	Screws, nuts, washers and bolts can be found everywhere holding our world together, but some of them lead a much harder life than others, especially those used in harsh environments like offshore installations. Because nobody ever wants to dismantle a wind turbine or oil rig just to replace the fasteners, special corrosion-resistant alloys of stainless steel are used for them. This enables the supplier to guarantee a much longer service life, but that, in turn, requires clear and rigorous supervision of the material composition.

  Industrielle Messtechni...  

Show textShow cached sourceOpen source URL	Andere, wie die Atomabsorption (AA) sind zerstörend und damit nicht geeignet, jeden einzelnen Lotpunkt zu testen. Die Röntgenfluoreszenz-Methode (RFA) hat sich als ideales Verfahren zur Überwachung der Konzentration aller drei Elemente erwiesen.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	The small size of the bumps (typically 80μm in diameter) prevents the use of most analytical methods. Others, such as atomic absorption (AA), are destructive and are therefore not suitable for testing each individual bump. However, X-ray fluorescence (XRF), has proven to be an ideal approach for monitoring the concentration of all three elements. Table 1 shows typical measurement results for a SnAgCu solder bump.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	The small size of the bumps (typically 80μm in diameter) prevents the use of most analytical methods. Others, such as atomic absorption (AA), are destructive and are therefore not suitable for testing each individual bump. However, X-ray fluorescence (XRF), has proven to be an ideal approach for monitoring the concentration of all three elements. Table 1 shows typical measurement results for a SnAgCu solder bump.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	The small size of the bumps (typically 80μm in diameter) prevents the use of most analytical methods. Others, such as atomic absorption (AA), are destructive and are therefore not suitable for testing each individual bump. However, X-ray fluorescence (XRF), has proven to be an ideal approach for monitoring the concentration of all three elements. Table 1 shows typical measurement results for a SnAgCu solder bump.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	The small size of the bumps (typically 80μm in diameter) prevents the use of most analytical methods. Others, such as atomic absorption (AA), are destructive and are therefore not suitable for testing each individual bump. However, X-ray fluorescence (XRF), has proven to be an ideal approach for monitoring the concentration of all three elements. Table 1 shows typical measurement results for a SnAgCu solder bump.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	The small size of the bumps (typically 80μm in diameter) prevents the use of most analytical methods. Others, such as atomic absorption (AA), are destructive and are therefore not suitable for testing each individual bump. However, X-ray fluorescence (XRF), has proven to be an ideal approach for monitoring the concentration of all three elements. Table 1 shows typical measurement results for a SnAgCu solder bump.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	The small size of the bumps (typically 80μm in diameter) prevents the use of most analytical methods. Others, such as atomic absorption (AA), are destructive and are therefore not suitable for testing each individual bump. However, X-ray fluorescence (XRF), has proven to be an ideal approach for monitoring the concentration of all three elements. Table 1 shows typical measurement results for a SnAgCu solder bump.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	The small size of the bumps (typically 80μm in diameter) prevents the use of most analytical methods. Others, such as atomic absorption (AA), are destructive and are therefore not suitable for testing each individual bump. However, X-ray fluorescence (XRF), has proven to be an ideal approach for monitoring the concentration of all three elements. Table 1 shows typical measurement results for a SnAgCu solder bump.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	The small size of the bumps (typically 80μm in diameter) prevents the use of most analytical methods. Others, such as atomic absorption (AA), are destructive and are therefore not suitable for testing each individual bump. However, X-ray fluorescence (XRF), has proven to be an ideal approach for monitoring the concentration of all three elements. Table 1 shows typical measurement results for a SnAgCu solder bump.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	The small size of the bumps (typically 80μm in diameter) prevents the use of most analytical methods. Others, such as atomic absorption (AA), are destructive and are therefore not suitable for testing each individual bump. However, X-ray fluorescence (XRF), has proven to be an ideal approach for monitoring the concentration of all three elements. Table 1 shows typical measurement results for a SnAgCu solder bump.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	The small size of the bumps (typically 80μm in diameter) prevents the use of most analytical methods. Others, such as atomic absorption (AA), are destructive and are therefore not suitable for testing each individual bump. However, X-ray fluorescence (XRF), has proven to be an ideal approach for monitoring the concentration of all three elements. Table 1 shows typical measurement results for a SnAgCu solder bump.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	The small size of the bumps (typically 80μm in diameter) prevents the use of most analytical methods. Others, such as atomic absorption (AA), are destructive and are therefore not suitable for testing each individual bump. However, X-ray fluorescence (XRF), has proven to be an ideal approach for monitoring the concentration of all three elements. Table 1 shows typical measurement results for a SnAgCu solder bump.

  Industrielle Messtechni...  

Show textShow cached sourceOpen source URL	In der Elektronikindustrie werden zur Verhinderung von Kriechströmen und als Schutz vor Feuchtigkeit und anderen Umwelteinflüssen Zweikomponenten-Isolierlacke verwendet. Dabei spielt die richtige Zusammensetzung eine entscheidende Rolle, weshalb für deren Qualitätskontrolle eine zuverlässige Messtechnik benötigt wird.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	In the electronics industry, two-component conformal coatings are often used to minimize current leakage on PCBs and as protection against humidity and other environmental stressors. Because the exact composition of the polymer determines its final mechanical properties, quality control using a reliable measurement technology is mandatory.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	In the electronics industry, two-component conformal coatings are often used to minimize current leakage on PCBs and as protection against humidity and other environmental stressors. Because the exact composition of the polymer determines its final mechanical properties, quality control using a reliable measurement technology is mandatory.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	In the electronics industry, two-component conformal coatings are often used to minimize current leakage on PCBs and as protection against humidity and other environmental stressors. Because the exact composition of the polymer determines its final mechanical properties, quality control using a reliable measurement technology is mandatory.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	In the electronics industry, two-component conformal coatings are often used to minimize current leakage on PCBs and as protection against humidity and other environmental stressors. Because the exact composition of the polymer determines its final mechanical properties, quality control using a reliable measurement technology is mandatory.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	In the electronics industry, two-component conformal coatings are often used to minimize current leakage on PCBs and as protection against humidity and other environmental stressors. Because the exact composition of the polymer determines its final mechanical properties, quality control using a reliable measurement technology is mandatory.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	In the electronics industry, two-component conformal coatings are often used to minimize current leakage on PCBs and as protection against humidity and other environmental stressors. Because the exact composition of the polymer determines its final mechanical properties, quality control using a reliable measurement technology is mandatory.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	In the electronics industry, two-component conformal coatings are often used to minimize current leakage on PCBs and as protection against humidity and other environmental stressors. Because the exact composition of the polymer determines its final mechanical properties, quality control using a reliable measurement technology is mandatory.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	In the electronics industry, two-component conformal coatings are often used to minimize current leakage on PCBs and as protection against humidity and other environmental stressors. Because the exact composition of the polymer determines its final mechanical properties, quality control using a reliable measurement technology is mandatory.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	In the electronics industry, two-component conformal coatings are often used to minimize current leakage on PCBs and as protection against humidity and other environmental stressors. Because the exact composition of the polymer determines its final mechanical properties, quality control using a reliable measurement technology is mandatory.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	In the electronics industry, two-component conformal coatings are often used to minimize current leakage on PCBs and as protection against humidity and other environmental stressors. Because the exact composition of the polymer determines its final mechanical properties, quality control using a reliable measurement technology is mandatory.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	In the electronics industry, two-component conformal coatings are often used to minimize current leakage on PCBs and as protection against humidity and other environmental stressors. Because the exact composition of the polymer determines its final mechanical properties, quality control using a reliable measurement technology is mandatory.

  Industrielle Messtechni...  

Show textShow cached sourceOpen source URL	Neue Technologien für effiziente und umweltfreundliche Energieversorgungssysteme gewinnen immer mehr an Bedeutung. Ein Bespiel dafür ist die Wasserstofftechnologie, die sowohl als Speichermedium als auch als Treibstoff ein großes Potenzial bietet.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	New technologies have become more important than ever for developing efficient and clean energy supply systems. Hydrogen technology is one example that holds high potential both as an accumulator and as a fuel. However, cryogenic liquid hydrogen is typically stored in special steel tanks – a circumstance that presents its own safety challenges: Should the structure of the tank fail in any way, the hydrogen can escape uncontrollably and form inflammable mixtures with other elements like oxygen present in the air. Therefore, material testing is absolutely essential in any quality control process for tanks used to store liquid hydrogen.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	New technologies have become more important than ever for developing efficient and clean energy supply systems. Hydrogen technology is one example that holds high potential both as an accumulator and as a fuel. However, cryogenic liquid hydrogen is typically stored in special steel tanks – a circumstance that presents its own safety challenges: Should the structure of the tank fail in any way, the hydrogen can escape uncontrollably and form inflammable mixtures with other elements like oxygen present in the air. Therefore, material testing is absolutely essential in any quality control process for tanks used to store liquid hydrogen.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	New technologies have become more important than ever for developing efficient and clean energy supply systems. Hydrogen technology is one example that holds high potential both as an accumulator and as a fuel. However, cryogenic liquid hydrogen is typically stored in special steel tanks – a circumstance that presents its own safety challenges: Should the structure of the tank fail in any way, the hydrogen can escape uncontrollably and form inflammable mixtures with other elements like oxygen present in the air. Therefore, material testing is absolutely essential in any quality control process for tanks used to store liquid hydrogen.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	New technologies have become more important than ever for developing efficient and clean energy supply systems. Hydrogen technology is one example that holds high potential both as an accumulator and as a fuel. However, cryogenic liquid hydrogen is typically stored in special steel tanks – a circumstance that presents its own safety challenges: Should the structure of the tank fail in any way, the hydrogen can escape uncontrollably and form inflammable mixtures with other elements like oxygen present in the air. Therefore, material testing is absolutely essential in any quality control process for tanks used to store liquid hydrogen.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	New technologies have become more important than ever for developing efficient and clean energy supply systems. Hydrogen technology is one example that holds high potential both as an accumulator and as a fuel. However, cryogenic liquid hydrogen is typically stored in special steel tanks – a circumstance that presents its own safety challenges: Should the structure of the tank fail in any way, the hydrogen can escape uncontrollably and form inflammable mixtures with other elements like oxygen present in the air. Therefore, material testing is absolutely essential in any quality control process for tanks used to store liquid hydrogen.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	New technologies have become more important than ever for developing efficient and clean energy supply systems. Hydrogen technology is one example that holds high potential both as an accumulator and as a fuel. However, cryogenic liquid hydrogen is typically stored in special steel tanks – a circumstance that presents its own safety challenges: Should the structure of the tank fail in any way, the hydrogen can escape uncontrollably and form inflammable mixtures with other elements like oxygen present in the air. Therefore, material testing is absolutely essential in any quality control process for tanks used to store liquid hydrogen.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	New technologies have become more important than ever for developing efficient and clean energy supply systems. Hydrogen technology is one example that holds high potential both as an accumulator and as a fuel. However, cryogenic liquid hydrogen is typically stored in special steel tanks – a circumstance that presents its own safety challenges: Should the structure of the tank fail in any way, the hydrogen can escape uncontrollably and form inflammable mixtures with other elements like oxygen present in the air. Therefore, material testing is absolutely essential in any quality control process for tanks used to store liquid hydrogen.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	New technologies have become more important than ever for developing efficient and clean energy supply systems. Hydrogen technology is one example that holds high potential both as an accumulator and as a fuel. However, cryogenic liquid hydrogen is typically stored in special steel tanks – a circumstance that presents its own safety challenges: Should the structure of the tank fail in any way, the hydrogen can escape uncontrollably and form inflammable mixtures with other elements like oxygen present in the air. Therefore, material testing is absolutely essential in any quality control process for tanks used to store liquid hydrogen.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	New technologies have become more important than ever for developing efficient and clean energy supply systems. Hydrogen technology is one example that holds high potential both as an accumulator and as a fuel. However, cryogenic liquid hydrogen is typically stored in special steel tanks – a circumstance that presents its own safety challenges: Should the structure of the tank fail in any way, the hydrogen can escape uncontrollably and form inflammable mixtures with other elements like oxygen present in the air. Therefore, material testing is absolutely essential in any quality control process for tanks used to store liquid hydrogen.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	New technologies have become more important than ever for developing efficient and clean energy supply systems. Hydrogen technology is one example that holds high potential both as an accumulator and as a fuel. However, cryogenic liquid hydrogen is typically stored in special steel tanks – a circumstance that presents its own safety challenges: Should the structure of the tank fail in any way, the hydrogen can escape uncontrollably and form inflammable mixtures with other elements like oxygen present in the air. Therefore, material testing is absolutely essential in any quality control process for tanks used to store liquid hydrogen.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	New technologies have become more important than ever for developing efficient and clean energy supply systems. Hydrogen technology is one example that holds high potential both as an accumulator and as a fuel. However, cryogenic liquid hydrogen is typically stored in special steel tanks – a circumstance that presents its own safety challenges: Should the structure of the tank fail in any way, the hydrogen can escape uncontrollably and form inflammable mixtures with other elements like oxygen present in the air. Therefore, material testing is absolutely essential in any quality control process for tanks used to store liquid hydrogen.

  Industrielle Messtechni...  

Show textShow cached sourceOpen source URL	Kühlt man Auste­nit jedoch sehr schnell ab ("Abschrecken" des Stahls, um diesen zu härten), so kann sich kein Ferrit bzw. Ze­mentit bilden, da es gar nicht erst zu einer entsprechen­den Diffusion des Kohlenstoffs kommt. Als Folge dieser diffusionslosen Transformation bildet sich ebenfalls Martensit.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	Also dropping below the MS (martensite start) temperature can be problematic. When allowed to cool slowly, the austenite transforms into a mixture of ferrite and cementite. But in a rapid cooling process (i.e. quenching, employed to harden the steel), there is no time for the carbon atoms to diffuse out of the crystalline structure in large enough quantities to form ferrite and cementite, resulting in martensite.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	Also dropping below the MS (martensite start) temperature can be problematic. When allowed to cool slowly, the austenite transforms into a mixture of ferrite and cementite. But in a rapid cooling process (i.e. quenching, employed to harden the steel), there is no time for the carbon atoms to diffuse out of the crystalline structure in large enough quantities to form ferrite and cementite, resulting in martensite.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	Also dropping below the MS (martensite start) temperature can be problematic. When allowed to cool slowly, the austenite transforms into a mixture of ferrite and cementite. But in a rapid cooling process (i.e. quenching, employed to harden the steel), there is no time for the carbon atoms to diffuse out of the crystalline structure in large enough quantities to form ferrite and cementite, resulting in martensite.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	Also dropping below the MS (martensite start) temperature can be problematic. When allowed to cool slowly, the austenite transforms into a mixture of ferrite and cementite. But in a rapid cooling process (i.e. quenching, employed to harden the steel), there is no time for the carbon atoms to diffuse out of the crystalline structure in large enough quantities to form ferrite and cementite, resulting in martensite.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	Also dropping below the MS (martensite start) temperature can be problematic. When allowed to cool slowly, the austenite transforms into a mixture of ferrite and cementite. But in a rapid cooling process (i.e. quenching, employed to harden the steel), there is no time for the carbon atoms to diffuse out of the crystalline structure in large enough quantities to form ferrite and cementite, resulting in martensite.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	Also dropping below the MS (martensite start) temperature can be problematic. When allowed to cool slowly, the austenite transforms into a mixture of ferrite and cementite. But in a rapid cooling process (i.e. quenching, employed to harden the steel), there is no time for the carbon atoms to diffuse out of the crystalline structure in large enough quantities to form ferrite and cementite, resulting in martensite.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	Also dropping below the MS (martensite start) temperature can be problematic. When allowed to cool slowly, the austenite transforms into a mixture of ferrite and cementite. But in a rapid cooling process (i.e. quenching, employed to harden the steel), there is no time for the carbon atoms to diffuse out of the crystalline structure in large enough quantities to form ferrite and cementite, resulting in martensite.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	Also dropping below the MS (martensite start) temperature can be problematic. When allowed to cool slowly, the austenite transforms into a mixture of ferrite and cementite. But in a rapid cooling process (i.e. quenching, employed to harden the steel), there is no time for the carbon atoms to diffuse out of the crystalline structure in large enough quantities to form ferrite and cementite, resulting in martensite.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	Also dropping below the MS (martensite start) temperature can be problematic. When allowed to cool slowly, the austenite transforms into a mixture of ferrite and cementite. But in a rapid cooling process (i.e. quenching, employed to harden the steel), there is no time for the carbon atoms to diffuse out of the crystalline structure in large enough quantities to form ferrite and cementite, resulting in martensite.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	Also dropping below the MS (martensite start) temperature can be problematic. When allowed to cool slowly, the austenite transforms into a mixture of ferrite and cementite. But in a rapid cooling process (i.e. quenching, employed to harden the steel), there is no time for the carbon atoms to diffuse out of the crystalline structure in large enough quantities to form ferrite and cementite, resulting in martensite.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	Also dropping below the MS (martensite start) temperature can be problematic. When allowed to cool slowly, the austenite transforms into a mixture of ferrite and cementite. But in a rapid cooling process (i.e. quenching, employed to harden the steel), there is no time for the carbon atoms to diffuse out of the crystalline structure in large enough quantities to form ferrite and cementite, resulting in martensite.

  Industrielle Messtechni...  

Show textShow cached sourceOpen source URL	Ein zu hoher Anteil Martensit ist bei der Nutzung als Wasserstoff-Tank allerdings nicht erwünscht, denn an den Martensit-Korngrenzen kann sich Wasserstoff einlagern, was zum Bruch des Materials führen kann (Versprödung oder Kälterissbildung).
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	Too much martensite is undesirable in steel destined for hydrogen tanks, because hydrogen can settle at the grain boundaries of the martensite (hydrogen embrittle­ment or cold cracking), which can then lead to material failures. Therefore, testing the steel’s martensite content with precise measurements is required to determine its suitability for this purpose.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	Too much martensite is undesirable in steel destined for hydrogen tanks, because hydrogen can settle at the grain boundaries of the martensite (hydrogen embrittle­ment or cold cracking), which can then lead to material failures. Therefore, testing the steel’s martensite content with precise measurements is required to determine its suitability for this purpose.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	Too much martensite is undesirable in steel destined for hydrogen tanks, because hydrogen can settle at the grain boundaries of the martensite (hydrogen embrittle­ment or cold cracking), which can then lead to material failures. Therefore, testing the steel’s martensite content with precise measurements is required to determine its suitability for this purpose.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	Too much martensite is undesirable in steel destined for hydrogen tanks, because hydrogen can settle at the grain boundaries of the martensite (hydrogen embrittle­ment or cold cracking), which can then lead to material failures. Therefore, testing the steel’s martensite content with precise measurements is required to determine its suitability for this purpose.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	Too much martensite is undesirable in steel destined for hydrogen tanks, because hydrogen can settle at the grain boundaries of the martensite (hydrogen embrittle­ment or cold cracking), which can then lead to material failures. Therefore, testing the steel’s martensite content with precise measurements is required to determine its suitability for this purpose.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	Too much martensite is undesirable in steel destined for hydrogen tanks, because hydrogen can settle at the grain boundaries of the martensite (hydrogen embrittle­ment or cold cracking), which can then lead to material failures. Therefore, testing the steel’s martensite content with precise measurements is required to determine its suitability for this purpose.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	Too much martensite is undesirable in steel destined for hydrogen tanks, because hydrogen can settle at the grain boundaries of the martensite (hydrogen embrittle­ment or cold cracking), which can then lead to material failures. Therefore, testing the steel’s martensite content with precise measurements is required to determine its suitability for this purpose.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	Too much martensite is undesirable in steel destined for hydrogen tanks, because hydrogen can settle at the grain boundaries of the martensite (hydrogen embrittle­ment or cold cracking), which can then lead to material failures. Therefore, testing the steel’s martensite content with precise measurements is required to determine its suitability for this purpose.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	Too much martensite is undesirable in steel destined for hydrogen tanks, because hydrogen can settle at the grain boundaries of the martensite (hydrogen embrittle­ment or cold cracking), which can then lead to material failures. Therefore, testing the steel’s martensite content with precise measurements is required to determine its suitability for this purpose.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	Too much martensite is undesirable in steel destined for hydrogen tanks, because hydrogen can settle at the grain boundaries of the martensite (hydrogen embrittle­ment or cold cracking), which can then lead to material failures. Therefore, testing the steel’s martensite content with precise measurements is required to determine its suitability for this purpose.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	Too much martensite is undesirable in steel destined for hydrogen tanks, because hydrogen can settle at the grain boundaries of the martensite (hydrogen embrittle­ment or cold cracking), which can then lead to material failures. Therefore, testing the steel’s martensite content with precise measurements is required to determine its suitability for this purpose.

  Industrielle Messtechni...  

Show textShow cached sourceOpen source URL	Neue Technologien für effiziente und umweltfreundliche Energieversorgungssysteme gewinnen immer mehr an Bedeutung. Ein Bespiel dafür ist die Wasserstofftechnologie, die sowohl als Speichermedium als auch als Treibstoff ein großes Potenzial bietet.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	New technologies have become more important than ever for developing efficient and clean energy supply systems. Hydrogen technology is one example that holds high potential both as an accumulator and as a fuel. However, cryogenic liquid hydrogen is typically stored in special steel tanks – a circumstance that presents its own safety challenges: Should the structure of the tank fail in any way, the hydrogen can escape uncontrollably and form inflammable mixtures with other elements like oxygen present in the air. Therefore, material testing is absolutely essential in any quality control process for tanks used to store liquid hydrogen.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	New technologies have become more important than ever for developing efficient and clean energy supply systems. Hydrogen technology is one example that holds high potential both as an accumulator and as a fuel. However, cryogenic liquid hydrogen is typically stored in special steel tanks – a circumstance that presents its own safety challenges: Should the structure of the tank fail in any way, the hydrogen can escape uncontrollably and form inflammable mixtures with other elements like oxygen present in the air. Therefore, material testing is absolutely essential in any quality control process for tanks used to store liquid hydrogen.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	New technologies have become more important than ever for developing efficient and clean energy supply systems. Hydrogen technology is one example that holds high potential both as an accumulator and as a fuel. However, cryogenic liquid hydrogen is typically stored in special steel tanks – a circumstance that presents its own safety challenges: Should the structure of the tank fail in any way, the hydrogen can escape uncontrollably and form inflammable mixtures with other elements like oxygen present in the air. Therefore, material testing is absolutely essential in any quality control process for tanks used to store liquid hydrogen.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	New technologies have become more important than ever for developing efficient and clean energy supply systems. Hydrogen technology is one example that holds high potential both as an accumulator and as a fuel. However, cryogenic liquid hydrogen is typically stored in special steel tanks – a circumstance that presents its own safety challenges: Should the structure of the tank fail in any way, the hydrogen can escape uncontrollably and form inflammable mixtures with other elements like oxygen present in the air. Therefore, material testing is absolutely essential in any quality control process for tanks used to store liquid hydrogen.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	New technologies have become more important than ever for developing efficient and clean energy supply systems. Hydrogen technology is one example that holds high potential both as an accumulator and as a fuel. However, cryogenic liquid hydrogen is typically stored in special steel tanks – a circumstance that presents its own safety challenges: Should the structure of the tank fail in any way, the hydrogen can escape uncontrollably and form inflammable mixtures with other elements like oxygen present in the air. Therefore, material testing is absolutely essential in any quality control process for tanks used to store liquid hydrogen.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	New technologies have become more important than ever for developing efficient and clean energy supply systems. Hydrogen technology is one example that holds high potential both as an accumulator and as a fuel. However, cryogenic liquid hydrogen is typically stored in special steel tanks – a circumstance that presents its own safety challenges: Should the structure of the tank fail in any way, the hydrogen can escape uncontrollably and form inflammable mixtures with other elements like oxygen present in the air. Therefore, material testing is absolutely essential in any quality control process for tanks used to store liquid hydrogen.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	New technologies have become more important than ever for developing efficient and clean energy supply systems. Hydrogen technology is one example that holds high potential both as an accumulator and as a fuel. However, cryogenic liquid hydrogen is typically stored in special steel tanks – a circumstance that presents its own safety challenges: Should the structure of the tank fail in any way, the hydrogen can escape uncontrollably and form inflammable mixtures with other elements like oxygen present in the air. Therefore, material testing is absolutely essential in any quality control process for tanks used to store liquid hydrogen.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	New technologies have become more important than ever for developing efficient and clean energy supply systems. Hydrogen technology is one example that holds high potential both as an accumulator and as a fuel. However, cryogenic liquid hydrogen is typically stored in special steel tanks – a circumstance that presents its own safety challenges: Should the structure of the tank fail in any way, the hydrogen can escape uncontrollably and form inflammable mixtures with other elements like oxygen present in the air. Therefore, material testing is absolutely essential in any quality control process for tanks used to store liquid hydrogen.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	New technologies have become more important than ever for developing efficient and clean energy supply systems. Hydrogen technology is one example that holds high potential both as an accumulator and as a fuel. However, cryogenic liquid hydrogen is typically stored in special steel tanks – a circumstance that presents its own safety challenges: Should the structure of the tank fail in any way, the hydrogen can escape uncontrollably and form inflammable mixtures with other elements like oxygen present in the air. Therefore, material testing is absolutely essential in any quality control process for tanks used to store liquid hydrogen.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	New technologies have become more important than ever for developing efficient and clean energy supply systems. Hydrogen technology is one example that holds high potential both as an accumulator and as a fuel. However, cryogenic liquid hydrogen is typically stored in special steel tanks – a circumstance that presents its own safety challenges: Should the structure of the tank fail in any way, the hydrogen can escape uncontrollably and form inflammable mixtures with other elements like oxygen present in the air. Therefore, material testing is absolutely essential in any quality control process for tanks used to store liquid hydrogen.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	New technologies have become more important than ever for developing efficient and clean energy supply systems. Hydrogen technology is one example that holds high potential both as an accumulator and as a fuel. However, cryogenic liquid hydrogen is typically stored in special steel tanks – a circumstance that presents its own safety challenges: Should the structure of the tank fail in any way, the hydrogen can escape uncontrollably and form inflammable mixtures with other elements like oxygen present in the air. Therefore, material testing is absolutely essential in any quality control process for tanks used to store liquid hydrogen.

  Industrielle Messtechni...  

Show textShow cached sourceOpen source URL	Im Kraftwerksbau wird auf hochbelastete, metallische Bauteile eine sogenannte Cladding-Schicht – ein hochlegierter Stahl – als Oberflächenschutz aufgebracht. Um möglichst lange Standzeiten zur gewährleisten, muss die Beschichtung gleichmäßig aufgebracht werden.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	In power plants, high-alloy steel coatings are bonded onto metal components that are subject to extreme wear and/or corrosion using so-called cladding techniques. For longest service life, it is essential that the coating material is applied with uniform thickness. Continuous monitoring of the thickness is mandatory.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	In power plants, high-alloy steel coatings are bonded onto metal components that are subject to extreme wear and/or corrosion using so-called cladding techniques. For longest service life, it is essential that the coating material is applied with uniform thickness. Continuous monitoring of the thickness is mandatory.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	In power plants, high-alloy steel coatings are bonded onto metal components that are subject to extreme wear and/or corrosion using so-called cladding techniques. For longest service life, it is essential that the coating material is applied with uniform thickness. Continuous monitoring of the thickness is mandatory.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	In power plants, high-alloy steel coatings are bonded onto metal components that are subject to extreme wear and/or corrosion using so-called cladding techniques. For longest service life, it is essential that the coating material is applied with uniform thickness. Continuous monitoring of the thickness is mandatory.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	In power plants, high-alloy steel coatings are bonded onto metal components that are subject to extreme wear and/or corrosion using so-called cladding techniques. For longest service life, it is essential that the coating material is applied with uniform thickness. Continuous monitoring of the thickness is mandatory.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	In power plants, high-alloy steel coatings are bonded onto metal components that are subject to extreme wear and/or corrosion using so-called cladding techniques. For longest service life, it is essential that the coating material is applied with uniform thickness. Continuous monitoring of the thickness is mandatory.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	In power plants, high-alloy steel coatings are bonded onto metal components that are subject to extreme wear and/or corrosion using so-called cladding techniques. For longest service life, it is essential that the coating material is applied with uniform thickness. Continuous monitoring of the thickness is mandatory.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	In power plants, high-alloy steel coatings are bonded onto metal components that are subject to extreme wear and/or corrosion using so-called cladding techniques. For longest service life, it is essential that the coating material is applied with uniform thickness. Continuous monitoring of the thickness is mandatory.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	In power plants, high-alloy steel coatings are bonded onto metal components that are subject to extreme wear and/or corrosion using so-called cladding techniques. For longest service life, it is essential that the coating material is applied with uniform thickness. Continuous monitoring of the thickness is mandatory.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	In power plants, high-alloy steel coatings are bonded onto metal components that are subject to extreme wear and/or corrosion using so-called cladding techniques. For longest service life, it is essential that the coating material is applied with uniform thickness. Continuous monitoring of the thickness is mandatory.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	In power plants, high-alloy steel coatings are bonded onto metal components that are subject to extreme wear and/or corrosion using so-called cladding techniques. For longest service life, it is essential that the coating material is applied with uniform thickness. Continuous monitoring of the thickness is mandatory.

  Industrielle Messtechni...  

Show textShow cached sourceOpen source URL	Da stößt selbst die beste Zahnhygiene an ihre Grenzen und häufig ist Karies die unerwünschte Begleiterscheinung der ungesunden Lebensweise. Als Folge sind die Entfernung der Kariesstellen und das Einbringen von Füllungen inzwischen alltägliche Praxis.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	Enticing snacks and beverages with high sugar and/or acid content are a constant temptation in today’s vast offering of fast and prepared foods. Even the best oral hygiene has trouble keeping up; often, the side effects of unhealthy eating habits are cavities. As a result, the removal of caries and the placement of fillings have become common practice. However, the age of ugly black fillings is coming to an end, as tooth-coloured inlays and onlays of composite resin are replacing their unsightly amalgam precursors.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	Enticing snacks and beverages with high sugar and/or acid content are a constant temptation in today’s vast offering of fast and prepared foods. Even the best oral hygiene has trouble keeping up; often, the side effects of unhealthy eating habits are cavities. As a result, the removal of caries and the placement of fillings have become common practice. However, the age of ugly black fillings is coming to an end, as tooth-coloured inlays and onlays of composite resin are replacing their unsightly amalgam precursors.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	Enticing snacks and beverages with high sugar and/or acid content are a constant temptation in today’s vast offering of fast and prepared foods. Even the best oral hygiene has trouble keeping up; often, the side effects of unhealthy eating habits are cavities. As a result, the removal of caries and the placement of fillings have become common practice. However, the age of ugly black fillings is coming to an end, as tooth-coloured inlays and onlays of composite resin are replacing their unsightly amalgam precursors.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	Enticing snacks and beverages with high sugar and/or acid content are a constant temptation in today’s vast offering of fast and prepared foods. Even the best oral hygiene has trouble keeping up; often, the side effects of unhealthy eating habits are cavities. As a result, the removal of caries and the placement of fillings have become common practice. However, the age of ugly black fillings is coming to an end, as tooth-coloured inlays and onlays of composite resin are replacing their unsightly amalgam precursors.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	Enticing snacks and beverages with high sugar and/or acid content are a constant temptation in today’s vast offering of fast and prepared foods. Even the best oral hygiene has trouble keeping up; often, the side effects of unhealthy eating habits are cavities. As a result, the removal of caries and the placement of fillings have become common practice. However, the age of ugly black fillings is coming to an end, as tooth-coloured inlays and onlays of composite resin are replacing their unsightly amalgam precursors.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	Enticing snacks and beverages with high sugar and/or acid content are a constant temptation in today’s vast offering of fast and prepared foods. Even the best oral hygiene has trouble keeping up; often, the side effects of unhealthy eating habits are cavities. As a result, the removal of caries and the placement of fillings have become common practice. However, the age of ugly black fillings is coming to an end, as tooth-coloured inlays and onlays of composite resin are replacing their unsightly amalgam precursors.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	Enticing snacks and beverages with high sugar and/or acid content are a constant temptation in today’s vast offering of fast and prepared foods. Even the best oral hygiene has trouble keeping up; often, the side effects of unhealthy eating habits are cavities. As a result, the removal of caries and the placement of fillings have become common practice. However, the age of ugly black fillings is coming to an end, as tooth-coloured inlays and onlays of composite resin are replacing their unsightly amalgam precursors.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	Enticing snacks and beverages with high sugar and/or acid content are a constant temptation in today’s vast offering of fast and prepared foods. Even the best oral hygiene has trouble keeping up; often, the side effects of unhealthy eating habits are cavities. As a result, the removal of caries and the placement of fillings have become common practice. However, the age of ugly black fillings is coming to an end, as tooth-coloured inlays and onlays of composite resin are replacing their unsightly amalgam precursors.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	Enticing snacks and beverages with high sugar and/or acid content are a constant temptation in today’s vast offering of fast and prepared foods. Even the best oral hygiene has trouble keeping up; often, the side effects of unhealthy eating habits are cavities. As a result, the removal of caries and the placement of fillings have become common practice. However, the age of ugly black fillings is coming to an end, as tooth-coloured inlays and onlays of composite resin are replacing their unsightly amalgam precursors.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	Enticing snacks and beverages with high sugar and/or acid content are a constant temptation in today’s vast offering of fast and prepared foods. Even the best oral hygiene has trouble keeping up; often, the side effects of unhealthy eating habits are cavities. As a result, the removal of caries and the placement of fillings have become common practice. However, the age of ugly black fillings is coming to an end, as tooth-coloured inlays and onlays of composite resin are replacing their unsightly amalgam precursors.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	Enticing snacks and beverages with high sugar and/or acid content are a constant temptation in today’s vast offering of fast and prepared foods. Even the best oral hygiene has trouble keeping up; often, the side effects of unhealthy eating habits are cavities. As a result, the removal of caries and the placement of fillings have become common practice. However, the age of ugly black fillings is coming to an end, as tooth-coloured inlays and onlays of composite resin are replacing their unsightly amalgam precursors.

  Institute for Scientifi...  

Show textShow cached sourceOpen source URL	Durch den idealen Mix aus Praxis und theoretischer Lehre ist das lfG stark in Industrie und Wissenschaft gleichermaßen. So gilt es als führend in der Herstellung von Polykapillaroptiken für die Röntgenfluoreszenz.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	An ideal combination of practical and theoretical expertise accounts for the IfG’s strength in both industrial and basic-science applications. For this reason, it is considered a leader in the manufacture of polycapillary optics for X-ray fluorescence.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	Une combinaison idéale d'expertise pratique et théorique explique la force de l'IfG dans les applications industrielles comme scientifiques. Pour cette raison, il est considéré comme un leader dans la fabrication d'optique polycapillaire destinée à la spectrométrie de fluorescence X.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	La fortaleza del IfG se basa en la combinación ideal de experiencia práctica y teórica en aplicaciones industriales y de ciencias básicas. Por esa razón, se le considera líder en la fabricación de sistemas ópticos policapilares para la fluorescencia de rayos X.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	Una combinazione ottimale di competenza teorica e pratica corrispondente all'efficacia di IfG in applicazioni sia industriali sia di base. Per questa ragione, è considerato un leader nella fabbricazione di ottica policapillare per la fluorescenza a raggi X.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	De ideale combinatie van praktische en theoretische kennis is de basis voor de kracht van IfG bij zowel industriële als fundamenteel wetenschappelijke toepassingen. Daarom wordt het beschouwd als leider voor de productie van polycapillaire lenzen voor röntgenfluorescentie.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	Ideaalse praktiliste ja teoreetiliste ekspertiiside kombinatsioon moodustab IfG tugevuse nii tööstuses kui ka loodusteadustes. Sel põhjusel peetakse seda liider polükaapillaarse optika tootmiseks röntgenfluorestsentsi jaoks.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	Idealus praktinių ir teorinių žinių derinys atspindi IfG stiprumą tiek pramonėje, tiek pagrindinėse mokslo srityse. Dėl šios priežasties laikoma polikapilinės optikos gamintoja rentgeno fluorescencijos srityje.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	Dzięki doskonałemu połączeniu wiedzy teoretycznej i praktycznej przyrządy IfG doskonale sprawdzają się zarówno w zastosowaniach przemysłowych, jak i naukowych. Z tego powodu firma IfG jest uznawana za jednego z wiodących producentów polikapilarnych układów optycznych do urządzeń do fluorescencji rentgenowskiej.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	Идеальное сочетание практических навыков и теоретических знаний специалистов института является оптимальным как для решения прикладных промышленных, так и общих научных задач. Благодаря этому институт считается ведущей организацией в сфере производства поликапиллярной оптики для рентгенофлуоресцентных приборов.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	İdeal bir pratik ve teorik uzmanlık kombinasyonu IfG’nin hem endüstriyel hem de temel bilim uygulamalarında güçlü olmasını sağlamaktadır. Bu nedenle, X-ray flüoresans için polikapiler optik üretimi alanında bir lider olarak görülmektedir.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	Ideāla praktisku un teorētisku ekspertīžu kombinācija veido IfG spēku gan industriālajās, gan fundamentālajās zinātnēs. Šā iemesla dēļ tiek uzskatīts par līderi polikapilārās optikas ražošanā rentgena fluorescencei.

  Industrielle Messtechni...  

Show textShow cached sourceOpen source URL	Als Grundmaterial für die Herstellung von Wasserstoff-Tanks dient meist austenitischer Stahl. Das kubisch flächenzentrierte Gefüge von austenitischen Stählen befindet sich jedoch in metastabilem Zustand.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	Austenitic steel is often used as a base material for producing hydrogen storage tanks. However, the face-centred cubic (FCC) crystalline structure of the alloy is only metastable. Indeed, the manufacturing process itself (cold rolling or forming) can cause the FCC crystals to transform into the body-centred tetragonal (BCT) microstructure of martensite.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	Austenitic steel is often used as a base material for producing hydrogen storage tanks. However, the face-centred cubic (FCC) crystalline structure of the alloy is only metastable. Indeed, the manufacturing process itself (cold rolling or forming) can cause the FCC crystals to transform into the body-centred tetragonal (BCT) microstructure of martensite.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	Austenitic steel is often used as a base material for producing hydrogen storage tanks. However, the face-centred cubic (FCC) crystalline structure of the alloy is only metastable. Indeed, the manufacturing process itself (cold rolling or forming) can cause the FCC crystals to transform into the body-centred tetragonal (BCT) microstructure of martensite.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	Austenitic steel is often used as a base material for producing hydrogen storage tanks. However, the face-centred cubic (FCC) crystalline structure of the alloy is only metastable. Indeed, the manufacturing process itself (cold rolling or forming) can cause the FCC crystals to transform into the body-centred tetragonal (BCT) microstructure of martensite.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	Austenitic steel is often used as a base material for producing hydrogen storage tanks. However, the face-centred cubic (FCC) crystalline structure of the alloy is only metastable. Indeed, the manufacturing process itself (cold rolling or forming) can cause the FCC crystals to transform into the body-centred tetragonal (BCT) microstructure of martensite.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	Austenitic steel is often used as a base material for producing hydrogen storage tanks. However, the face-centred cubic (FCC) crystalline structure of the alloy is only metastable. Indeed, the manufacturing process itself (cold rolling or forming) can cause the FCC crystals to transform into the body-centred tetragonal (BCT) microstructure of martensite.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	Austenitic steel is often used as a base material for producing hydrogen storage tanks. However, the face-centred cubic (FCC) crystalline structure of the alloy is only metastable. Indeed, the manufacturing process itself (cold rolling or forming) can cause the FCC crystals to transform into the body-centred tetragonal (BCT) microstructure of martensite.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	Austenitic steel is often used as a base material for producing hydrogen storage tanks. However, the face-centred cubic (FCC) crystalline structure of the alloy is only metastable. Indeed, the manufacturing process itself (cold rolling or forming) can cause the FCC crystals to transform into the body-centred tetragonal (BCT) microstructure of martensite.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	Austenitic steel is often used as a base material for producing hydrogen storage tanks. However, the face-centred cubic (FCC) crystalline structure of the alloy is only metastable. Indeed, the manufacturing process itself (cold rolling or forming) can cause the FCC crystals to transform into the body-centred tetragonal (BCT) microstructure of martensite.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	Austenitic steel is often used as a base material for producing hydrogen storage tanks. However, the face-centred cubic (FCC) crystalline structure of the alloy is only metastable. Indeed, the manufacturing process itself (cold rolling or forming) can cause the FCC crystals to transform into the body-centred tetragonal (BCT) microstructure of martensite.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	Austenitic steel is often used as a base material for producing hydrogen storage tanks. However, the face-centred cubic (FCC) crystalline structure of the alloy is only metastable. Indeed, the manufacturing process itself (cold rolling or forming) can cause the FCC crystals to transform into the body-centred tetragonal (BCT) microstructure of martensite.

  Industrielle Messtechni...  

Show textShow cached sourceOpen source URL	Neue Technologien für effiziente und umweltfreundliche Energieversorgungssysteme gewinnen immer mehr an Bedeutung. Ein Bespiel dafür ist die Wasserstofftechnologie, die sowohl als Speichermedium als auch als Treibstoff ein großes Potenzial bietet.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	New technologies have become more important than ever for developing efficient and clean energy supply systems. Hydrogen technology is one example that holds high potential both as an accumulator and as a fuel. However, cryogenic liquid hydrogen is typically stored in special steel tanks – a circumstance that presents its own safety challenges: Should the structure of the tank fail in any way, the hydrogen can escape uncontrollably and form inflammable mixtures with other elements like oxygen present in the air. Therefore, material testing is absolutely essential in any quality control process for tanks used to store liquid hydrogen.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	New technologies have become more important than ever for developing efficient and clean energy supply systems. Hydrogen technology is one example that holds high potential both as an accumulator and as a fuel. However, cryogenic liquid hydrogen is typically stored in special steel tanks – a circumstance that presents its own safety challenges: Should the structure of the tank fail in any way, the hydrogen can escape uncontrollably and form inflammable mixtures with other elements like oxygen present in the air. Therefore, material testing is absolutely essential in any quality control process for tanks used to store liquid hydrogen.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	New technologies have become more important than ever for developing efficient and clean energy supply systems. Hydrogen technology is one example that holds high potential both as an accumulator and as a fuel. However, cryogenic liquid hydrogen is typically stored in special steel tanks – a circumstance that presents its own safety challenges: Should the structure of the tank fail in any way, the hydrogen can escape uncontrollably and form inflammable mixtures with other elements like oxygen present in the air. Therefore, material testing is absolutely essential in any quality control process for tanks used to store liquid hydrogen.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	New technologies have become more important than ever for developing efficient and clean energy supply systems. Hydrogen technology is one example that holds high potential both as an accumulator and as a fuel. However, cryogenic liquid hydrogen is typically stored in special steel tanks – a circumstance that presents its own safety challenges: Should the structure of the tank fail in any way, the hydrogen can escape uncontrollably and form inflammable mixtures with other elements like oxygen present in the air. Therefore, material testing is absolutely essential in any quality control process for tanks used to store liquid hydrogen.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	New technologies have become more important than ever for developing efficient and clean energy supply systems. Hydrogen technology is one example that holds high potential both as an accumulator and as a fuel. However, cryogenic liquid hydrogen is typically stored in special steel tanks – a circumstance that presents its own safety challenges: Should the structure of the tank fail in any way, the hydrogen can escape uncontrollably and form inflammable mixtures with other elements like oxygen present in the air. Therefore, material testing is absolutely essential in any quality control process for tanks used to store liquid hydrogen.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	New technologies have become more important than ever for developing efficient and clean energy supply systems. Hydrogen technology is one example that holds high potential both as an accumulator and as a fuel. However, cryogenic liquid hydrogen is typically stored in special steel tanks – a circumstance that presents its own safety challenges: Should the structure of the tank fail in any way, the hydrogen can escape uncontrollably and form inflammable mixtures with other elements like oxygen present in the air. Therefore, material testing is absolutely essential in any quality control process for tanks used to store liquid hydrogen.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	New technologies have become more important than ever for developing efficient and clean energy supply systems. Hydrogen technology is one example that holds high potential both as an accumulator and as a fuel. However, cryogenic liquid hydrogen is typically stored in special steel tanks – a circumstance that presents its own safety challenges: Should the structure of the tank fail in any way, the hydrogen can escape uncontrollably and form inflammable mixtures with other elements like oxygen present in the air. Therefore, material testing is absolutely essential in any quality control process for tanks used to store liquid hydrogen.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	New technologies have become more important than ever for developing efficient and clean energy supply systems. Hydrogen technology is one example that holds high potential both as an accumulator and as a fuel. However, cryogenic liquid hydrogen is typically stored in special steel tanks – a circumstance that presents its own safety challenges: Should the structure of the tank fail in any way, the hydrogen can escape uncontrollably and form inflammable mixtures with other elements like oxygen present in the air. Therefore, material testing is absolutely essential in any quality control process for tanks used to store liquid hydrogen.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	New technologies have become more important than ever for developing efficient and clean energy supply systems. Hydrogen technology is one example that holds high potential both as an accumulator and as a fuel. However, cryogenic liquid hydrogen is typically stored in special steel tanks – a circumstance that presents its own safety challenges: Should the structure of the tank fail in any way, the hydrogen can escape uncontrollably and form inflammable mixtures with other elements like oxygen present in the air. Therefore, material testing is absolutely essential in any quality control process for tanks used to store liquid hydrogen.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	New technologies have become more important than ever for developing efficient and clean energy supply systems. Hydrogen technology is one example that holds high potential both as an accumulator and as a fuel. However, cryogenic liquid hydrogen is typically stored in special steel tanks – a circumstance that presents its own safety challenges: Should the structure of the tank fail in any way, the hydrogen can escape uncontrollably and form inflammable mixtures with other elements like oxygen present in the air. Therefore, material testing is absolutely essential in any quality control process for tanks used to store liquid hydrogen.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	New technologies have become more important than ever for developing efficient and clean energy supply systems. Hydrogen technology is one example that holds high potential both as an accumulator and as a fuel. However, cryogenic liquid hydrogen is typically stored in special steel tanks – a circumstance that presents its own safety challenges: Should the structure of the tank fail in any way, the hydrogen can escape uncontrollably and form inflammable mixtures with other elements like oxygen present in the air. Therefore, material testing is absolutely essential in any quality control process for tanks used to store liquid hydrogen.

  Industrielle Messtechni...  

Show textShow cached sourceOpen source URL	Neue Technologien für effiziente und umweltfreundliche Energieversorgungssysteme gewinnen immer mehr an Bedeutung. Ein Bespiel dafür ist die Wasserstofftechnologie, die sowohl als Speichermedium als auch als Treibstoff ein großes Potenzial bietet.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	New technologies have become more important than ever for developing efficient and clean energy supply systems. Hydrogen technology is one example that holds high potential both as an accumulator and as a fuel. However, cryogenic liquid hydrogen is typically stored in special steel tanks – a circumstance that presents its own safety challenges: Should the structure of the tank fail in any way, the hydrogen can escape uncontrollably and form inflammable mixtures with other elements like oxygen present in the air. Therefore, material testing is absolutely essential in any quality control process for tanks used to store liquid hydrogen.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	New technologies have become more important than ever for developing efficient and clean energy supply systems. Hydrogen technology is one example that holds high potential both as an accumulator and as a fuel. However, cryogenic liquid hydrogen is typically stored in special steel tanks – a circumstance that presents its own safety challenges: Should the structure of the tank fail in any way, the hydrogen can escape uncontrollably and form inflammable mixtures with other elements like oxygen present in the air. Therefore, material testing is absolutely essential in any quality control process for tanks used to store liquid hydrogen.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	New technologies have become more important than ever for developing efficient and clean energy supply systems. Hydrogen technology is one example that holds high potential both as an accumulator and as a fuel. However, cryogenic liquid hydrogen is typically stored in special steel tanks – a circumstance that presents its own safety challenges: Should the structure of the tank fail in any way, the hydrogen can escape uncontrollably and form inflammable mixtures with other elements like oxygen present in the air. Therefore, material testing is absolutely essential in any quality control process for tanks used to store liquid hydrogen.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	New technologies have become more important than ever for developing efficient and clean energy supply systems. Hydrogen technology is one example that holds high potential both as an accumulator and as a fuel. However, cryogenic liquid hydrogen is typically stored in special steel tanks – a circumstance that presents its own safety challenges: Should the structure of the tank fail in any way, the hydrogen can escape uncontrollably and form inflammable mixtures with other elements like oxygen present in the air. Therefore, material testing is absolutely essential in any quality control process for tanks used to store liquid hydrogen.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	New technologies have become more important than ever for developing efficient and clean energy supply systems. Hydrogen technology is one example that holds high potential both as an accumulator and as a fuel. However, cryogenic liquid hydrogen is typically stored in special steel tanks – a circumstance that presents its own safety challenges: Should the structure of the tank fail in any way, the hydrogen can escape uncontrollably and form inflammable mixtures with other elements like oxygen present in the air. Therefore, material testing is absolutely essential in any quality control process for tanks used to store liquid hydrogen.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	New technologies have become more important than ever for developing efficient and clean energy supply systems. Hydrogen technology is one example that holds high potential both as an accumulator and as a fuel. However, cryogenic liquid hydrogen is typically stored in special steel tanks – a circumstance that presents its own safety challenges: Should the structure of the tank fail in any way, the hydrogen can escape uncontrollably and form inflammable mixtures with other elements like oxygen present in the air. Therefore, material testing is absolutely essential in any quality control process for tanks used to store liquid hydrogen.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	New technologies have become more important than ever for developing efficient and clean energy supply systems. Hydrogen technology is one example that holds high potential both as an accumulator and as a fuel. However, cryogenic liquid hydrogen is typically stored in special steel tanks – a circumstance that presents its own safety challenges: Should the structure of the tank fail in any way, the hydrogen can escape uncontrollably and form inflammable mixtures with other elements like oxygen present in the air. Therefore, material testing is absolutely essential in any quality control process for tanks used to store liquid hydrogen.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	New technologies have become more important than ever for developing efficient and clean energy supply systems. Hydrogen technology is one example that holds high potential both as an accumulator and as a fuel. However, cryogenic liquid hydrogen is typically stored in special steel tanks – a circumstance that presents its own safety challenges: Should the structure of the tank fail in any way, the hydrogen can escape uncontrollably and form inflammable mixtures with other elements like oxygen present in the air. Therefore, material testing is absolutely essential in any quality control process for tanks used to store liquid hydrogen.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	New technologies have become more important than ever for developing efficient and clean energy supply systems. Hydrogen technology is one example that holds high potential both as an accumulator and as a fuel. However, cryogenic liquid hydrogen is typically stored in special steel tanks – a circumstance that presents its own safety challenges: Should the structure of the tank fail in any way, the hydrogen can escape uncontrollably and form inflammable mixtures with other elements like oxygen present in the air. Therefore, material testing is absolutely essential in any quality control process for tanks used to store liquid hydrogen.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	New technologies have become more important than ever for developing efficient and clean energy supply systems. Hydrogen technology is one example that holds high potential both as an accumulator and as a fuel. However, cryogenic liquid hydrogen is typically stored in special steel tanks – a circumstance that presents its own safety challenges: Should the structure of the tank fail in any way, the hydrogen can escape uncontrollably and form inflammable mixtures with other elements like oxygen present in the air. Therefore, material testing is absolutely essential in any quality control process for tanks used to store liquid hydrogen.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	New technologies have become more important than ever for developing efficient and clean energy supply systems. Hydrogen technology is one example that holds high potential both as an accumulator and as a fuel. However, cryogenic liquid hydrogen is typically stored in special steel tanks – a circumstance that presents its own safety challenges: Should the structure of the tank fail in any way, the hydrogen can escape uncontrollably and form inflammable mixtures with other elements like oxygen present in the air. Therefore, material testing is absolutely essential in any quality control process for tanks used to store liquid hydrogen.

  Industrielle Messtechni...  

Show textShow cached sourceOpen source URL	Aluminium wird gerne für die architektonisch ansprechende Gestaltung von Außenfassaden und anderen, der Witterung ausgesetzten Objekten verwendet. Es gilt als leicht zu verarbeiten und punktet durch sein geringes Gewicht und die langfristige Wartungsfreiheit, erreicht durch die Aufbringung einer schützenden Eloxalschicht.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	Aluminum is often used for architecturally pleasing building façades and other structures exposed to weathering influences. Lightweight and fairly easy to work, it is also durable and requires little to no maintenance over the long term when effectively protected by an anodized coating. But to ensure the reliability of the corrosion protection, the sealing of the coating must be verified.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	Aluminum is often used for architecturally pleasing building façades and other structures exposed to weathering influences. Lightweight and fairly easy to work, it is also durable and requires little to no maintenance over the long term when effectively protected by an anodized coating. But to ensure the reliability of the corrosion protection, the sealing of the coating must be verified.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	Aluminum is often used for architecturally pleasing building façades and other structures exposed to weathering influences. Lightweight and fairly easy to work, it is also durable and requires little to no maintenance over the long term when effectively protected by an anodized coating. But to ensure the reliability of the corrosion protection, the sealing of the coating must be verified.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	Aluminum is often used for architecturally pleasing building façades and other structures exposed to weathering influences. Lightweight and fairly easy to work, it is also durable and requires little to no maintenance over the long term when effectively protected by an anodized coating. But to ensure the reliability of the corrosion protection, the sealing of the coating must be verified.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	Aluminum is often used for architecturally pleasing building façades and other structures exposed to weathering influences. Lightweight and fairly easy to work, it is also durable and requires little to no maintenance over the long term when effectively protected by an anodized coating. But to ensure the reliability of the corrosion protection, the sealing of the coating must be verified.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	Aluminum is often used for architecturally pleasing building façades and other structures exposed to weathering influences. Lightweight and fairly easy to work, it is also durable and requires little to no maintenance over the long term when effectively protected by an anodized coating. But to ensure the reliability of the corrosion protection, the sealing of the coating must be verified.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	Aluminum is often used for architecturally pleasing building façades and other structures exposed to weathering influences. Lightweight and fairly easy to work, it is also durable and requires little to no maintenance over the long term when effectively protected by an anodized coating. But to ensure the reliability of the corrosion protection, the sealing of the coating must be verified.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	Aluminum is often used for architecturally pleasing building façades and other structures exposed to weathering influences. Lightweight and fairly easy to work, it is also durable and requires little to no maintenance over the long term when effectively protected by an anodized coating. But to ensure the reliability of the corrosion protection, the sealing of the coating must be verified.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	Aluminum is often used for architecturally pleasing building façades and other structures exposed to weathering influences. Lightweight and fairly easy to work, it is also durable and requires little to no maintenance over the long term when effectively protected by an anodized coating. But to ensure the reliability of the corrosion protection, the sealing of the coating must be verified.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	Aluminum is often used for architecturally pleasing building façades and other structures exposed to weathering influences. Lightweight and fairly easy to work, it is also durable and requires little to no maintenance over the long term when effectively protected by an anodized coating. But to ensure the reliability of the corrosion protection, the sealing of the coating must be verified.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	Aluminum is often used for architecturally pleasing building façades and other structures exposed to weathering influences. Lightweight and fairly easy to work, it is also durable and requires little to no maintenance over the long term when effectively protected by an anodized coating. But to ensure the reliability of the corrosion protection, the sealing of the coating must be verified.

  Industrielle Messtechni...  

Show textShow cached sourceOpen source URL	Neue Technologien für effiziente und umweltfreundliche Energieversorgungssysteme gewinnen immer mehr an Bedeutung. Ein Bespiel dafür ist die Wasserstofftechnologie, die sowohl als Speichermedium als auch als Treibstoff ein großes Potenzial bietet.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	New technologies have become more important than ever for developing efficient and clean energy supply systems. Hydrogen technology is one example that holds high potential both as an accumulator and as a fuel. However, cryogenic liquid hydrogen is typically stored in special steel tanks – a circumstance that presents its own safety challenges: Should the structure of the tank fail in any way, the hydrogen can escape uncontrollably and form inflammable mixtures with other elements like oxygen present in the air. Therefore, material testing is absolutely essential in any quality control process for tanks used to store liquid hydrogen.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	New technologies have become more important than ever for developing efficient and clean energy supply systems. Hydrogen technology is one example that holds high potential both as an accumulator and as a fuel. However, cryogenic liquid hydrogen is typically stored in special steel tanks – a circumstance that presents its own safety challenges: Should the structure of the tank fail in any way, the hydrogen can escape uncontrollably and form inflammable mixtures with other elements like oxygen present in the air. Therefore, material testing is absolutely essential in any quality control process for tanks used to store liquid hydrogen.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	New technologies have become more important than ever for developing efficient and clean energy supply systems. Hydrogen technology is one example that holds high potential both as an accumulator and as a fuel. However, cryogenic liquid hydrogen is typically stored in special steel tanks – a circumstance that presents its own safety challenges: Should the structure of the tank fail in any way, the hydrogen can escape uncontrollably and form inflammable mixtures with other elements like oxygen present in the air. Therefore, material testing is absolutely essential in any quality control process for tanks used to store liquid hydrogen.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	New technologies have become more important than ever for developing efficient and clean energy supply systems. Hydrogen technology is one example that holds high potential both as an accumulator and as a fuel. However, cryogenic liquid hydrogen is typically stored in special steel tanks – a circumstance that presents its own safety challenges: Should the structure of the tank fail in any way, the hydrogen can escape uncontrollably and form inflammable mixtures with other elements like oxygen present in the air. Therefore, material testing is absolutely essential in any quality control process for tanks used to store liquid hydrogen.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	New technologies have become more important than ever for developing efficient and clean energy supply systems. Hydrogen technology is one example that holds high potential both as an accumulator and as a fuel. However, cryogenic liquid hydrogen is typically stored in special steel tanks – a circumstance that presents its own safety challenges: Should the structure of the tank fail in any way, the hydrogen can escape uncontrollably and form inflammable mixtures with other elements like oxygen present in the air. Therefore, material testing is absolutely essential in any quality control process for tanks used to store liquid hydrogen.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	New technologies have become more important than ever for developing efficient and clean energy supply systems. Hydrogen technology is one example that holds high potential both as an accumulator and as a fuel. However, cryogenic liquid hydrogen is typically stored in special steel tanks – a circumstance that presents its own safety challenges: Should the structure of the tank fail in any way, the hydrogen can escape uncontrollably and form inflammable mixtures with other elements like oxygen present in the air. Therefore, material testing is absolutely essential in any quality control process for tanks used to store liquid hydrogen.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	New technologies have become more important than ever for developing efficient and clean energy supply systems. Hydrogen technology is one example that holds high potential both as an accumulator and as a fuel. However, cryogenic liquid hydrogen is typically stored in special steel tanks – a circumstance that presents its own safety challenges: Should the structure of the tank fail in any way, the hydrogen can escape uncontrollably and form inflammable mixtures with other elements like oxygen present in the air. Therefore, material testing is absolutely essential in any quality control process for tanks used to store liquid hydrogen.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	New technologies have become more important than ever for developing efficient and clean energy supply systems. Hydrogen technology is one example that holds high potential both as an accumulator and as a fuel. However, cryogenic liquid hydrogen is typically stored in special steel tanks – a circumstance that presents its own safety challenges: Should the structure of the tank fail in any way, the hydrogen can escape uncontrollably and form inflammable mixtures with other elements like oxygen present in the air. Therefore, material testing is absolutely essential in any quality control process for tanks used to store liquid hydrogen.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	New technologies have become more important than ever for developing efficient and clean energy supply systems. Hydrogen technology is one example that holds high potential both as an accumulator and as a fuel. However, cryogenic liquid hydrogen is typically stored in special steel tanks – a circumstance that presents its own safety challenges: Should the structure of the tank fail in any way, the hydrogen can escape uncontrollably and form inflammable mixtures with other elements like oxygen present in the air. Therefore, material testing is absolutely essential in any quality control process for tanks used to store liquid hydrogen.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	New technologies have become more important than ever for developing efficient and clean energy supply systems. Hydrogen technology is one example that holds high potential both as an accumulator and as a fuel. However, cryogenic liquid hydrogen is typically stored in special steel tanks – a circumstance that presents its own safety challenges: Should the structure of the tank fail in any way, the hydrogen can escape uncontrollably and form inflammable mixtures with other elements like oxygen present in the air. Therefore, material testing is absolutely essential in any quality control process for tanks used to store liquid hydrogen.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	New technologies have become more important than ever for developing efficient and clean energy supply systems. Hydrogen technology is one example that holds high potential both as an accumulator and as a fuel. However, cryogenic liquid hydrogen is typically stored in special steel tanks – a circumstance that presents its own safety challenges: Should the structure of the tank fail in any way, the hydrogen can escape uncontrollably and form inflammable mixtures with other elements like oxygen present in the air. Therefore, material testing is absolutely essential in any quality control process for tanks used to store liquid hydrogen.

  Industrielle Messtechni...  

Show textShow cached sourceOpen source URL	Verglichen mit anderen Methoden ist die Röntgenfluoreszenz-Analyse einfach durchzuführen: Die Probe ist schnell präpariert und als Verbrauchsmaterial werden lediglich kleine Stücke Plastikfolie benötigt, im Gegensatz zu anderen Methoden, die Analysegase wie Argon oder aufbereitetes, reines Wasser einsetzen.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	The quality of metallic coatings depends heavily on the formulation of the plating bath, which consequently needs to be monitored. Compared with other methods, XRF (x-ray fluorescence) analysis of such solutions is straightforward: sample preparation is quick, and the only consumables required are small pieces of plastic foil, as opposed to other analytical methods where gases (Ar) or purified water are used.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	The quality of metallic coatings depends heavily on the formulation of the plating bath, which consequently needs to be monitored. Compared with other methods, XRF (x-ray fluorescence) analysis of such solutions is straightforward: sample preparation is quick, and the only consumables required are small pieces of plastic foil, as opposed to other analytical methods where gases (Ar) or purified water are used.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	The quality of metallic coatings depends heavily on the formulation of the plating bath, which consequently needs to be monitored. Compared with other methods, XRF (x-ray fluorescence) analysis of such solutions is straightforward: sample preparation is quick, and the only consumables required are small pieces of plastic foil, as opposed to other analytical methods where gases (Ar) or purified water are used.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	The quality of metallic coatings depends heavily on the formulation of the plating bath, which consequently needs to be monitored. Compared with other methods, XRF (x-ray fluorescence) analysis of such solutions is straightforward: sample preparation is quick, and the only consumables required are small pieces of plastic foil, as opposed to other analytical methods where gases (Ar) or purified water are used.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	The quality of metallic coatings depends heavily on the formulation of the plating bath, which consequently needs to be monitored. Compared with other methods, XRF (x-ray fluorescence) analysis of such solutions is straightforward: sample preparation is quick, and the only consumables required are small pieces of plastic foil, as opposed to other analytical methods where gases (Ar) or purified water are used.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	The quality of metallic coatings depends heavily on the formulation of the plating bath, which consequently needs to be monitored. Compared with other methods, XRF (x-ray fluorescence) analysis of such solutions is straightforward: sample preparation is quick, and the only consumables required are small pieces of plastic foil, as opposed to other analytical methods where gases (Ar) or purified water are used.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	The quality of metallic coatings depends heavily on the formulation of the plating bath, which consequently needs to be monitored. Compared with other methods, XRF (x-ray fluorescence) analysis of such solutions is straightforward: sample preparation is quick, and the only consumables required are small pieces of plastic foil, as opposed to other analytical methods where gases (Ar) or purified water are used.

  Industrielle Messtechni...  

Show textShow cached sourceOpen source URL	Aluminium wird gerne für die architektonisch ansprechende Gestaltung von Außenfassaden und anderen, der Witterung ausgesetzten Objekten verwendet. Es gilt als leicht zu verarbeiten und punktet durch sein geringes Gewicht und die langfristige Wartungsfreiheit, erreicht durch die Aufbringung einer schützenden Eloxalschicht.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	Aluminum is often used for architecturally pleasing building façades and other structures exposed to weathering influences. Lightweight and fairly easy to work, it is also durable and requires little to no maintenance over the long term when effectively protected by an anodized coating. But to ensure the reliability of the corrosion protection, the sealing of the coating must be verified.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	Aluminum is often used for architecturally pleasing building façades and other structures exposed to weathering influences. Lightweight and fairly easy to work, it is also durable and requires little to no maintenance over the long term when effectively protected by an anodized coating. But to ensure the reliability of the corrosion protection, the sealing of the coating must be verified.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	Aluminum is often used for architecturally pleasing building façades and other structures exposed to weathering influences. Lightweight and fairly easy to work, it is also durable and requires little to no maintenance over the long term when effectively protected by an anodized coating. But to ensure the reliability of the corrosion protection, the sealing of the coating must be verified.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	Aluminum is often used for architecturally pleasing building façades and other structures exposed to weathering influences. Lightweight and fairly easy to work, it is also durable and requires little to no maintenance over the long term when effectively protected by an anodized coating. But to ensure the reliability of the corrosion protection, the sealing of the coating must be verified.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	Aluminum is often used for architecturally pleasing building façades and other structures exposed to weathering influences. Lightweight and fairly easy to work, it is also durable and requires little to no maintenance over the long term when effectively protected by an anodized coating. But to ensure the reliability of the corrosion protection, the sealing of the coating must be verified.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	Aluminum is often used for architecturally pleasing building façades and other structures exposed to weathering influences. Lightweight and fairly easy to work, it is also durable and requires little to no maintenance over the long term when effectively protected by an anodized coating. But to ensure the reliability of the corrosion protection, the sealing of the coating must be verified.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	Aluminum is often used for architecturally pleasing building façades and other structures exposed to weathering influences. Lightweight and fairly easy to work, it is also durable and requires little to no maintenance over the long term when effectively protected by an anodized coating. But to ensure the reliability of the corrosion protection, the sealing of the coating must be verified.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	Aluminum is often used for architecturally pleasing building façades and other structures exposed to weathering influences. Lightweight and fairly easy to work, it is also durable and requires little to no maintenance over the long term when effectively protected by an anodized coating. But to ensure the reliability of the corrosion protection, the sealing of the coating must be verified.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	Aluminum is often used for architecturally pleasing building façades and other structures exposed to weathering influences. Lightweight and fairly easy to work, it is also durable and requires little to no maintenance over the long term when effectively protected by an anodized coating. But to ensure the reliability of the corrosion protection, the sealing of the coating must be verified.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	Aluminum is often used for architecturally pleasing building façades and other structures exposed to weathering influences. Lightweight and fairly easy to work, it is also durable and requires little to no maintenance over the long term when effectively protected by an anodized coating. But to ensure the reliability of the corrosion protection, the sealing of the coating must be verified.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	Aluminum is often used for architecturally pleasing building façades and other structures exposed to weathering influences. Lightweight and fairly easy to work, it is also durable and requires little to no maintenance over the long term when effectively protected by an anodized coating. But to ensure the reliability of the corrosion protection, the sealing of the coating must be verified.

  Industrielle Messtechni...  

Show textShow cached sourceOpen source URL	Fischer als Arbeitgeber
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	FISCHER as an Employer
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	FISCHER comme employeur
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	Ofertas de empleo en FISCHER
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	Lavorate con noi
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	FISCHER als werkgever
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	FISCHER kui tööandja
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	FISCHER kaip darbdavys
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	FISCHER jako pracodawca
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	Вакансии в FISCHER
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	Bir işveren olarak FISCHER
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	FISCHER kā darba devējs

  Institute for Scientifi...  

Show textShow cached sourceOpen source URL	Die Stärke von IfG liegt sowohl in der Industrie als auch in der Grundlagenforschung
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	IfG’s strengths are in both industrial and basic-science applications
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	Les forces de l'IfG résident dans les applications industrielles comme scientifiques
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	Los puntos fuertes del IfG están en las aplicaciones industriales y de ciencias básicas
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	L'efficacia di IfG si attua in applicazioni sia industriali sia di base
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	Het IfG heeft een goede reputatie voor zowel industriële als fundamenteel wetenschappelijke toepassingen
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	IfG tugevused on nii tööstus- kui ka põhiteaduslikes rakendustes
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	IfG stipriosios pusės yra tiek pramoninės, tiek pagrindinės mokslo srityse
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	Przyrządy IfG mają zastosowania zarówno przemysłowe, jak i naukowe
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	Основное направление работы института IfG заключается в выполнении как прикладных промышленных, так и общих научных задач
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	IfG hem endüstriyel hem de temel bilim uygulamalarında güçlüdür
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	IfG stiprās puses ir gan rūpnieciskās, gan fundamentālās dabas zinātnēs

  Industrielle Messtechni...  

Show textShow cached sourceOpen source URL	Feuerverzinkung als Korrosionsschutz
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	Hot-Dip Galvanization as Corrosion Protection
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	Hot-Dip Galvanization as Corrosion Protection
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	Hot-Dip Galvanization as Corrosion Protection
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	Hot-Dip Galvanization as Corrosion Protection
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	Hot-Dip Galvanization as Corrosion Protection
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	Hot-Dip Galvanization as Corrosion Protection
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	Hot-Dip Galvanization as Corrosion Protection
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	Hot-Dip Galvanization as Corrosion Protection
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	Hot-Dip Galvanization as Corrosion Protection
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	Hot-Dip Galvanization as Corrosion Protection
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	Hot-Dip Galvanization as Corrosion Protection

  Lösungen: Metallischer ...  

Show textShow cached sourceOpen source URL	Feuerverzinkung als Korrosionsschutz
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	Hot-Dip Galvanization as Corrosion Protection
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	Hot-Dip Galvanization as Corrosion Protection
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	Hot-Dip Galvanization as Corrosion Protection
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	Hot-Dip Galvanization as Corrosion Protection
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	Hot-Dip Galvanization as Corrosion Protection
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	Hot-Dip Galvanization as Corrosion Protection
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	Hot-Dip Galvanization as Corrosion Protection
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	Hot-Dip Galvanization as Corrosion Protection
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	Hot-Dip Galvanization as Corrosion Protection

  Industrielle Messtechni...  

Show textShow cached sourceOpen source URL	Als Material werden gesinterte Carbidhartmetalle verwendet, die in den meisten Fällen hauptsächlich aus Wolframcarbid bestehen. Dazu kommen in sehr geringen Mengen Additive wie Titancarbid, Tantalcarbid, Chromcarbid oder Vanadiumcarbid, die je nach Zusammensetzung die Materialeigenschaften des fertigen Hartmetalls wesentlich beeinflussen.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	The cemented carbides most often employed industrially are made by sintering grains of tungsten carbide with a metallic binder, frequently cobalt. Tiny amounts of titanium, tantalum, chromium and/or vanadium carbides are also used; depending on the final composition, these additives significantly influence the material properties – and thus the performance – of the finished material.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	The cemented carbides most often employed industrially are made by sintering grains of tungsten carbide with a metallic binder, frequently cobalt. Tiny amounts of titanium, tantalum, chromium and/or vanadium carbides are also used; depending on the final composition, these additives significantly influence the material properties – and thus the performance – of the finished material.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	The cemented carbides most often employed industrially are made by sintering grains of tungsten carbide with a metallic binder, frequently cobalt. Tiny amounts of titanium, tantalum, chromium and/or vanadium carbides are also used; depending on the final composition, these additives significantly influence the material properties – and thus the performance – of the finished material.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	The cemented carbides most often employed industrially are made by sintering grains of tungsten carbide with a metallic binder, frequently cobalt. Tiny amounts of titanium, tantalum, chromium and/or vanadium carbides are also used; depending on the final composition, these additives significantly influence the material properties – and thus the performance – of the finished material.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	The cemented carbides most often employed industrially are made by sintering grains of tungsten carbide with a metallic binder, frequently cobalt. Tiny amounts of titanium, tantalum, chromium and/or vanadium carbides are also used; depending on the final composition, these additives significantly influence the material properties – and thus the performance – of the finished material.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	The cemented carbides most often employed industrially are made by sintering grains of tungsten carbide with a metallic binder, frequently cobalt. Tiny amounts of titanium, tantalum, chromium and/or vanadium carbides are also used; depending on the final composition, these additives significantly influence the material properties – and thus the performance – of the finished material.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	The cemented carbides most often employed industrially are made by sintering grains of tungsten carbide with a metallic binder, frequently cobalt. Tiny amounts of titanium, tantalum, chromium and/or vanadium carbides are also used; depending on the final composition, these additives significantly influence the material properties – and thus the performance – of the finished material.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	The cemented carbides most often employed industrially are made by sintering grains of tungsten carbide with a metallic binder, frequently cobalt. Tiny amounts of titanium, tantalum, chromium and/or vanadium carbides are also used; depending on the final composition, these additives significantly influence the material properties – and thus the performance – of the finished material.

  Industrielle Messtechni...  

Show textShow cached sourceOpen source URL	Rechts: Messung auf 10 “bead spacern” mit einer max. Kraft von 10 mN. Das Verhältnis aus bleibender Verformung und maximaler Verformung kann als Maß der Regenerationsfähigkeit betrachtet werden.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	Fig. 3b: Measurements on 10 bead spacers with max. load of 10 mN. The residual displacement divided by total displacement can be considered the recovery rate.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	Fig. 3b: Measurements on 10 bead spacers with max. load of 10 mN. The residual displacement divided by total displacement can be considered the recovery rate.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	Fig. 3b: Measurements on 10 bead spacers with max. load of 10 mN. The residual displacement divided by total displacement can be considered the recovery rate.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	Fig. 3b: Measurements on 10 bead spacers with max. load of 10 mN. The residual displacement divided by total displacement can be considered the recovery rate.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	Fig. 3b: Measurements on 10 bead spacers with max. load of 10 mN. The residual displacement divided by total displacement can be considered the recovery rate.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	Fig. 3b: Measurements on 10 bead spacers with max. load of 10 mN. The residual displacement divided by total displacement can be considered the recovery rate.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	Fig. 3b: Measurements on 10 bead spacers with max. load of 10 mN. The residual displacement divided by total displacement can be considered the recovery rate.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	Fig. 3b: Measurements on 10 bead spacers with max. load of 10 mN. The residual displacement divided by total displacement can be considered the recovery rate.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	Fig. 3b: Measurements on 10 bead spacers with max. load of 10 mN. The residual displacement divided by total displacement can be considered the recovery rate.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	Fig. 3b: Measurements on 10 bead spacers with max. load of 10 mN. The residual displacement divided by total displacement can be considered the recovery rate.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	Fig. 3b: Measurements on 10 bead spacers with max. load of 10 mN. The residual displacement divided by total displacement can be considered the recovery rate.

  Fachartikel | Helmut Fi...  

Show textShow cached sourceOpen source URL	Fischer als Arbeitgeber
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	FISCHER comme employeur
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	Ofertas de empleo en FISCHER
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	FISCHER als werkgever
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	FISCHER kui tööandja
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	FISCHER kaip darbdavys
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	FISCHER jako pracodawca
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	Вакансии в FISCHER
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	Bir işveren olarak FISCHER
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	FISCHER kā darba devējs

  Industrielle Messtechni...  

Show textShow cached sourceOpen source URL	Im Vergleich zu anderen Beschichtungsprozessen wie etwa Galvanisieren oder Bedampfen ist eine hohe Abscheidungsrate möglich. Das als Draht zugeführte Aluminium wird geschmolzen und als mikrometergroße Partikel durch ein Gebläse Richtung Oberfläche geschleudert, sodass eine widerstandsfähige Schutzschicht entsteht.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	Thermal spraying techniques are very effective for applying thick layers over large areas, as the hot coating materials are literally squirted onto the surface. Com-pared to other coating processes, such as electroplating or chemical vapour deposition, the rates of deposition are high: the aluminium is fed in wire form, molten and accelerated as micrometre-sized particles towards the substrate, forming a tough, protective casing.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	Thermal spraying techniques are very effective for applying thick layers over large areas, as the hot coating materials are literally squirted onto the surface. Com-pared to other coating processes, such as electroplating or chemical vapour deposition, the rates of deposition are high: the aluminium is fed in wire form, molten and accelerated as micrometre-sized particles towards the substrate, forming a tough, protective casing.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	Thermal spraying techniques are very effective for applying thick layers over large areas, as the hot coating materials are literally squirted onto the surface. Com-pared to other coating processes, such as electroplating or chemical vapour deposition, the rates of deposition are high: the aluminium is fed in wire form, molten and accelerated as micrometre-sized particles towards the substrate, forming a tough, protective casing.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	Thermal spraying techniques are very effective for applying thick layers over large areas, as the hot coating materials are literally squirted onto the surface. Com-pared to other coating processes, such as electroplating or chemical vapour deposition, the rates of deposition are high: the aluminium is fed in wire form, molten and accelerated as micrometre-sized particles towards the substrate, forming a tough, protective casing.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	Thermal spraying techniques are very effective for applying thick layers over large areas, as the hot coating materials are literally squirted onto the surface. Com-pared to other coating processes, such as electroplating or chemical vapour deposition, the rates of deposition are high: the aluminium is fed in wire form, molten and accelerated as micrometre-sized particles towards the substrate, forming a tough, protective casing.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	Thermal spraying techniques are very effective for applying thick layers over large areas, as the hot coating materials are literally squirted onto the surface. Com-pared to other coating processes, such as electroplating or chemical vapour deposition, the rates of deposition are high: the aluminium is fed in wire form, molten and accelerated as micrometre-sized particles towards the substrate, forming a tough, protective casing.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	Thermal spraying techniques are very effective for applying thick layers over large areas, as the hot coating materials are literally squirted onto the surface. Com-pared to other coating processes, such as electroplating or chemical vapour deposition, the rates of deposition are high: the aluminium is fed in wire form, molten and accelerated as micrometre-sized particles towards the substrate, forming a tough, protective casing.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	Thermal spraying techniques are very effective for applying thick layers over large areas, as the hot coating materials are literally squirted onto the surface. Com-pared to other coating processes, such as electroplating or chemical vapour deposition, the rates of deposition are high: the aluminium is fed in wire form, molten and accelerated as micrometre-sized particles towards the substrate, forming a tough, protective casing.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	Thermal spraying techniques are very effective for applying thick layers over large areas, as the hot coating materials are literally squirted onto the surface. Com-pared to other coating processes, such as electroplating or chemical vapour deposition, the rates of deposition are high: the aluminium is fed in wire form, molten and accelerated as micrometre-sized particles towards the substrate, forming a tough, protective casing.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	Thermal spraying techniques are very effective for applying thick layers over large areas, as the hot coating materials are literally squirted onto the surface. Com-pared to other coating processes, such as electroplating or chemical vapour deposition, the rates of deposition are high: the aluminium is fed in wire form, molten and accelerated as micrometre-sized particles towards the substrate, forming a tough, protective casing.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	Thermal spraying techniques are very effective for applying thick layers over large areas, as the hot coating materials are literally squirted onto the surface. Com-pared to other coating processes, such as electroplating or chemical vapour deposition, the rates of deposition are high: the aluminium is fed in wire form, molten and accelerated as micrometre-sized particles towards the substrate, forming a tough, protective casing.

  Lösungen: Metallischer ...  

Show textShow cached sourceOpen source URL	Stahlblech-Dachbaustoffe mit glänzender oder matter Polyesterbeschichtung haben Lackschichten mit einer Dicke von 27-38 µm. Sie gelten als "Dünnschicht-Beschichtungen" und sind in der Regel mit einer schriftlichen Garantie von 10 Jahren versehen.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	Steel sheet roofing materials coated in gloss or matte polyester typically have inner lacquer layers measuring between 27-38 µm. They are considered “thin-layered coatings” and are generally covered by a written guarantee of 10 years.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	Steel sheet roofing materials coated in gloss or matte polyester typically have inner lacquer layers measuring between 27-38 µm. They are considered “thin-layered coatings” and are generally covered by a written guarantee of 10 years.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	Steel sheet roofing materials coated in gloss or matte polyester typically have inner lacquer layers measuring between 27-38 µm. They are considered “thin-layered coatings” and are generally covered by a written guarantee of 10 years.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	Steel sheet roofing materials coated in gloss or matte polyester typically have inner lacquer layers measuring between 27-38 µm. They are considered “thin-layered coatings” and are generally covered by a written guarantee of 10 years.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	Steel sheet roofing materials coated in gloss or matte polyester typically have inner lacquer layers measuring between 27-38 µm. They are considered “thin-layered coatings” and are generally covered by a written guarantee of 10 years.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	Steel sheet roofing materials coated in gloss or matte polyester typically have inner lacquer layers measuring between 27-38 µm. They are considered “thin-layered coatings” and are generally covered by a written guarantee of 10 years.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	Steel sheet roofing materials coated in gloss or matte polyester typically have inner lacquer layers measuring between 27-38 µm. They are considered “thin-layered coatings” and are generally covered by a written guarantee of 10 years.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	Steel sheet roofing materials coated in gloss or matte polyester typically have inner lacquer layers measuring between 27-38 µm. They are considered “thin-layered coatings” and are generally covered by a written guarantee of 10 years.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	Steel sheet roofing materials coated in gloss or matte polyester typically have inner lacquer layers measuring between 27-38 µm. They are considered “thin-layered coatings” and are generally covered by a written guarantee of 10 years.

  Applikationslabore welt...  

Show textShow cached sourceOpen source URL	Alle Applikationslabore sind sowohl untereinander als auch mit Hochschulen, Institutionen und der Wirtschaft bestens vernetzt. Durch den ständigen Wissensaustausch sorgen wir dafür, dass weltweit ein hohes und topaktuelles Know-How sowie bestmögliche Beratung zur Verfügung stehen.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	All of our application laboratories have connections within the Fischer Group as well as with universities, institutions and business. This constant exchange of knowledge ensures access to cutting-edge expertise and exceptional consultation worldwide. Besides providing customized training, either at our Labs or on your company premises, our technical experts are also happy to assist you with interpreting your results.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	Tous nos laboratoires d'application disposent de connexions au sein du Fischer Group ainsi qu'avec des universités, institutions et entreprises. Cet échange constant de connaissances garantit l'accès à une expertise de pointe et un conseil exceptionnel à travers le monde. En plus de fournir une formation personnalisée, dans nos laboratoires ou les locaux de notre entreprise, nos experts techniques se tiennent également à votre disposition pour vous aider à interpréter vos résultats.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	Todos nuestros laboratorios de aplicaciones tienen conexiones dentro del Grupo Fischer, así como con universidades, instituciones y empresas. Este intercambio continuo de conocimiento garantiza el acceso a unos conocimientos expertos avanzados y a una asesoría excepcional en todo el mundo. Además de la formación individualizada en nuestros laboratorios o en las instalaciones de su empresa, nuestros expertos técnicos estarán encantados de ayudarle a interpretar sus resultados.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	Tutti i nostri laboratori applicativi sono collegati al gruppo Fischer, nonché a università, istituzioni e aziende. Questo scambio continuo di conoscenza garantisce l'accesso a competenza all'avanguardia e consulenze eccezionali a livello mondiale. Oltre alla formazione personalizzata presso i nostri laboratori o nei locali dell'azienda, i nostri tecnici esperti saranno lieti di assistervi nell'interpretazione dei risultati.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	Al onze toepassingslaboratoria hebben banden binnen de Fischer Groep en met universiteiten, instituten en het bedrijfsleven. Deze constante kennisuitwisseling garandeert toegang tot geavanceerde expertise en uitzonder-lijke advisering wereldwijd. Naast het aanbieden van aangepaste training, zowel in onze laboratoria als in uw bedrijf, helpen onze technische experts u ook graag bij de interpretatie van uw meetresultaten.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	Kõikidel meie rakenduslaboritel on ühendused Fischeri kontserni, samuti ülikoolide, institutsioonide ja ettevõtete vahel. See pidev teadmiste vahetamine tagab juurdepääsu tipptasemel teadmistele ja erakorralistele konsultatsioonidele kogu maailmas. Meie kohandatud koolituse pakkumine kas meie laborites või ettevõtte ruumides on ka meie tehnilised eksperdid, kes aitavad teil tulemusi tõlgendada.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	Visos mūsų paraiškų laboratorijos jungiasi "Fischer" grupės, taip pat su universitetais, institucijomis ir verslu. Šis nuolatinis žinių mainus užtikrina galimybę naudotis naujausia patirtimi ir išskirtinėmis konsultacijomis visame pasaulyje. Mūsų specialistai taip pat džiaugiasi galėdama suprasti savo rezultatus, be individualizuoto mokymo teikimo mūsų laboratorijose arba jūsų įmonės patalpose.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	Wszystkie nasze laboratoria aplikacyjne współpracują nie tylko z grupą Fischer Group, ale również wieloma uniwersytetami, organizacjami i firmami. Dzięki nieustannej wymianie wiedzy możemy korzystać z najnowocześniejszych technologii i pomocy ekspertów z całego świata. Oprócz specjalistycznych szkoleń prowadzonych w naszych laboratoriach lub w zakładzie klienta, nasi eksperci pomagają również w interpretacji wyników.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	Все исследовательские лаборатории компании тесно взаимодействуют с группой Fischer Group, а также с учебными заведениями, государственными организациями и представителями бизнеса. Такое взаимодействие обеспечивает доступ к данным новейших исследований и позволяет осуществлять обмен знаниями на международном уровне. Кроме индивидуальных курсов обучения, проводимых как в наших лабораториях, так и на объектах заказчика, технические специалисты нашей компании будут рады оказать помощь в анализе результатов измерений.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	Tüm uygulama laboratuvarlarımızın Fischer Group ve ayrıca üniversiteler, enstitüler ve işletmelerle bağlantıları bulunmaktadır. Bu sürekli bilgi alışverişi, dünya genelinde en yeni uzmanlık bilgilerine ve sıra dışı danışmanlığa erişimi mümkün kılmaktadır. Teknik uzmanlarımız özel eğitim sunmanın yanı sıra, elde ettiğiniz sonuçları bizim Laboratuvarlarımızda veya sizin şirket tesislerinizde değerlendirmeye seve seve yardım edeceklerdir.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	Visām mūsu pieteikumu laboratorijām ir savienojumi Fischer grupas ietvaros, kā arī ar universitātēm, iestādēm un uzņēmumiem. Šī pastāvīgā zināšanu apmaiņa nodrošina piekļuvi progresīvām zināšanām un ārkārtas konsultācijām visā pasaulē. Papildus pielāgotu apmācību nodrošināšanai mūsu laboratorijās vai uzņēmuma telpās mūsu tehniskie speciālisti ar prieku palīdzēs jums interpretēt savus rezultātus.

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Show textShow cached sourceOpen source URL	Als Beispiel wurden jeweils 4 Bleche aus den Legierun­gen AlMg3 und AlMgSi0,5 farbeloxiert. Im Ergebnis zeigten sich zwei unterschiedliche Blautöne. Die elektrische Leitfähigkeit der beiden Grundmaterialien weist deutliche Unterschiede auf, wie in Tabelle 1 zu sehen ist.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	As an example, four sheets each of the alloys AIMg3 and AlMgSi0.5 were color-anodized all together, resulting in two different shades of blue. The electrical conductivity of the two base materials showed significant differences, as seen in Table 1.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	As an example, four sheets each of the alloys AIMg3 and AlMgSi0.5 were color-anodized all together, resulting in two different shades of blue. The electrical conductivity of the two base materials showed significant differences, as seen in Table 1.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	As an example, four sheets each of the alloys AIMg3 and AlMgSi0.5 were color-anodized all together, resulting in two different shades of blue. The electrical conductivity of the two base materials showed significant differences, as seen in Table 1.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	As an example, four sheets each of the alloys AIMg3 and AlMgSi0.5 were color-anodized all together, resulting in two different shades of blue. The electrical conductivity of the two base materials showed significant differences, as seen in Table 1.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	As an example, four sheets each of the alloys AIMg3 and AlMgSi0.5 were color-anodized all together, resulting in two different shades of blue. The electrical conductivity of the two base materials showed significant differences, as seen in Table 1.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	As an example, four sheets each of the alloys AIMg3 and AlMgSi0.5 were color-anodized all together, resulting in two different shades of blue. The electrical conductivity of the two base materials showed significant differences, as seen in Table 1.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	As an example, four sheets each of the alloys AIMg3 and AlMgSi0.5 were color-anodized all together, resulting in two different shades of blue. The electrical conductivity of the two base materials showed significant differences, as seen in Table 1.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	As an example, four sheets each of the alloys AIMg3 and AlMgSi0.5 were color-anodized all together, resulting in two different shades of blue. The electrical conductivity of the two base materials showed significant differences, as seen in Table 1.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	As an example, four sheets each of the alloys AIMg3 and AlMgSi0.5 were color-anodized all together, resulting in two different shades of blue. The electrical conductivity of the two base materials showed significant differences, as seen in Table 1.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	As an example, four sheets each of the alloys AIMg3 and AlMgSi0.5 were color-anodized all together, resulting in two different shades of blue. The electrical conductivity of the two base materials showed significant differences, as seen in Table 1.
Compare text pagesCompare HTM pagesOpen source URLOpen target URLDefine helmut-fischer.fr as primary domain	As an example, four sheets each of the alloys AIMg3 and AlMgSi0.5 were color-anodized all together, resulting in two different shades of blue. The electrical conductivity of the two base materials showed significant differences, as seen in Table 1.