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Gleitlager, wie sie für Röntgenröhren bei medizinischen Geräten eingesetzt werden, bewegen sich auf einem dünnen Flüssigkeitsfilm. Weisen die Oberflächen Beschädigungen wie etwa Haarrisse auf, welche z. B. im mechanischen Bearbeitungsprozess der Bauteile entstehen können, so sind die Gleiteigenschaften auf Dauer nicht zu gewährleisten.
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Bearings, such as those used for holding and smoothly moving the X-ray tubes in medical devices, are actually gliding on a thin film of liquid. If the surfaces have any damage, such as the thin fractures that can occur during the machining of the components, the sliding properties cannot be ensured for the device’s entire service lifetime. Technically, such cracks near the surface are difficult to detect, as optical inspection methods very quickly reach their limits with fine hairline cracks. However, measuring the electrical conductivity of the material provides a simple and quick way to detect even tiny fissures, as this method is very sensitive to structural inconsistencies.
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Bearings, such as those used for holding and smoothly moving the X-ray tubes in medical devices, are actually gliding on a thin film of liquid. If the surfaces have any damage, such as the thin fractures that can occur during the machining of the components, the sliding properties cannot be ensured for the device’s entire service lifetime. Technically, such cracks near the surface are difficult to detect, as optical inspection methods very quickly reach their limits with fine hairline cracks. However, measuring the electrical conductivity of the material provides a simple and quick way to detect even tiny fissures, as this method is very sensitive to structural inconsistencies.
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Bearings, such as those used for holding and smoothly moving the X-ray tubes in medical devices, are actually gliding on a thin film of liquid. If the surfaces have any damage, such as the thin fractures that can occur during the machining of the components, the sliding properties cannot be ensured for the device’s entire service lifetime. Technically, such cracks near the surface are difficult to detect, as optical inspection methods very quickly reach their limits with fine hairline cracks. However, measuring the electrical conductivity of the material provides a simple and quick way to detect even tiny fissures, as this method is very sensitive to structural inconsistencies.
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Bearings, such as those used for holding and smoothly moving the X-ray tubes in medical devices, are actually gliding on a thin film of liquid. If the surfaces have any damage, such as the thin fractures that can occur during the machining of the components, the sliding properties cannot be ensured for the device’s entire service lifetime. Technically, such cracks near the surface are difficult to detect, as optical inspection methods very quickly reach their limits with fine hairline cracks. However, measuring the electrical conductivity of the material provides a simple and quick way to detect even tiny fissures, as this method is very sensitive to structural inconsistencies.
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Bearings, such as those used for holding and smoothly moving the X-ray tubes in medical devices, are actually gliding on a thin film of liquid. If the surfaces have any damage, such as the thin fractures that can occur during the machining of the components, the sliding properties cannot be ensured for the device’s entire service lifetime. Technically, such cracks near the surface are difficult to detect, as optical inspection methods very quickly reach their limits with fine hairline cracks. However, measuring the electrical conductivity of the material provides a simple and quick way to detect even tiny fissures, as this method is very sensitive to structural inconsistencies.
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Bearings, such as those used for holding and smoothly moving the X-ray tubes in medical devices, are actually gliding on a thin film of liquid. If the surfaces have any damage, such as the thin fractures that can occur during the machining of the components, the sliding properties cannot be ensured for the device’s entire service lifetime. Technically, such cracks near the surface are difficult to detect, as optical inspection methods very quickly reach their limits with fine hairline cracks. However, measuring the electrical conductivity of the material provides a simple and quick way to detect even tiny fissures, as this method is very sensitive to structural inconsistencies.
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Bearings, such as those used for holding and smoothly moving the X-ray tubes in medical devices, are actually gliding on a thin film of liquid. If the surfaces have any damage, such as the thin fractures that can occur during the machining of the components, the sliding properties cannot be ensured for the device’s entire service lifetime. Technically, such cracks near the surface are difficult to detect, as optical inspection methods very quickly reach their limits with fine hairline cracks. However, measuring the electrical conductivity of the material provides a simple and quick way to detect even tiny fissures, as this method is very sensitive to structural inconsistencies.
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Bearings, such as those used for holding and smoothly moving the X-ray tubes in medical devices, are actually gliding on a thin film of liquid. If the surfaces have any damage, such as the thin fractures that can occur during the machining of the components, the sliding properties cannot be ensured for the device’s entire service lifetime. Technically, such cracks near the surface are difficult to detect, as optical inspection methods very quickly reach their limits with fine hairline cracks. However, measuring the electrical conductivity of the material provides a simple and quick way to detect even tiny fissures, as this method is very sensitive to structural inconsistencies.
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Bearings, such as those used for holding and smoothly moving the X-ray tubes in medical devices, are actually gliding on a thin film of liquid. If the surfaces have any damage, such as the thin fractures that can occur during the machining of the components, the sliding properties cannot be ensured for the device’s entire service lifetime. Technically, such cracks near the surface are difficult to detect, as optical inspection methods very quickly reach their limits with fine hairline cracks. However, measuring the electrical conductivity of the material provides a simple and quick way to detect even tiny fissures, as this method is very sensitive to structural inconsistencies.
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Bearings, such as those used for holding and smoothly moving the X-ray tubes in medical devices, are actually gliding on a thin film of liquid. If the surfaces have any damage, such as the thin fractures that can occur during the machining of the components, the sliding properties cannot be ensured for the device’s entire service lifetime. Technically, such cracks near the surface are difficult to detect, as optical inspection methods very quickly reach their limits with fine hairline cracks. However, measuring the electrical conductivity of the material provides a simple and quick way to detect even tiny fissures, as this method is very sensitive to structural inconsistencies.
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Bearings, such as those used for holding and smoothly moving the X-ray tubes in medical devices, are actually gliding on a thin film of liquid. If the surfaces have any damage, such as the thin fractures that can occur during the machining of the components, the sliding properties cannot be ensured for the device’s entire service lifetime. Technically, such cracks near the surface are difficult to detect, as optical inspection methods very quickly reach their limits with fine hairline cracks. However, measuring the electrical conductivity of the material provides a simple and quick way to detect even tiny fissures, as this method is very sensitive to structural inconsistencies.
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