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Valve Selection Best Practices - Swagelok Chicago

Apr. 29, 2024

Valve Selection Best Practices - Swagelok Chicago

When selecting a valve for an instrumentation system, your choices may seem overwhelming. Just to name a few, there are ball valves, diaphragm and bellows valves, as well as check valves, excess flow valves, fine metering, gate, multi-port, needle, plug, relief, rising plug, and safety valves. Furthermore, each of these valves comes in many sizes, configurations, materials of construction, and actuation modes. To make the best choice, it is always good practice to ask the first question in valve selection: What do I want the valve to do?

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Most valves fulfill one of five primary functions:

  • on-off
  • flow control
  • directional flow
  • over- pressure protection
  • excess-flow protection

Matching valve type to function is the first and most important step in the valve selection process. It is not unusual in the field to see the misapplication of valves, such as a ball valve used for throttling flow. In some cases, the mismatch can be catastrophic, say, if a ball valve were used in a high-pressure oxygen system. With a source of ignition, the sudden burst of oxygen – enabled by the fast opening of the valve – could lead to an oxygen fire.

Here is a tutorial reviewing the basic types of valves, how they work, what functions they fulfill, and what to think about when choosing one.

On-Off Valves

On-off control is the most basic valve function. Valves in this category stop and restart system fluid flow. Primarily on-off valves are ball, gate, diaphragm and bellows valves.

Perhaps the most common of all valve types, ball valves are designed for on-off control. Quarter turn actuation starts or stops flow by positioning a metallic ball in a straight-through flow path. The ball has a large hole through the center of it. When the hole is lined up with the flow path, it enables flow. When it is turned 90 degrees from the flow path, it stops flow. If you are seeking an on-off valve with quick shutoff and high flow capacity, then a ball valve is a good choice. The position of the handle provides a quick indication of whether the valve is open or closed, and, for safety purposes, ball valves are easy to lock out and tag. They are most practical and economical at sizes between 1/4 inch and 2 inches.

Typically used for process control rather than instrumentation applications, gate valves are commonly chosen for on-off control, particularly for lines above 2 inches. They are also used as the first valve off the process line for process instrumentation, often in a double block and bleed configuration. Among the oldest types of on/off valves, they are typically specified in general industrial applications, such as large process or transmission lines. Some can even be larger than 100 inches (2540 mm). Multiple rotations of the handle raise and lower a sealing mechanism in and out of a straight flow path. Shutoff is gradual. Packing surrounds the stem, preventing system media from escaping to atmosphere where the stem meets the valve body. Valves that seal to atmosphere with metal-to-metal seals are referred to as “packless” because they do not contain the soft packing material, e.g. gaskets and O-rings, normally found around the stem in other valves. The valve stem is the cylindrical part that connects the handle (or actuation) with the inner mechanism for shut-off, flow control and directional control. Usually, the stem turns and/or moves up and down.

 

All stem seals or packing are subject to wear, and wear can lead to leakage. Valves with packing must be serviced or replaced at regular intervals, although some types of packing create more effective seals and last longer than others, such as the two-piece chevron design.

 

Contrary to packed valves, diaphragm valves are packless, and provide rapid shutoff and precise actuation speeds. In some cases, they may also deliver consistent quantities of process fluid. Typically, diaphragm valves are employed in high purity applications in the biopharmaceutical and semiconductor industries. Among all valve types, they provide the highest cycle life, a product of the valve’s highly engineered anatomy. Each valve contains a thin metal or plastic diaphragm, which flexes up and down, creating a leak-tight seal over the inlet. This robust valve is usually small, with the largest orifice — or internal pathway — typically less than two inches.

Like the diaphragm valve, bellows valves are packless, making them a good choice when the seal to atmosphere is critical and access for maintenance is limited. Frequently, they are specified for the containment area in nuclear power plants. A welded seal divides the lower half of the valve, where the system media resides, from the upper parts of the valve, where actuation is initiated. The stem, which is entirely encased in a metal bellows, moves up and down without rotating, sealing over the inlet.

Bellows valves and diaphragm valves are said to have a globe-like flow path. In globe valves, fluid does not flow straight through on a level plane as it does with a ball valve. The flow path enters the valve under the seat and exits above the seat. Globe valves will have lower flow rates than valves a straight-through flow path of the same orifice size.

 

Flow-Control Valves

Flow-control valves enable the operator to increase or decrease flow by rotating the handle. The operator can adjust the valve to a desired flow rate, and the valve will hold that flow rate reliably. Some flow control valves also provide very reliable shut-off, but many turns of the handle are necessary to move from the fully open to the fully closed position.

 

The most common flow-control valves are needle, fine metering, quarter-turn plug, and rising plug. Needle valves provide excellent flow control and, depending on design, leak-tight shut-off. They consist of a long stem with a highly engineered stem-tip geometry (e.g., vee- or needle-shaped) that fits precisely into a seat over the inlet. The stem is finely threaded, enabling precise flow control. Stem packing provides the seal to atmosphere.

Some designs contain a metal-to-metal seat seal; consequently, needle valves may be a good choice for high-temperature applications. As discussed earlier, flow is limited because of the globe-style flow path. Needle valves are a good choice with lighter, less viscous fluids. For the most precise flow control, consider fine metering valves, typically found in laboratory settings. Fine metering valves are a type of needle valve, with a long, fine stem that lowers through a long, narrow channel. This anatomy makes for a pronounced globe pattern, ideal for marking fine gradations of flow. Some fine metering valves are not designed to shut off.

Quarter-turn plug valves are utility valves, economically priced. Quarter-turn actuation rotates a cylindrical plug in a straight-through flow path. The plug contains an orifice to permit flow. Plug valves are commonly used for low-pressure throttling applications, in addition to shut off.

 

Another type of plug valve is the rising plug valve. Like a needle valve, a tapered plug lowers into an orifice to reduce flow. It differs from a needle valve in its flow path, which is straight-through rather than globe patterned. Because of the straight path, the valve is not as effective at providing fine gradations of flow. The rising plug is roddable, which is a good choice if the valve becomes clogged with system media.

 

Directional Flow Valves

A third type of valve directs fluid flow. Check valves ensure flow in one direction only. In most designs, the upstream fluid force pushes a spring-loaded poppet open, allowing flow. In the case of an increase in downstream or back-pressure force, the poppet is forced back into the seat, stopping reverse flow. Check valves are available with fixed or adjustable cracking pressures.

Some ball valves and diaphragm valves are designed with multiple ports. In most multi-port valves, fluid enters through a single inlet but may exit through one of many outlets, depending on the position of the actuator.

 

Multi-port valves may or may not have a shut-off position.

Overpressure Protection Valves

Valves in this category prevent the buildup of system pressure beyond a certain pressure setting. They are available in two types: relief valves and rupture discs. One type of relief valve is a proportional relief valve. It contains a vent to atmosphere that opens when pressure in a system exceeds a certain point set by the operator. A spring-loaded poppet enables the measured release of fluid.The vent closes when pressure returns to a point below where it was set. A safety relief valve is designed to open very quickly, releasing a large amount of system media. Due to their critical safety function, safety relief valves are required by code in certain applications. Safety relief and proportional relief valves are not to be used interchangeably with check valves, since the three have different functions.

Rupture discs are used mainly on sample cylinders to protect against overpressurization, which may occur, for example, when temperatures rise during transport. Similar to relief valves, rupture discs vent to atmosphere. A metal diaphragm bursts when pressure reaches a set point. This value is preset by the manufacturer. Once activated, the rupture disc must be replaced. Transportation codes require that compressed gas cylinders be equipped with a pressure relief device. A rupture disc is an economical choice for this application.

 

Excess Flow Valves

Excess flow valves stop uncontrolled release of system media if a downstream line ruptures. Under normal conditions, a spring holds a poppet in the open position. In an excess flow condition downstream, the poppet moves to a tripped position stopping almost all the fluid flow. When the system is corrected, the valve resets automatically. These valves are available with fixed tripping values.

 

Conclusion

Once you have matched valve type to function, you are well on your way in the valve selection process. Many details remain, though. You will need to give detailed attention to each of the following, if you have not had occasion to so far in the process:

 

Installation issues, maintenance schedules and access:

  • Installation issues, maintenance schedules and access
  • Safety and code requirements
  • System parameters, such as pressure, temperature, flow rates, and system media

Ultimately, you will need to determine:

  • Valve size and actuation types
  • Materials of construction (including O-rings and seals), which must be compatible with the chemical composition of the system media, pressures, and temperatures.

 

Questions on selecting the proper valve for your application? Email or call 866.901.0151.

Valve Selection Guide

    Valve Terms

    Has three ports. Depending on the particular valve, all three ports may be open, two ports may be open, or all ports may be closed.

    Has three ports. Depending on the particular valve, all three ports may be open, two ports may be open, or all ports may be closed.

    Has three ports. Depending on the particular valve, all three ports may be open, two ports may be open, or all ports may be closed.

    Has three ports. Depending on the particular valve, all three ports may be open, two ports may be open, or all ports may be closed.

    The difference between the inlet and the outlet pressure through a valve. The outlet pressure is lower than the inlet pressure due to the restriction caused by the valve.

    The difference between the inlet and the outlet pressure through a valve. The outlet pressure is lower than the inlet pressure due to the restriction caused by the valve.

    The difference between the inlet and the outlet pressure through a valve. The outlet pressure is lower than the inlet pressure due to the restriction caused by the valve.

    The difference between the inlet and the outlet pressure through a valve. The outlet pressure is lower than the inlet pressure due to the restriction caused by the valve.

    A diagram showing how flow can be directed using a particular valve. (See the

    A diagram showing how flow can be directed using a particular valve. (See the “ Flow Patterns ” box below for further explanation.)

    A diagram showing how flow can be directed using a particular valve. (See the “ Flow Patterns ” box below for further explanation.)

    A diagram showing how flow can be directed using a particular valve. (See the “ Flow Patterns ” box below for further explanation.)

    100% duty cycle is defined as continuous operation without any damage occurring. For intermittent duty cycle (<100%), alternate energized and de-energized state at regular intervals to allow the valve to completely down to room temperature.

    100% duty cycle is defined as continuous operation without any damage occurring. For intermittent duty cycle (<100%), alternate energized and de-energized state at regular intervals to allow the valve to completely down to room temperature.

    100% duty cycle is defined as continuous operation without any damage occurring. For intermittent duty cycle (<100%), alternate energized and de-energized state at regular intervals to allow the valve to completely down to room temperature.

    Selecting your Valve

    Consider your fluid type (liquid or gas) and its characteristics to determine compatible valve materials.

    Consider your fluid type (liquid or gas) and its characteristics to determine compatible valve materials.

    Consider your fluid type (liquid or gas) and its characteristics to determine compatible valve materials.

    Consider your fluid type (liquid or gas) and its characteristics to determine compatible valve materials.

    Our manual valve selection includes ball, check, diaphragm, elliptic, metering, needle, pinch, plug, pressure relief, and stopcock valves. Our actuated valve selection includes electrically actuated ball, elliptic, pinch, proportioning, and general-purpose solenoid valves.

    Our manual valve selection includes ball, check, diaphragm, elliptic, metering, needle, pinch, plug, pressure relief, and stopcock valves. Our actuated valve selection includes electrically actuated ball, elliptic, pinch, proportioning, and general-purpose solenoid valves.

    Our manual valve selection includes ball, check, diaphragm, elliptic, metering, needle, pinch, plug, pressure relief, and stopcock valves. Our actuated valve selection includes electrically actuated ball, elliptic, pinch, proportioning, and general-purpose solenoid valves.

             PTFE withstands many harsh or corrosive chemicals. For safety reasons, always use metal valves for pressurized gases.

    Determine the temperature, pressure, and flow rate under which your valve will be operating.

    Determine the temperature, pressure, and flow rate under which your valve will be operating.

    Determine the temperature, pressure, and flow rate under which your valve will be operating.

    Determine the temperature, pressure, and flow rate under which your valve will be operating.

             In general, metal valves withstand higher temperatures and pressures than plastic valves.

    Continuous (100%) duty solenoid valves are best for frequent on/off cycling. Choose normally closed or normally open depending on the state the valve will be in most often.

    Continuous (100%) duty solenoid valves are best for frequent on/off cycling. Choose normally closed or normally open depending on the state the valve will be in most often.

    Continuous (100%) duty solenoid valves are best for frequent on/off cycling. Choose normally closed or normally open depending on the state the valve will be in most often.

    For solenoid valves, consider response time and length of time valve will be energized.

    For solenoid valves, consider response time and length of time valve will be energized.

    For solenoid valves, consider response time and length of time valve will be energized.

    For solenoid valves, consider response time and length of time valve will be energized.

             Ball valves resist plugging and are easiest to service.

    Valve Types

  • Angle-Seat Valves:


    Utilize an ultra-compact actuator to move a piston back and forth within the valve body. On/off control and continuous control designs are available for gases, steam, and liquids. The construction of the body allows extremely high flow rates, particularly in comparison to conventional globe valves.

  • Ball Valves:


    Designed primarily for on/off service. These valves contain a ball with a hole through it. A handle or electric actuator rotates the ball 90°, turning the flow on or off. Use plastic ball valves for liquid applications only.

  • Butterfly Valves:


    Designed primarily for on/off service. These valves have low pressure drops and are self-sealing so they don't require an additional flange gasket for installation. For pipe sizes ranging from 1.5" to 12" dia.

  • Check Valves:


    Self-actuated valves designed to prevent fluid from flowing backward into your system. Flow forces a ball or disk in one direction to open the valve; when flow stops, the ball or disk seats to close the valve.

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    What are the characteristics and function of the directional ...
  • Diaphragm Valves:


    Use a flexible diaphragm to shut off flowÑcenter of the diaphragm is pushed down into a seat. Use these valves for fluids that are dirty or have a high particulate content.

  • Elliptic Valves:


    Similar to ball valves except elliptic valves use an elliptic O-ring to seal the cylinder during rotation. The seal design makes these valves ideal for vacuum applications.

  • Manifold Valves:


    Have one common port to two or more additional ports. For mixing, use the common port as the outlet; for distributing, use the common port as the inlet.

  • Metering Valves:


    Multi-turn valves designed to regulate the flow of fluid. These valves generally have low flow rates and high pressure differentials.

  • Needle Valves:


    Feature the most accurate flow control among the valves we offer. They are an excellent choice for precise metering of liquids or gases.

  • Pinch Valves:


    Use solenoid to squeeze shut a piece of tubing. Fluid contacts only the tubingÑideal for your high-purity fluid applications.

  • Plug Valves:


    Used primarily for on/off service. Controls flow using a plug with a hole through it. Plugs can be made of rigid materials such as PTFE¨, making them ideal for high-purity applications.

  • Pressure Valves:


    Designed to control or limit pressureÑnot flowÑin a system. These self-actuating valves will either open a relief port or bypass the fluid when a preset limit is reached.

  • Proportioning Valves:


    Designed to produce variable flow rates. Valves open and close in proportion to the signal from your controller.

  • Sample Valves:


    Special three-way valve designed to tap off a portion of the main flow for sampling purposes.

  • Sanitary Valves:


    Feature Tri-Clamp® connections and 316 stainless steel body construction for sanitary and high purity applications.

  • Solenoid Valves (Direct Lift):


    Use a plunger that is actuated to open or close the fluid path. These valves usually have low flow rates and high differential pressure drops. They generally have quicker response time than pilot-operated valves.

  • Solenoid Valves (Pilot-Operated):


    Utilize pressure created by air or liquids for actuation purposes. These valves are either piston or diaphragm types and require differential pressure to keep valve closed. Because they don't have a plunger, they are usually available in larger orifice sizes than direct lift valves.

  • Stopcocks:


    Similar to ball valves except stopcocks are much smaller in size. Primarily used in the laboratory for on/off control of flow or as a crude regulation of flow rate.

    The company is the world’s best Valve Accessories supplier. We are your one-stop shop for all needs. Our staff are highly-specialized and will help you find the product you need.

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