The correct selection of the valves being used within any process control system is key to ensuring the performance and reliability of that system. Michael Hannig, Product Manager for Solenoid Valves at Bürkert Fluid Control Systems, looks at this process with particular focus on the chemical resistance of the various components.

Bürkert element and twinpower valves showing stainless steel valve and plastic valve

Applications

A valve in a brewery can be very different to one used in a pharmaceutical application for example; one of the critical aspects of valve design is the chemical resistance properties of the valve housing and the gasket materials in relation to the substances which it is expected to control. A long and trouble-free service can only be expected if the correct materials have been selected in the design process.

In the case of a simple solenoid valve, many of the components, such as the plunger, return spring and seals are all exposed to the media. Therefore, information on the chemical compounds, temperature and pressure are all necessary to make an informed material selection.

If the production process involves liquid food products, the plastics and elastomers used should also conform to the local food and hygiene regulations. In addition, some processes require a cleaning cycle to be performed in between production processes and so the data is also required for this procedure as well to ensure there is no undue material degradation.

Factors such as mechanical loading, increased temperatures and chemical concentrations all have a bearing on the performance of individual components, which can be manufactured from a range of materials. In general the valve bodies are made from either brass or stainless steel with some being constructed from Polyamide.

The type of valve most appropriate for each application is governed by a number of factors, but in general, plunger-type direct acting valves are best suited to neutral and clean fluids while pivoted armature valves offer improved reliability by employing a media separating membrane to control corrosive, contaminated or aggressive fluids.

Chemical resistance of valve materials twinpower valve showing seals

Sealing

The range of options for sealing and separating membranes is quite extensive with each having benefits and drawbacks. The combination of chemical compound, temperature, pressure and cost all have influence in this design decision. Below are some of the more common compounds in use with brief descriptions of their properties.

PTFE

Polytetrafluoroethylene is almost totally insoluble and chemically inert. It has a high temperature resistance and PTFE ball valve seats, because of their natural lubricity, require no lubrication. PTFE diaphragms and flange gaskets are used in the most severe chemical resistance applications.

EPDM

Ethylene Propylene Terpolymer is a synthetic rubber used as the standard seal material for many valves. It is the most economical choice of elastomer and has excellent chemical resistance to acids, alkalis, salts and many others at temperatures up to 90 degrees C. However, it is not suitable for use with oils, petrochemicals and concentrated acids.

NBR

Nitrile rubber has a high chemical resistance to oil and petroleum but is weak on oxidizing media such as acids. Nitrile also has excellent abrasion resistance and is less expensive than FKM and FFKM.

FKM

Fluorinated elastomer) and perfluoro-elastomers (FFKM) are more expensive than neoprene and nitrile elastomers because they provide additional temperature and chemical resistance. Certain grades of FFKM can perform continuously at temperatures above 200 degrees C.

PPS

Polyphenyl sulphide is a high performance thermoplastic used in many engineering applications. With the ability to perform above 200 degrees C and with resistance to acids and alkalis as well as abrasion, PPS can be selected as a valve body material.

PVDF

Polyvinylidene fluoride is resistant to solvents, acids and bases, making it an ideal material for the valve body where high temperature resistance is not required. A very flexible product, it can be injected, moulded and welded, making for easier manufacturing of the valve bodies.

PEEK

Polyether ether ketone has excellent mechanical and chemical properties but is susceptible to high concentrations of sulphuric and nitric acid. This improved performance accounts for a higher price but provides superior qualities for valve bodies.

To help designers and maintenance engineers through the selection process, Bürkert has released a chemical resistance chart and a selection guide for solenoid valves. The guides are available here from the Bürkert website or by clicking 'visit website' on the right.


The correct selection of the valves being used within any process control system is key to ensuring the performance and reliability of that system. Michael Hannig, Product Manager for Solenoid Valves at Bürkert Fluid Control Systems, looks at this process with particular focus on the chemical resistance of the various components.

Bürkert element and twinpower valves showing stainless steel valve and plastic valve

Applications

A valve in a brewery can be very different to one used in a pharmaceutical application for example; one of the critical aspects of valve design is the chemical resistance properties of the valve housing and the gasket materials in relation to the substances which it is expected to control. A long and trouble-free service can only be expected if the correct materials have been selected in the design process.

In the case of a simple solenoid valve, many of the components, such as the plunger, return spring and seals are all exposed to the media. Therefore, information on the chemical compounds, temperature and pressure are all necessary to make an informed material selection.

If the production process involves liquid food products, the plastics and elastomers used should also conform to the local food and hygiene regulations. In addition, some processes require a cleaning cycle to be performed in between production processes and so the data is also required for this procedure as well to ensure there is no undue material degradation.

Factors such as mechanical loading, increased temperatures and chemical concentrations all have a bearing on the performance of individual components, which can be manufactured from a range of materials. In general the valve bodies are made from either brass or stainless steel with some being constructed from Polyamide.

The type of valve most appropriate for each application is governed by a number of factors, but in general, plunger-type direct acting valves are best suited to neutral and clean fluids while pivoted armature valves offer improved reliability by employing a media separating membrane to control corrosive, contaminated or aggressive fluids.

Chemical resistance of valve materials twinpower valve showing seals

Sealing

The range of options for sealing and separating membranes is quite extensive with each having benefits and drawbacks. The combination of chemical compound, temperature, pressure and cost all have influence in this design decision. Below are some of the more common compounds in use with brief descriptions of their properties.

PTFE

Polytetrafluoroethylene is almost totally insoluble and chemically inert. It has a high temperature resistance and PTFE ball valve seats, because of their natural lubricity, require no lubrication. PTFE diaphragms and flange gaskets are used in the most severe chemical resistance applications.

EPDM

Ethylene Propylene Terpolymer is a synthetic rubber used as the standard seal material for many valves. It is the most economical choice of elastomer and has excellent chemical resistance to acids, alkalis, salts and many others at temperatures up to 90 degrees C. However, it is not suitable for use with oils, petrochemicals and concentrated acids.

NBR

Nitrile rubber has a high chemical resistance to oil and petroleum but is weak on oxidizing media such as acids. Nitrile also has excellent abrasion resistance and is less expensive than FKM and FFKM.

FKM

Fluorinated elastomer) and perfluoro-elastomers (FFKM) are more expensive than neoprene and nitrile elastomers because they provide additional temperature and chemical resistance. Certain grades of FFKM can perform continuously at temperatures above 200 degrees C.

PPS

Polyphenyl sulphide is a high performance thermoplastic used in many engineering applications. With the ability to perform above 200 degrees C and with resistance to acids and alkalis as well as abrasion, PPS can be selected as a valve body material.

PVDF

Polyvinylidene fluoride is resistant to solvents, acids and bases, making it an ideal material for the valve body where high temperature resistance is not required. A very flexible product, it can be injected, moulded and welded, making for easier manufacturing of the valve bodies.

PEEK

Polyether ether ketone has excellent mechanical and chemical properties but is susceptible to high concentrations of sulphuric and nitric acid. This improved performance accounts for a higher price but provides superior qualities for valve bodies.

To help designers and maintenance engineers through the selection process, Bürkert has released a chemical resistance chart and a selection guide for solenoid valves. The guides are available here from the Bürkert website or by clicking 'visit website' on the right.


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