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Vacuum flange
Vacuum flange
Vacuum flange
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A vacuum flange is a flange at the end of a tube used to connect vacuum chambers, tubing and vacuum pumps to each other. Vacuum flanges are used for scientific and industrial applications to allow various pieces of equipment to interact via physical connections and for vacuum maintenance, monitoring, and manipulation from outside a vacuum's chamber. Several flange standards exist with differences in ultimate attainable pressure, size, and ease of attachment.

Vacuum flange types

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Several vacuum flange standards exist, and the same flange types are called by different names by different manufacturers and standards organizations.

KF/QF

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A KF-25 tee, o-ring, and clamp

The ISO standard quick-release flange is known by the names Quick Flange (QF) or Kleinflansch (KF, German which translates to "Small flange" in English).[1] The KF designation has been adopted by ISO, DIN, and Pneurop. KF flanges are made with a chamfered back surface that is attached with a circular clamp and an elastomeric o-ring (AS568 specification) that is mounted in a metal centering ring. Standard sizes are indicated by the nominal inner diameter in millimeters for flanges 10 through 50 mm in diameter.[2] Sizes 10, 20 and 32 are less common sizes (see Renard numbers). Some sizes share their flange dimensions with their respective larger neighbor and use the same clamp size. This means a DN10KF can mate to a DN16KF by using an adaptive centering ring. The same applies for DN20KF to DN25KF and DN32KF to DN40KF.

Flange O-ring size
DN10KF AS-311
DN16KF AS-314
DN20KF
DN25KF AS-320
DN32KF
DN40KF AS-326
DN50KF AS-330

ISO

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The ISO large flange standard is known as LF, LFB, MF or sometimes just ISO flange. As in KF flanges, the flanges are joined by a centering ring and an elastomeric o-ring. An extra spring-loaded circular clamp is often used around the large-diameter o-rings to prevent them from rolling off from the centering ring during mounting.

ISO large flanges come in two varieties. ISO-K (or ISO LF) flanges are joined with double-claw clamps, which clamp to a circular groove on the tubing side of the flange. ISO-F (or ISO LFB) flanges have holes for attaching the two flanges with bolts. Two tubes with ISO-K and ISO-F flanges can be joined by clamping the ISO-K side with single-claw clamps, which are then bolted to the holes on the ISO-F side.

ISO large flanges are available in sizes from 63 to 500 mm nominal tube diameter:[2]

Flange Tube diameter (mm)
DN63LF 63.5
DN100LF 102
DN160LF 160
DN200LF 200
DN250LF 254
DN320LF 316
DN400LF 400
DN500LF 500

CF (Conflat)

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A 2+34-inch (70 mm) CF (conflat) full nipple with blank flange and oxygen-free high thermal conductivity copper gasket
A 60 kV high-voltage electrical feedthrough on a 4+12-inch (110 mm) (or DN63) conflat flange

CF (ConFlat) flanges use a gasket (typically oxygen-free high thermal conductivity copper or aluminum) and a knife-edge flange (stainless steel for copper gaskets and hardened aluminum for aluminum gaskets) to achieve an ultrahigh vacuum seal.[3] The term "ConFlat" is a registered trademark of Varian, Inc., so "CF" is commonly used by other flange manufacturers. Each face of the two mating CF flanges has a knife edge, which cuts into the softer metal gasket, providing an extremely leak-tight, metal-to-metal seal. Deformation of the metal gasket fills small defects in the flange, allowing ConFlat flanges to operate down to 10−13 Torr (10−11 Pa) pressure. The knife edge is recessed in a groove in each flange. In addition to protecting the knife edge, the groove helps hold the gasket in place, which aligns the two flanges and also reduces gasket expansion during bake-out.[4] For stainless-steel ConFlat flanges, baking temperatures of 450 °C can be achieved; the temperature is limited by the choice of gasket material. CF flanges are sexless and interchangeable. In North America, flange sizes are given by flange outer diameter in inches, while in Europe and Asia, sizes are given by tube inner diameter in millimeters. Despite the different naming conventions, the actual flanges are the same.

European, Asian size North American size [inches]
DN10 1
DN16 1+13 ("mini")
DN25 2+18
DN40 (or DN35) 2+34
DN50 3+38
DN63 4+12
DN75 4+58
DN100 6
DN125 6+34
DN160 (or DN150) 8
DN200 10
DN250 12
  13+14
  14
  16+12

ConFlat gaskets were originally invented by William Wheeler and other engineers at Varian in an attempt to build a flange that would not leak after baking.[5]

Wheeler

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A Wheeler flange is a large wire-seal flange often used on large vacuum chambers.[6]

American Standards Association (ASA)

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A flange standard popularized in the United States is codified by the American National Standards Institute (ANSI), and is also sometimes named after the organization's previous name, the American Standards Association (ASA).[7] These flanges have elastomeric o-ring seals and can be used for both vacuum and pressure applications. Flange sizes are indicated by tube nominal inner diameter (ANSI naming convention) or by flange outer diameter in inches (ASA naming convention).

Nominal inner diameter/ANSI Flange outer diameter [inches]/ASA
1 4.25
1.5 5
2 6
3 7.5
4 9
6 11
8 13.5
10 16

Vacuum gaskets

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To achieve a vacuum seal, a gasket is required. An elastomeric o-ring gasket can be made of Buna rubber, viton fluoropolymer, silicone rubber or teflon. O-rings can be placed in a groove or may be used in combination with a centering ring or as a "captured" o-ring that is held in place by separate metal rings. Metal gaskets are used in ultra-high-vacuum systems where outgassing of the elastomer could be a significant gas load. A copper ring gasket is used with ConFlat flanges. Metal wire gaskets made of copper, gold or indium can be used.

Vacuum feedthrough

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A vacuum feedthrough is a flange that contains a vacuum-tight electrical, physical or mechanical connection to the vacuum chamber. An electrical feedthrough allows voltages to be applied to components under vacuum, for example a filament or heater. An example of a physical feedthrough is a vacuum-tight connection for cooling water. A mechanical feedthrough is used for rotation and translation of components under vacuum. A wobble stick is a mechanical feedthrough device that can be used to pick up, move and otherwise manipulate objects in a vacuum chamber.

See also

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References

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Revisions and contributorsEdit on WikipediaRead on Wikipedia

Vacuum flange

View on Grokipedia
from Grokipedia
A vacuum flange is a standardized, demountable connector used to join metallic vacuum components, such as chambers, tubing, pumps, valves, and tubulations, while maintaining a leak-tight seal essential for vacuum systems operating from rough vacuum to levels. These flanges are critical in industries including semiconductor manufacturing, deposition, scientific , and process equipment, where they enable modular assembly and disassembly without compromising vacuum integrity. Common types include KF (Klein Flansche) flanges for small connections (nominal widths 10–50 mm), featuring quick-action clamps and seals suitable for pressures down to 1×10⁻⁸ ; ISO flanges, available in clamped (ISO-K) and bolted (ISO-F) forms for larger diameters (63– mm), used in medium to high vacuum applications up to 1×10⁻⁸ ; CF (ConFlat) flanges for (down to 1×10⁻¹² ), employing metal with knife-edge seals that allow high-temperature bakeouts up to 450°C; and ASA flanges, adapted from American standards for bolted connections in general vacuum systems up to 1×10⁻⁸ . Materials are typically 304/304L for resistance and thermal stability, or aluminum for cost-effective rough vacuum use, with seals like elastomers (e.g., NBR, FPM) for lower vacuums and or for ultrahigh vacuums. Standards such as DIN 28403 (KF), DIN 28404 (ISO), and ISO 1609 ensure global compatibility and reliability across these systems.

Introduction

Definition and Purpose

A vacuum flange is a specialized connector attached to the ends of tubing, chambers, or other components, designed to join multiple parts of a while providing a leak-tight seal capable of withstanding reduced conditions. These flanges are essential interfaces in technology, allowing for the reliable interconnection of pipes, valves, pumps, and enclosures without compromising the internal . The primary purpose of vacuum flanges is to facilitate the modular and of vacuum systems used in applications demanding low-pressure environments, such as analytical , thin-film deposition, and high-energy physics experiments. By preventing the ingress of atmospheric gases, they help achieve and sustain vacuum levels from rough (up to 1 mbar) to (UHV, below 10910^{-9} mbar), thereby minimizing contamination and enabling precise control over system pressure. This modularity supports efficient assembly, disassembly, and upgrades, which are critical for complex setups where components must be frequently reconfigured. At their core, vacuum flanges comprise pairs of mating flange faces, along with clamping mechanisms—such as bolts or quick-release clamps—and sealing elements like elastomeric O-rings or metal gaskets that compress to form the airtight barrier. The importance of these components lies in their role in upholding overall system integrity; without robust flanges, even minor leaks could introduce contaminants, elevate gas loads from or , and disrupt the delicate pressure balances required for sensitive processes.

Historical Development

The roots of vacuum technology trace back to the , when demonstrated the principles of vacuum with his air pump experiments in the , laying the groundwork for later developments in evacuation and sealing. However, specialized vacuum flanges did not emerge until the , driven by the need for reliable high-vacuum systems in emerging fields like metallurgy and thin-film coating after . In the mid-20th century, ASA flanges were adapted from existing 150-pound steam-pipe standards to serve high-vacuum applications, providing a simple, sexed design with sealing that facilitated broader adoption in industrial vacuum setups. Around the same period, the Wheeler flange originated as a U.S. military-specification type in the for specialized high-vacuum needs, though it became largely obsolete with subsequent innovations. By the early , (now Agilent) developed the CF (Conflat) flange, patented as a knife-edge seal for (UHV) systems, particularly in manufacturing, enabling bakeable connections that withstood high temperatures without leaking. The saw Leybold introduce the KF flange for quick-assembly in small-scale vacuum systems, emphasizing ease of use with clamp mechanisms for nominal widths up to 50 mm. In the , ISO flanges were standardized internationally through ISO 2861 and related norms, promoting compatibility across global vacuum equipment with elastomer-sealed, sexless designs for medium to large diameters. These evolutions were propelled by advancements in vacuum pumps, such as oil diffusion and turbomolecular types, alongside growing demands from particle accelerators and space simulation chambers that required robust, UHV-capable, and bakeable flange systems.

Design Principles

Sealing Mechanisms

Sealing mechanisms in vacuum flanges achieve vacuum-tight connections by applying compressive to compliant sealing elements, which deform to fill microscopic gaps and prevent gas . These seals are governed by the interplay of flange geometry, which defines the contact area; clamping , which ensures sufficient ; and compliance, allowing elastic or plastic deformation without cracking. For (UHV) applications, effective seals maintain leak rates below 10^{-10} mbar·L/s, minimizing unintended gas ingress that could compromise system performance. Elastomeric seals, typically O-rings made from fluorinated elastomers like (Viton), are compressed within machined grooves on the flange faces to form a barrier suitable for high vacuum (HV) regimes from 10^{-3} to 10^{-7} mbar. These seals rely on the material's elasticity to conform to surface irregularities under moderate clamping, but their efficacy is limited by —where volatile compounds evaporate into the vacuum—and thermal constraints, restricting operation to temperatures below 200°C to avoid degradation or excessive . In contrast, metal seals employ ductile , such as those made from or , which undergo plastic deformation under high clamping torque to create a gas-impermeable contact for UHV environments. This deformation embeds the gasket into the sealing surfaces, forming a robust, diffusion-resistant barrier that supports bakeout temperatures up to 450°C to desorb adsorbed gases without seal failure. Clamping methods vary to apply the necessary uniform pressure, with bolted systems using multiple fasteners—such as 8 to 24 bolts on larger flanges—to distribute load evenly, while quick-release mechanisms like hinged clamps enable faster assembly without tools. Torque specifications for small flanges typically range from 2 to 30 Nm, depending on size and type, to achieve adequate compression without damaging components, ensuring the seal deforms predictably across the joint. To verify seal integrity, vacuum flanges often incorporate dedicated ports or adapters that connect to helium leak detectors, allowing tracer gas introduction and monitoring for leaks as low as 10^{-10} mbar·L/s during assembly or maintenance.

Materials and Construction

Vacuum flanges are predominantly fabricated from austenitic stainless steels, such as 304 and 316L grades, which provide excellent corrosion resistance and minimal outgassing essential for maintaining high vacuum integrity. These materials ensure structural stability under vacuum conditions while resisting degradation from exposure to residual gases or cleaning agents. For applications requiring lighter weight in high vacuum (HV) systems, aluminum alloys are used as an alternative, offering comparable performance with reduced mass. Inconel alloys, such as nickel alloy 625, serve as options for ultra-high vacuum (UHV) environments involving elevated temperatures, where enhanced heat resistance is critical. Surface finishes on vacuum flanges are typically achieved through or precision to a roughness of Ra < 0.5 μm, which minimizes particle generation and facilitates effective bakeout processes to remove adsorbed contaminants. This smooth finish enhances cleanability and reduces the risk of virtual leaks by promoting uniform during thermal conditioning. Flanges are constructed by machining from or , followed by precision boring to match the outer (OD) of the connected tubing, such as a 63 mm bore for DN 63 ISO-K sizes. Designs include fixed configurations, where bolt holes are rigidly oriented relative to the bore, and rotatable variants that allow independent of the mating face for easier alignment during assembly. Material compatibility is paramount, particularly avoiding ferromagnetic alloys like 400-series stainless steels in applications near strong magnets to prevent field distortion or interference. Thermal expansion coefficients must align between the flange and tubing materials—typically achieved by using matching austenitic stainless steels—to avoid stress-induced leaks during temperature cycling or bakeouts. Manufacturing adheres to CNC precision standards, with sealing surfaces held to tolerances of ±0.05 for flatness and alignment to ensure reliable seals without distortion. These tight specifications, often verified through leak testing, support consistent performance across ranges from HV to UHV.

Types of Vacuum Flanges

KF (Klein) Flanges

The KF (Klein) flange system, also known as QF (Quick Flange) or NW (Norddeutscher Verband), was developed by Oerlikon Leybold and has become a widely adopted standard for quick-connect connections in and industrial applications. These flanges are designed for use in rough to high environments, achieving pressures down to 10^{-7} mbar, and conform to standards such as DIN 28403, ISO 1609, and PNEUROP recommendations. Typically constructed from 304 or 316 , or aluminum for non-critical applications, they incorporate O-ring seals in a centering ring to form a gastight . The design features circular flanges with a machined groove for the , which is housed within a centering ring that ensures proper alignment during . Assembly relies on a simple wingnut or thumbscrew clamp that applies even pressure around the circumference, eliminating the need for bolts or torque wrenches and allowing for tool-free connection in under one minute. This sexless, rotatable interface promotes interchangeability across manufacturers and facilitates rapid reconfiguration of vacuum setups. KF flanges offer significant advantages in cost-effectiveness and reusability, as the components can be repeatedly assembled and disassembled without seal degradation in standard conditions, making them ideal for laboratory prototyping and frequent maintenance. They support positive overpressures up to 1.5 bar while maintaining integrity, providing a versatile solution for small-scale systems handling non-aggressive gases. However, limitations arise from the seals, which restrict bakeout temperatures to a maximum of 150°C for most configurations, beyond which material degradation occurs. They are unsuitable for (UHV) applications below 10^{-7} mbar due to from the O-rings, which can contaminate sensitive processes. Common sizes range from NW10 to NW50, corresponding to outer diameters of approximately 30 mm to 70 mm, with the NW25 size (40 mm OD) frequently used for interfacing 3/8-inch (9.5 mm OD) tubing in analytical instruments. These flanges achieve leak rates below 10^{-8} mbar·L/s when properly assembled with compatible seals like Viton or NBR.

ISO Flanges

ISO flanges, standardized in the under ISO 2861 and related norms, encompass ISO-K (fixed clamp-type) and ISO-F (rotatable bolted-type) variants designed as medium-vacuum connectors for industrial systems. These flanges support nominal diameters (DN) from 16 to 500, corresponding to outer diameters (OD) ranging from 30 mm to 595 mm, and operate effectively in high to medium vacuum ranges of 10^{-3} to 10^{-8} mbar using elastomeric seals. The design features bolted or clamped with integrated O-ring grooves for sealing, where ISO-K flanges provide non-rotatable, fixed alignment via claw clamps that engage grooves on the flange backs, ensuring position-independent connections without bolt holes. In contrast, ISO-F flanges incorporate through-holes for bolts, enabling for simplified alignment during assembly, particularly beneficial in complex setups; claw clamps are employed for larger sizes (DN 160 and above) to facilitate quick securing. These flanges offer versatility for foreline and process piping in industrial vacuum systems, with compatibility to cleanroom standards due to their smooth, low-particle generation surfaces, and bakeability up to 200°C to enhance removal without seal degradation. Bolt patterns conform to ISO 2861 specifications, ensuring interchangeable components across manufacturers; for example, a DN 100 ISO-K has a 130 mm OD and uses 8 M8 bolts in the mating ISO-F counterpart, with a recommended of 20 Nm to achieve uniform sealing . A notable variant is the ISO-MF (multi-fastener) flange, optimized for larger bores (NW 63 to 500) with multiple or bolt points to distribute loads evenly and support heavier structural applications in extended vacuum lines.

CF (Conflat) Flanges

CF (Conflat) flanges, originally trademarked as ConFlat and invented in the early by William Wheeler at (now part of Agilent Technologies), represent a key advancement in (UHV) sealing technology designed for demanding applications requiring pressures below 10^{-9} mbar. These flanges feature a sexless, identical-pair design available in standard sizes from 1.33 inches (DN16, 34 mm outer diameter) to 30 inches (DN350, 864 mm outer diameter), accommodating tube diameters from 0.5 inches to 24 inches. Primarily constructed from austenitic stainless steels such as 304L, 316L, or 316LN for low magnetic permeability and corrosion resistance, they enable reliable connections in environments down to 10^{-13} . The core design relies on precision-machined knife edges on each that deform a soft metal —typically oxygen-free high-conductivity (OFHC) , or gold-plated for minimized —creating a metal-to-metal seal upon bolting. This deformation embeds the gasket into the knife edges, ensuring a robust, all-metal barrier without elastomers, which aligns with principles of plastic deformation in metal sealing for UHV integrity. are assembled using or silver-plated bolts, nuts, and washers, tightened progressively in a crisscross pattern to uniform torque until the flange faces contact, preventing gasket extrusion; for instance, a 2.75-inch (DN40) typically employs six 1/4-28 bolts at 80–100 in-lb. Key advantages include high-temperature bakeability up to 450°C to reduce , reusability of the flanges themselves for up to 20 assembly cycles with fresh gaskets, and helium leak rates below 10^{-10} atm·cc/sec, establishing them as the preferred choice for particle accelerators, beamlines, and processing equipment. Unlike higher-vacuum alternatives, CF flanges maintain seal integrity across wide temperature cycles (-196°C to 450°C) and support non-magnetic variants in 316LN for sensitive fields. Specifications adhere to ISO 3669 for dimensions and tolerances, with optional ASME compliance for integration; a representative 6-inch (DN100, 152 mm outer ) flange features 16 clearance or tapped holes for 1/4-28 or 5/16-24 bolts, depending on the manufacturer, and accommodates a 4.5-inch tube. for such assemblies ranges from 120–150 in-lb to achieve face contact without over-stressing the material. Variants include rectangular CF flanges, which adapt the knife-edge and bolting system to non-circular geometries for custom vacuum chambers in specialized UHV setups like large-scale vessels. Fixed (non-rotatable) and rotatable configurations further enhance alignment flexibility during installation.

Legacy Types (ASA and Wheeler)

ASA flanges, also known as ANSI flanges, were adapted in the mid-20th century from the ANSI 150# pipe flange standards originally designed for steam and pressure applications. These legacy designs feature a sexed configuration with one flange having a grooved surface for an elastomeric O-ring seal—typically a dove-tailed or single/double-bevel groove to secure the O-ring—while the mating flange is smooth and flat. Bolted connections using large-diameter bolts secure the assembly, enabling compatibility with standard tubing sizes ranging from 1.5 to 12 inches in nominal inner diameter, corresponding to outer diameters of approximately 89 to 305 mm. Constructed primarily from 304 or 304L stainless steel, or occasionally mild steel or aluminum alloys, ASA flanges are suited for high vacuum (HV) applications down to about 10^{-6} to 10^{-7} mbar. Wheeler flanges emerged in the 1950s and early 1960s as a U.S.-developed specification, primarily by Varian Associates, for high vacuum systems, including potential military and large-scale scientific uses. Similar in robustness to ASA designs but tailored for ultra-high vacuum (UHV), they incorporate wire-seal variants using soft metal gaskets, such as oxygen-free high-conductivity (OFHC) copper wire, compressed between mating flanges to achieve seals. These flanges are sexed and bolted, with sizes accommodating larger tubes from 10 to 24 inches, and outer diameters up to 27 inches or more for custom applications. Developed by William R. Wheeler and colleagues, the design drew from earlier metal-seal innovations to support expansive vacuum chambers, as detailed in their 1961 presentation on ultra-high vacuum flanges. Both ASA and Wheeler flanges offer advantages rooted in their origins from established industrial technologies, providing robust, low-cost construction that leverages pipe manufacturing for durability under mechanical stress. Their thicker profiles—originally rated for 150 psi—ensure high strength and compatibility with older vacuum pumps and roughing systems in industrial settings. However, limitations include restricted bakeout temperatures for ASA designs (typically 150–200°C due to O-ring degradation, rendering them non-bakeable for UHV processes) and higher leak rates exceeding 10^{-7} mbar·L/s, primarily from elastomer in larger diameters. Wheeler flanges, while bakeable to higher temperatures with metal seals, are now rare outside maintenance of legacy systems, having been phased out in favor of more reliable UHV options due to slightly inferior sealing consistency compared to modern standards. To integrate these legacy types into contemporary setups, adapters are commonly employed to connect ASA or Wheeler flanges to modern ISO or CF systems, facilitating upgrades without full replacement of older vacuum infrastructure.

Supporting Components

Vacuum Gaskets

Vacuum gaskets serve as the primary sealing elements in vacuum flange assemblies, providing a barrier against atmospheric leakage while accommodating the compression mechanisms of different flange types. These gaskets are selected based on the required vacuum level, operating conditions, and material properties to ensure reliable performance in high vacuum (HV) and ultra-high vacuum (UHV) environments. Elastomeric gaskets, such as those made from Viton (fluorocarbon, FKM) or Buna-N (nitrile rubber), are commonly used with KF, ISO, and ASA flanges for HV applications up to approximately 10^{-8} . Viton offers a temperature range of -20°C to 200°C and excellent resistance to oils and chemicals, making it suitable for general vacuum systems. Buna-N provides similar performance but with better low-temperature flexibility down to -40°C, though it has lower chemical resistance. These materials are formed into O-rings that compress elastically to form a seal. For UHV applications requiring bakeout temperatures up to 450°C, metal gaskets such as oxygen-free high-conductivity (OFHC) are standard for flanges, with a melting point of 1085°C. These gaskets undergo deformation under compression, creating a metal-to-metal seal that minimizes . gaskets, such as Kalrez (perfluoroelastomer, ), provide superior chemical resistance to aggressive media like acids and bases, often used in KF or ISO assemblies where elastomer compatibility is critical. Selection of vacuum gaskets depends on the target level, with elastomers suitable for HV due to their ease of use but limited by , while metals are essential for UHV to avoid hydrocarbon contamination. Temperature constraints guide choices; for instance, elastomers like Viton are limited to 200°C continuous use, whereas supports high-temperature baking without degradation. Material compatibility ensures no adverse reactions, such as of process gases in chemically aggressive environments. Installation involves placing the gasket between mating flanges and applying torque to achieve proper compression. For KF flanges, elastomeric O-rings are seated within aluminum centering rings, which align the components before clamping secures the seal. In CF flanges, the knife-edge design indents the metal gasket by 0.05-0.1 mm, ensuring a virgin sealing surface each time. Elastomeric gaskets can be reused for multiple cycles (typically 5-10 before replacement due to ), while metal gaskets are generally single-use to prevent leaks from work-hardening. Performance is evaluated through metrics like rates, with unbaked Viton exhibiting rates below 10^{-7} ·L/s·cm², reducible to 10^{-10} ·L/s·cm² after vacuum baking at 150°C. for elastomeric gaskets, such as Viton, is approximately 15 years under proper storage conditions away from and UV exposure, though vacuum-specific handling may shorten this to 2-5 years if not stored inertly. These properties ensure long-term integrity in systems.

Vacuum Feedthroughs

Vacuum feedthroughs are specialized devices integrated with vacuum flanges that enable the transmission of electrical, optical, or signals through the wall of a while preserving the required level. These components are essential for introducing utilities such as power, instrumentation signals, or cooling fluids into vacuum environments without compromising hermetic integrity. For instance, electrical feedthroughs allow pins or conductors to penetrate the vacuum barrier, supporting applications from low-voltage signaling to high-power delivery. The design of vacuum feedthroughs typically involves sealing conductors or fibers within an insulator that is bonded to a baseplate, ensuring a vacuum-tight interface. Common sealing mechanisms include glass-to-metal bonds, insulators such as alumina, or encapsulation, which provide electrical isolation and prevent gas permeation. Materials are selected for compatibility with (UHV) conditions, including low and thermal stability; for example, alloys are often used for their coefficient of that matches ceramics like alumina, minimizing stress during temperature cycling. Feedthroughs are engineered for standards such as KF (NW), CF (Conflat), and ISO, with examples including a 2.75-inch CF multi-pin electrical feedthrough featuring 9 pins. Types of vacuum feedthroughs vary by the medium transmitted and operational demands. Electrical feedthroughs include single-conductor designs for simple signals and multi-conductor variants, such as 8-pin instrumentation types, with options for high-voltage ratings up to 15 kVDC or power handling up to 600 A. Fluid feedthroughs, including types like Type K (/), facilitate liquid or gas transfer via tubing, often for cooling or sensing. Optical feedthroughs employ fiber optics, such as multimode step-index fibers with core diameters of 100–1000 μm or graded-index types, to transmit light signals in UHV systems. Bakeable variants, suitable for UHV bakeout, use metal-sealed designs compatible with temperatures up to 450°C on CF flanges. Key specifications for vacuum feedthroughs emphasize reliability in demanding environments. Helium leak rates are typically better than 101010^{-10} mbar·L/s for UHV metal-sealed models, with insulation resistance exceeding 101210^{12} Ω to prevent . Operating voltages range from 500 VDC for thermocouples to 15 kVDC for high-voltage types, while temperature ratings support -270°C to 450°C for bakeable CF configurations. Materials like oxygen-free high-conductivity (OFHC) for conductors and 304 for flanges ensure low down to 101010^{-10} . Installation of vacuum feedthroughs involves mounting the component directly to a compatible flange port, either by bolting with a metal gasket for CF types or using clamps for KF flanges, followed by connection to external cabling with strain relief to avoid mechanical stress on seals. Weldable baseplate designs allow integration into custom vacuum walls, ensuring alignment of conductors during assembly.

Applications and Standards

Typical Applications

Vacuum flanges are essential in research and scientific applications, particularly in high-vacuum and (UHV) environments. In particle accelerators, such as those at facilities like , Conflat () flanges are widely used for UHV beamlines due to their ability to maintain seals under extreme conditions and high baking temperatures up to 450°C, enabling reliable vacuum integrity for beam transport. For surface analysis instruments, like X-ray photoelectron spectrometers, Klein (KF) flanges facilitate connections in smaller vacuum chambers, allowing easy assembly and access for sample introduction while supporting pressures down to 10^-9 mbar. In manufacturing, vacuum flanges play a critical role in wafer processing equipment. ISO flanges are commonly employed in foreline systems to connect roughing pumps to process chambers, providing robust seals for moderate vacuum levels around 10^-3 to 10^-6 mbar and accommodating larger diameters for high gas throughput. Conflat flanges are preferred for load locks and transfer modules, where bakeable, contamination-free systems are required to achieve UHV conditions (below 10^-9 mbar) and prevent particle generation during wafer handling. Industrial applications leverage vacuum flanges for processes demanding precise vacuum control. In physical vapor deposition (PVD) and chemical vapor deposition (CVD) coating systems, a mix of KF, ISO, and CF flanges connects deposition sources, substrates, and exhaust lines, enabling uniform thin-film deposition on components like optical mirrors or tools at pressures from 10^-7 to 10^-2 mbar. Space simulation chambers, used to test satellites, often incorporate large ASA or CF flanges for expansive vacuum enclosures, simulating orbital conditions down to 10^-6 mbar over volumes exceeding 100 m³. Other specialized uses include and analytical instrumentation. Conflat flanges seal Dewar vessels in cryogenic systems, supporting or nitrogen storage at temperatures near 4 while withstanding thermal cycling and maintaining insulation to minimize heat leaks. In mass spectrometers, KF flanges integrate feedthroughs for ion sources and detectors, allowing operation in high- environments (10^-6 to 10^-8 mbar) for accurate molecular analysis in fields like . Beyond specific sectors, vacuum flanges enable modular , such as pump-to-chamber connections that allow quick disassembly for , reducing in production lines compared to welded systems. This supports scalable setups across applications, from prototypes to industrial-scale operations.

Standards and Specifications

Vacuum flanges are governed by a range of international and national standards to ensure , safety, and performance in vacuum systems. The (ISO) plays a central role, with key specifications including ISO 1609 for non-knife-edge flanges used in clamped and bolted connections like ISO-K and ISO-F types, ISO 2861 for clamped-type quick-release couplings such as KF flanges, and ISO 3669 for knife-edge flanges like CF types. National standards complement these, such as DIN 28403 and DIN 28404 in for KF and ISO flanges respectively, which align with ISO equivalents and define DN (nominal diameter) sizes. In the United States, ANSI/ASME B16.5 influences legacy ASA flanges through Class 150 configurations, while Japan's JIS B 2290 specifies vacuum flange dimensions for VF and VG types. These standards detail dimensions, tolerances, and pressure ratings to facilitate reliable sealing. For instance, ISO 1609 outlines flange outer diameters, bolt hole patterns, and tolerances for sizes from DN 63 to DN 630, with DN 63 ISO-K flanges featuring a tube outer diameter of 70 mm and compatibility with claw clamps rather than bolts, though ISO-F variants use four M8 to M10 bolts depending on size. Pressure ratings typically range from atmospheric to 10^{-8} Torr for elastomer-sealed ISO and KF flanges, and to 10^{-12} Torr for metal-sealed CF flanges, with tolerances ensuring leak rates below 10^{-9} std cc/sec helium. Testing protocols mandated by these standards include helium leak detection to verify seal integrity and bakeout cycles up to 450°C for CF flanges to minimize outgassing. Post-2000 updates to ISO standards, including revisions to ISO 1609 in 2020, have refined dimensions for better compatibility. Low-outgassing materials like are commonly used to meet requirements. In applications compliant with , vacuum flanges must use materials that minimize particle generation and , while specialized uses like particle accelerators follow specifications for rectangular CF flanges, which incorporate a 20° knife-edge for enhanced sealing under extreme conditions. The evolution of these standards reflects a transition from national variants, such as ASA in the 1940s based on industrial pipe fittings, to global harmonization via ISO in the 1980s, promoting widespread adoption and reducing proprietary designs.

References

  1. https://www.leybold.com/en-us/knowledge/vacuum-fundamentals/vacuum-generation/flange-types-and-materials
  2. https://www.mks.com/medias/sys_master/mksresources/h6e/hd6/9954698199070/VacuumComponentsFamily-DS/VacuumComponentsFamily-DS.pdf
  3. https://www.vacuumchamber.com/blog/comparing-kf-iso-cf-and-asa-flanges/
  4. https://milnepublishing.geneseo.edu/introtovacuumtech/chapter/an-introduction-to-vacuum-systems/
  5. https://jrm.phys.ksu.edu/Resource/Pubs/VacuumFlanges.pdf
  6. https://www.pumpsandsystems.com/flange-sealing-vacuum-magdeburg-hemispheres
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  23. https://www.atlasuhv.com/next-generation-vacuum-systems-aluminum
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  25. https://ancorp.com/blog/should-you-electropolish-your-vacuum-component/
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  27. https://www.n-c.com/our-capabilities/manufacturing
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  33. https://www.mdcprecision.com/sections/iso-kf-kwik-flanges
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