FAQs

What outgassing considerations are required for UHV components?

Ultra-high vacuum (UHV) components must be fabricated from low-outgassing materials like 304 or 316L stainless steel, high-purity alumina ceramics, and oxygen-free copper. Avoid materials like zinc, cadmium, or standard plastics, which vaporize under vacuum and destroy the integrity of the chamber environment.

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How is a vacuum component leak rate quantified?

Leak rates are quantified by measuring the volume of gas flowing through a leak path per unit of time at a specific pressure differential. The industry standard unit for high-performance hermetic feedthroughs is atmospheric cubic centimeters per second (atm cc/sec of helium) or millibar-liters per second (mbar·l/s).

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What does hermetically sealed mean for electronic component packaging?

For electronics, hermetically sealed means the housing completely isolates internal components from environmental degradation like humidity, atmospheric pressure changes, and corrosive gases. This durable protection is vital for sensitive aerospace, military, and subsea electronic assemblies to prevent premature component failure.

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What defines a true hermetic seal in vacuum applications?

A true hermetic seal is an entirely airtight joint that prevents the permeation of gas, moisture, and contaminants into or out of a sealed volume. In vacuum systems, this is typically achieved through molecularly bonded ceramic-to-metal or glass-to-metal seals, maintaining ultra-high vacuum integrity down to 10⁻¹¹ Torr.

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When should an engineer choose a floating shield coaxial feedthrough?

Floating shield configurations are necessary when signal return paths must be kept completely isolated from the vacuum chamber ground to eliminate electrical ground loops. This layout isolates the outer conductor shield from the system flange, protecting low-voltage instrumentation signals from electromagnetic interference and background system noise.

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How do you calculate the pressure safety factor for a vacuum viewport?

Viewport safety factors are determined by evaluating the window material’s flexural strength relative to the clear aperture diameter and glass thickness. A minimum 4:1 ratio against atmospheric pressure load is the standard design target. Material selection is a critical input: fused silica offers superior UV transmission and thermal stability, borosilicate

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How do high-quality vacuum feedthroughs prevent virtual leaks?

Premium vacuum feedthroughs utilize specialized geometry and blind-hole venting to completely eliminate trapped pockets of atmospheric gas. Combining these design methodologies with high-purity ceramic-to-metal brazing prevents outgassing and virtual leaks, allowing systems to reach ultra-high vacuum (UHV) thresholds efficiently without downstream contamination.

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What is Your Return Policy?

MPF guarantees products against production defects and listed performance-data issues for 365 days after receipt. Unused standard catalog items may be returned within 365 days if they are in original packaging. Restocking fees may apply, and custom items cannot be returned.

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How Much Standoff Do Our Electric Isolators Allow?

Standard MPF electric isolators, also known as high-voltage breaks, provide voltage standoff from 5KV to 60KV. Custom isolators can be manufactured for applications requiring up to 225,000 volts of standoff. Each UHV isolator is built as a metal adapter hermetically bonded to alumina ceramic for voltage standoff at each end.

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Does MPF Manufacture Custom Designs?

Yes. MPF technical specialists help customers design custom UHV systems, custom components, and bespoke ultra-high-vacuum assemblies. MPF also provides quotes for custom UHV components and systems.

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