Jul. 21, 2025
Globe valves, recognized for their spherical body and superior throttling accuracy, are integral components in fluid control systems. Their unique design allows for both the regulation and the complete obstruction of fluid flow, making them indispensable in various industrial applications. This article compiles a list of frequently asked questions about globe valves, providing insights into their functionality, installation, and operational characteristics.
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A globe valve is a linear motion valve designed to stop, start, and regulate flow. It has a spherical body with an internal baffle that houses a movable disk or plug which seals against a stationary seat.
A globe valve works by the upward and downward movement of the valve stem. When the handwheel is turned, the stem moves the disc or plug toward or away from the seat, which is perpendicular to the flow path, thus controlling the flow of fluid through the valve.
The primary purpose of a globe valve is to regulate flow in a pipeline. It is designed to throttle flow and can be used to completely shut off the fluid flow.
A globe valve controls flow in a pipeline by adjusting the distance between a movable disk and a stationary ring seat, thus throttling the flow as needed.
A globe valve typically has a spherical body with a protruding bonnet on top, housing the stem and handwheel. Internally, it has a baffle that splits the body with the seat on one side and the disk or plug on the other.
A globe valve’s characteristics can be changed by altering the shape and material of the disk and seat, stem packing, and by choosing the appropriate size for the intended flow rate and pressure.
illustrate the baffle that separates the two halves of the body and the bonnet, which houses the stem and packing that prevents leaks along the stem. The diagram may also detail the valve’s flow arrows, indicating the correct installation orientation to ensure proper operation.
No, not all shutoff valves are globe valves. There are several types of shutoff valves including ball valves, gate valves, plug valves, and butterfly valves, each with their own operational characteristics.
Globe valves are generally not recommended for slurries or suspensions because the particles can cause wear on the valve seat and the disk, leading to leakage. There are special valves used for this application, we THINKTANK has rich experience of slurry field, please feel free to contact us for an instant quote and solution.
WOG stands for Water, Oil, and Gas, which are the fluids a valve is rated to handle. Globe valves can be used in air conditioning systems for these fluids, provided they meet the system’s pressure and temperature requirements.
CV, or flow coefficient, is calculated for globe valves by determining the flow rate in gallons per minute (GPM) of water at 60°F that will flow through the valve with a pressure drop of 1 psi.
A 3-way globe valve has three ports and can be used to mix flow from two inlets or divert flow to two different outlets. The valve’s operation allows for changing the flow path within the valve body to the desired outlet.
A globe check valve works by allowing flow in one direction and automatically closing to prevent backflow when the flow reverses, typically using a swinging disc or piston.
A globe stop check valve combines the functions of a globe valve and a check valve. It allows the valve to be closed, even if flow is going in the intended direction, to stop flow entirely, or to act as a check valve and prevent backflow.
The cost of a globe sprinkler valve can vary widely depending on size, material, and specifications. It is best to consult with suppliers for specific pricing.
The globe valve system curve is a graphical representation of the head loss versus flow rate through the valve. It is calculated by measuring the pressure drop across the valve at various flow rates and plotting these values on a graph. The valve’s inherent flow characteristic curve can be superimposed on the system’s flow requirement curve to understand how the valve will perform within the system.
Simply to say, to calculate the globe valve system curve, you need to chart the relationship between the flow rate through the valve and the resulting pressure drop, considering the valve’s CV and the specific system characteristics.
CV is calculated for globe valves by measuring the flow rate in gallons per minute (GPM) that passes through the valve with a pressure drop of one pound per square inch (PSI) when the valve is fully open.
Trim refers to the internal parts of a valve that come in contact with the fluid, not a specific type of valve. Globe valves have trim parts, including the disc, seat, stem, and cage.
No, ball valves and globe valves are not the same. Ball valves use a spherical ball with a hole through the center to control flow, while globe valves use a movable disc or plug to regulate flow.
A control valve can be a globe valve if it is used for the purpose of controlling flow. However, ‘control valve’ is a broad category that can include other types of valves as well, such as butterfly type, plug type, V notch type, eccentric plug type, v-ball type, segment type and so on.
No, gate valves and globe valves are different; gate valves are designed primarily for on/off control with minimal pressure drop, while globe valves are used for regulating flow.
Globe valves can be normally closed (NC) or normally open (NO), depending on the design and the needs of the system they are installed in. Normally closed means the valve is closed when no actuating force is applied.
Typically, globe valves are not bidirectional. They are designed to be used with the flow in one direction, which is usually indicated by an arrow on the valve body.
Yes, globe valves are unidirectional and are designed to be installed with the flow in a specific direction to function correctly and to ensure a proper seal when closed.
Angle globe valves are a type of globe valve where the inlet and outlet ports are at a 90-degree or other angle to each other. This design can facilitate a change in the direction of flow and reduce the number of elbow fittings required in the piping system.
Globe valves are used for throttling or regulating flow in pipelines. They are also used for on/off service and are effective for frequent cycling and control of fluids anywhere in the amount or volume of flow.
A globe angle irrigation valve is a valve used in irrigation systems that combines the features of a globe valve and an angle valve, often used to control the flow of water at a 90-degree angle, which is beneficial in certain irrigation system layouts.
A globe check valve is a type of check valve with a globe-shaped body that allows fluid to flow in one direction only, preventing backflow and typically using a swinging disc or piston for closure.
A globe stop check valve is a type of valve that serves as a stop valve and a check valve. It can stop flow like a globe valve and prevent backflow like a check valve, even when the flow is in the correct direction.
In plumbing, a globe valve is used to regulate the flow of water, allowing for precise control of water supply within a building or system.
Globe valves can be made of various materials, including cast iron, cast steel, stainless steel, bronze, brass, PVC, special alloy steel, and other materials suitable for the specific application and the type of fluid being controlled.
A manual globe valve is operated by hand, using a handwheel or a similar device to open and close the valve, as opposed to an automated or actuated valve.
Needle valves are a type of globe valve with a small port and a threaded, needle-shaped plunger. They provide precise flow control. When referring to “needle and globe valves,” it typically points to both being used in applications where precise flow regulation is needed.
A pneumatic globe valve is controlled by pneumatic actuator rather than manual operation, which uses air pressure to open or close the valve.
This term is not standard in valve terminology. Reciprocating refers to a back-and-forth movement, which is not characteristic of globe valves. If referring to a valve used in a reciprocating pump system, then it would simply be a globe valve used within that context.
A stop globe valve is another term for a globe valve that is specifically used to stop flow. It emphasizes the valve’s ability to completely shut off the flow when needed.
The trim of a globe valve includes the internal parts that come into contact with the process fluid, such as the seat, disc, stem, and sleeve. The trim material is selected based on the fluid characteristics to ensure proper function and durability.
A bellow seal globe valve incorporates a metallic bellow welded to the stem and bonnet of the valve, which creates a hermetic seal and prevents leaks through the stem area, commonly used in applications where leakage into the atmosphere must be minimized.
A globe control valve is a type of globe valve that is used to regulate flow in a pipeline. It is designed to respond to signals from a control system and can be used for throttling or modulating flow.
SDNR stands for Screw Down Non-Return. An SDNR globe valve combines the functions of a globe valve and a check valve. It can be screwed down to stop flow like a globe valve and also allows flow in only one direction like a check valve. BTW, SDSL globe valve means Screw Down Screw Lift globe valve.
The advantages of a globe valve include good throttling capability, high rangeability, and the ability to maintain and regulate high-pressure drops. They also provide a better shut-off than gate valves.
The face on a globe valve typically refers to the surface where the valve connects to the flanges or pipe ends, known as the face-to-face dimension, which is important for proper installation and compatibility with the piping system. You can freely contact us for drawing or catalogs to check the standards of face to face dimension.
The symbol for a globe valve in piping and instrumentation diagrams (P&ID) usually consists of a circular representation with a solid line through it at an angle, indicating the valve seat, with two lines for the pipe connections on either side.
Valves that have both globe and angle configurations are usually known as angle globe valves. They have the flow-regulating feature of globe valves but with an angled body, which allows for a 90-degree or other degree turn in the flow path.
A globe valve gives a throttled flow which can be finely adjusted. It is not designed for full, unobstructed flow, so it will always cause some pressure drop even when fully open.
Globe valves are shaped with a spherical body to house the internal mechanism that requires space to accommodate the disk, seat, and stem assembly, which provides a good seal and allows for the precise regulation of flow.
It is called a globe valve because of the spherical shape of its body, which is divided by an internal baffle housing the valve’s seat and controls the flow within the spherical chamber.
Globe valves are used because they offer precise control of flow, are excellent for throttling, and provide a reliable shut-off. They are suitable for applications where flow needs to be adjusted regularly or maintained at a certain level.
A Y-type globe valve is used because its design reduces the flow resistance and pressure drop across the valve, which makes it more suitable for high-pressure applications. The angled path through the valve also allows for a smoother flow transition.
Yes, globe valves are directional due to their design and must be installed with the flow direction in mind to function properly.
Yes, a globe valve can be installed vertically as long as the flow direction is maintained and the valve is supported adequately.
A globe valve is considered unidirectional because it is designed to be used with the flow in one direction, which allows for the proper operation of the valve and effective shut-off.
Yes, a globe valve can be installed on its side, but the flow direction must be maintained as per the manufacturer’s instructions, and the actuator must be accessible.
No mechanical valve can be entirely without friction because there will always be some resistance when moving the parts against each other, especially the disk against the valve seat. However, well-designed valves can have minimal friction.
The pressure should enter the globe valve from under the seat. This assists in closing the valve and helps in achieving a tight seal when the valve is closed.
Yes, globe valves are particularly well-suited for throttling and regulating flow, making them ideal for applications where flow control is necessary.
Yes, globe valves are particularly suitable for throttling purposes due to their ability to control flow precisely.
It is not recommended to install globe valves upside down because it can complicate maintenance and may affect the performance due to the orientation of the stem and actuator.
Fixing a globe valve involves isolating the valve from the system, disassembling it to inspect for worn or damaged parts such as the seat, disc, stem, or packing, and replacing them as necessary. Reassembly should follow the manufacturer’s guidelines to ensure proper function.
To flush a line before the drip globe valve, you should open the valve fully to allow water to flow at maximum capacity, thereby flushing out any debris or sediment. Some systems may have dedicated flush valves or ports for this purpose.
Hydrotesting a globe valve involves filling the valve with water and pressurizing it to a specified test pressure, which is usually higher than the valve’s normal operating pressure. The valve is then inspected for leaks or deformities. Safety precautions must be strictly observed during hydrotesting.
To install a globe valve you can following the blew steps.
Step 1: Ensure the pipeline is depressurized and drained.
Step 2: Check the flow direction indicated on the valve body.
Step 3: Place the valve in the pipeline with the flow direction matching the system’s flow.
Step 4: Use flanges or threads to secure the valve in place according to the type of valve ends.
Step 5: Tighten bolts or fittings evenly to prevent damage.
Lapping a globe valve you can following the below method.
To create a system curve for a globe valve:
To open a stuck globe valve, please check the following tips.
Refilling typically refers to replenishing the packing:
To repair a globe valve, here are some tips for your reference.
Here is a way to replace a globe valve
Step 1: Shut off the system and relieve pressure.
Step 2: Disconnect the valve from the pipeline.
Step 3: Remove the old valve.
Step 4: Install the new valve, ensuring the flow direction is correct.
Step 5: Test the valve for proper operation.
The following is the method to use globe valve.
First, Turn the handwheel clockwise to close and counter-clockwise to open.
Second, Make incremental adjustments to the handwheel to throttle the flow as needed.
Finally, Do not force the valve to open or close, as this can damage the seating surfaces.
Gate valves have a flat gate that slides vertically in and out of the flow, while globe valves have a movable disk that moves perpendicular to the flow. Globe valves typically have a round body, and their stem movement is usually guided by a bonnet outside the valve body. Gate valves have a rising or non-rising stem that moves up or down as the valve is operated.
The main difference lies in their design and functionality: gate valves are optimized for on/off control, with a gate that moves up or down to block flow, while globe valves are used for throttling, with a disk that moves in or out of the seat to regulate flow.
A globe valve typically has a spherical body with the valve stem at the top operating perpendicular to the flow, while a gate valve has a more elongated body with a gate that moves up and down parallel to the flow.
Both the globe valve and gate valve can be used in the pipeline to shut off the flow of the medium, and due to gate valve and globe valve also have similar structures. Therefore, for some new guys whom just enter to industrial valves market, it will be really confused about the difference between globe valve and gate valve.There are four aspects to compare the difference between globe valve and gate valve.
The structure of the gate valve is more complicated than that of the globe valve.
First of all, according to the structure of the gate valve, there are two types of gate valves:
Rising Stem Gate Valves and Non-Rising Stem Gates. But globe valves don’t have this different design.
Secondly, in terms of appearance and structure, the face to face(length) of the gate valve is shorter than that of the globe valve, but the height is higher than that of the globe valve.
Therefore, the gate valve requires more installation space, especially the rising stem gate valve.
The rising stem gate valve is also called OS&Y design, which means Outside Stem and Yoke.
The operation method of the gate valve and globe valve is the same, all can use a pneumatic actuator, electric actuator, or handwheel to drives the valve stem open and close the valve.
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The difference between them is that the gate valve can only be fully opened and fully closed. And its travel/stroke is larger than the globe valve. It means that the opening and closing time of the gate valve is longer than the globe valve.
Due to the distance of plug to seat is short of globe valve, globe valve can be stopped at any travel during the movement for flow throttling. This is not available in gate valves.
In addition, when the gate valve is installed in the pipeline, there is no requirement for the direction of the inlet and outlet, and the medium can circulate in both directions. But the globe valve definitely has a direction of inlet and outlet. The flow direction of the globe valve can be down to up or up to down. Most flow type is from down to up for globe valve.
Because the gate valve can only be fully open and fully closed, when it is in a fully open state, the flow path in the entire pipeline is straight. When the medium flows through the valve body, there is nearly no obstruction, and the flow resistance is almost zero. In the globe valve, when the medium flows through the valve body, the flow direction is from top to bottom, and the resistance of the valve plug is relatively large.
When the gate valve is maintained and repaired, the gate valve needs to be disassembled completely from the pipeline, so the labor costs are relatively high. But for the globe valve, In most cases, the valve seat and plug can be directly replaced on the site without disassembling the complete valve. Therefore, the globe valve is suitable for welding connection applications.
The ball valve and globe valve both can be shut off the fluid of the pipeline.
The ball valve is evolved from the plug valve. Its opening and closing part is a sphere, which uses the sphere to rotate 90° around the axis of the valve stem to achieve the purpose of opening and closing.
Globe valve and butterfly valve both are common valves in industrial processes. What is the difference between the globe valve and the butterfly valve? The globe valve and the butterfly valve have similar functions, both of globe valve and butterfly valve can be used for flow regulating or cut off. The difference is that the globe valve has a better flow adjusting function when it is used to controlling the flow rate. The advantage of the butterfly valve is that it is more widely used, has a large flow capacity, shorter structure length, and a simpler structure.
The globe valve only allows the medium to flow in one direction when installed. The opening or closing stroke of the valve stem of the globe valve is relatively short, and it has a reliable shut-off function. Due to the response of the valve seat is proportional to the stroke of the valve plug, it is very suitable for flow adjustment. Therefore, this type of shut-off valve is very suitable for cutting off or regulating and throttling. The structural length of the globe valve is larger than butterfly valve.
A Butterfly valve is a rotary motion valve, which consists of four main parts: valve body, stem, disk and seat. A butterfly valve has a disc which is mounted on a rotating shaft. When the butterfly valve is fully closed, the disk back to seat and completely blocks the line. When the butterfly valve is fully opened, the disc is at a right angle to control the flow of gas or liquid.
Butterfly valve is a simple regulating valve, and it can also be used for on-off control of low-pressure pipeline media. There are many types of butterfly valves and used for wide range application. Butterfly valves are suitable for pipelines that transport various corrosive and non-corrosive fluid media in engineering systems such as generators, natural gas, petroleum, air, chemical and power plant, and are used for controlling and on/off medium. Butterfly valves have two-way sealing and one-way sealing.
The plug valve is suitable for cutting off or connecting pipeline media in various working conditions such as petroleum, chemical, pharmaceutical, fertilizer, and electric power industries with a nominal pressure of CLASS150-LBS and a working temperature of -29~550℃.
In total plug valve has a compact structure and a small volume, compared with a gate valve, the height of the valve is greatly reduced, also fluid resistance is greatly reduced.
A plug valve is a rotary type valve, the plug shaped like a cone or cylinder. It can be rotated inside the valve body to control the flow of fluids.
The opening process of the plug valve: When opening the valve, you need to rotate the handwheel to raise the plug and disengage it from the sealing surface. Rotate the handle 90° to make the passage of the plug communicate with the passage of the valve body, then to achieve the purpose of opening. The process of closing the valve is to rotate the handle 90° to make the passage of the plug perpendicular to the passage of the valve body, and then rotate the handwheel to lower the plug to achieve the seal.
Globe valves are used in steam lines because they can precisely control the flow and pressure of the steam, which is critical for the efficiency and safety of steam systems.
Globe valves are used in a variety of applications, including water, steam, and gas systems, where flow needs to be regulated or stopped completely.
A globe valve is best suited for applications that require flow regulation, throttling, and frequent operation. It’s also used where pressure drop through the valve is not a critical concern.
Yes, steam pressure can be controlled with globe valves by adjusting the valve opening, which regulates the flow and, consequently, the pressure.
Hunter PGV globe valves are typically used in irrigation systems and may be suitable for use on golf courses, depending on the specific requirements of the irrigation system.
Gas cylinders can have different types of valves, including gate or globe valves, depending on their intended use and the requirements of the system in which they are installed.
When fully open, globe valves do not significantly restrict flow, but they do have a higher pressure drop compared to other valves like ball or gate valves. When partially open, they effectively restrict and regulate the flow of hot water.
Yes, globe valves are commonly used on steam systems for their ability to throttle and precisely control the flow of steam.
A globe valve should be used when you need to regulate or throttle the flow, or when you require frequent operation of the valve.
Use a globe valve in a steam system when you need to control the steam flow rate or maintain and reduce steam pressure.
Place a globe valve at strategic points where flow control is needed, such as at the start of a zone, to regulate or stop flow for maintenance, or to control the flow to different sections of the system.
Globe valves are used in applications that require flow regulation, such as cooling systems, fuel oil systems, feedwater, chemical feed, and steam services.
Globe valves are linear motion valves that regulate fluid flow in pipelines. They are named for their spherical body shape, which houses a movable disk or plug mechanism. This mechanism controls the flow of fluid by closing, opening, or partially obstructing the valve’s flow path.
They are widely-used flow control devices in various industrial applications, and designed to regulate the flow of fluids, such as liquids, gases, and steam, in a flow stream a piping system. With their unique construction features and reliable performance, globe valves have gained popularity in industries such as oil and gas, power generation, chemical processing, and water treatment.
Globe valves are named after their spherical body shape, which houses a movable disc or plug, a stationary seat, and a stem. The stem connects the disc to an external handwheel or actuator. When the handwheel is turned or the actuator is activated, it moves the stem and disc either closer to or farther from the seat, thus controlling the flow rate and pressures.
There are three main types of globe valves, each with distinct characteristics:
Straight pattern globe valves have a linear flow path, with the inlet and outlet ports aligned vertically. The main components include a spherical body, a movable disc or plug, a stationary seat, and a stem connecting the disc to an external handwheel or actuator. The fluid enters from the port at the bottom and exits from the top of the valve, with the disc moving up and down to regulate the flow.
In angle pattern globe valves, the inlet and outlet ports are oriented at a 90-degree angle to each other. This design allows the fluid to change direction within the valve, making them ideal for situations where a change in flow direction is required or when space is limited. The main components are similar to those of a straight pattern globe valve: a body, a disc, a seat, and a stem. However, the flow path is bent within the angle pattern globe valve body, creating a 90-degree angle between the inlet and outlet ports.
Y-pattern stainless steel globe valves feature a 45-degree angle between the inlet and outlet ports. This design reduces pressure drop and turbulence within the valve, making them suitable for high-pressure and high-temperature applications or when minimizing erosion is critical. The main components of a Y-pattern, steel globe valve include a Y-shaped body, a disc, a seat, and a stem. The flow path is inclined at a 45-degree angle, which helps reduce flow resistance and minimize wear on the valve components.
Globe valves consist of several key components:
Globe valves are used across various industries, including:
Common applications include:
Proper installation, maintenance, and troubleshooting of globe valve control systems are essential for ensuring their optimal performance and longevity. By following best practices and addressing issues as they arise, you can maintain the reliability and efficiency of your globe valve system.
Globe valves should be installed with the disk facing upwards to ensure proper seating and minimize wear. This orientation also facilitates easier maintenance and inspection.
Regular maintenance is essential to extend the globe valve lifespan and ensure optimal performance. Maintenance tasks include:
Proper troubleshooting is essential for identifying and resolving issues with globe valves. By addressing problems promptly and accurately, you can ensure the reliable and efficient operation of your valve system. Below are some common issues encountered with globe valves and their potential solutions:
Issue: Fluid leakage is observed around the valve stem.
Solution: First, attempt to tighten the packing gland to compress the packing material and create a better seal. If the leakage persists, replace the packing material or consider repacking the entire valve.
Issue: Fluid leakage is detected at the flange connections.
Solution: Inspect the flange bolts for proper tightness and ensure they are evenly tightened following a crisscross pattern. If the leakage continues, replace the flanged gasket with a new one compatible with the fluid and operating conditions.
Issue: The valve becomes difficult to operate or the handwheel is hard to turn.
Solution: Check for misalignment, bent stems, or damaged actuators. Lubricate the stem and moving parts according to the valve manufacturer’s recommendations. If the problem persists, disassemble the valve to inspect for internal damage or obstructions and repair or replace the affected components as needed.
Issue: The valve fails to provide accurate flow control or the flow rate does not correspond to the handwheel position.
Solution: Inspect the disc and seat for wear, damage, or contamination. Replace or recondition the disc and seat if necessary. Also, check the stem and actuator for proper operation and alignment.
Issue: The valve produces excessive noise or vibration during operation.
Solution: Excessive noise or vibration may indicate cavitation, water hammer, or turbulent flow. Address the root cause by adjusting the flow rate, installing a valve with a different design, or adding additional flow control valves, accessories, or devices like a pressure-reducing valve or a flow control valve.
Issue: The valve does not close completely, leading to fluid leakage through the valve.
Solution: Inspect the disc and seat for damage, wear, or debris that may be preventing a tight seal. Clean, repair, or replace the disc and seat as necessary. Also, ensure that the valve stem is not bent or obstructed, preventing full closure.
By following a systematic approach to troubleshooting industrial valves and addressing issues as they arise, you can maintain the reliability and efficiency of your globe valve system. Regular inspection, timely repairs, and adherence to manufacturer guidelines will help prevent costly downtime and prolong the service life of your valves.
Selecting the right size and type of globe valve for your application is crucial for optimal performance, efficiency, and longevity. Several factors must be considered when choosing a globe valve, including the fluid type, flow rate, pressure, temperature, and installation requirements. Here are some key aspects to consider when sizing and selecting a globe valve:
2. Flow Rate:
Determine the required flow rate for your application to ensure the globe valve can adequately handle the flow. Valve sizing is based on the flow coefficient (Cv), which is a measure of the valve’s capacity to pass fluid. The larger the Cv value, the greater the flow rate the valve can handle. Select a valve with an appropriate Cv value to meet your flow requirements while minimizing pressure drop.
2. Fluid Type:
Consider the type of fluid the valve will handle (liquid, gas, or steam) and its properties, and features such as viscosity and corrosiveness. Select materials and sealing components compatible with the fluid to ensure reliable operation and prevent damage to the valve.
3. Pressure and Temperature:
Evaluate the operating pressure and temperature of the system to select a valve that can withstand these conditions. Ensure the selected valve’s pressure class and temperature rating meet or exceed the system’s requirements.
4. Valve Type:
Choose the appropriate type of globe valve (straight pattern, angle pattern, or Y-pattern) based on your application’s specific needs. Consider factors such as space constraints, flow direction changes, and pressure drop when selecting the valve type.
5. Material Selection:
Select the appropriate materials for the valve body, disc, seat, stem, and gaskets based on factors such as fluid compatibility, corrosion resistance, and temperature requirements. Common materials include cast iron, carbon steel, stainless steel, and brass.
6. Actuation:
Determine the appropriate method of actuation for your application (manual, electric, pneumatic, or hydraulic). Consider factors such as the required speed of operation, available utilities, and fail-safe requirements.
7. End Connections:
Select the appropriate end connections (flanged, threaded, or welded) based on your piping system requirements and ease of installation and maintenance.
8. Standards and Certifications:
Ensure the chosen globe valve meets the necessary industry standards and certifications for your application, such as ASME, API, or ISO.
9. Maintenance and Accessibility:
Consider the ease of maintenance and accessibility when selecting a globe valve. Options for valves that are easy to disassemble, clean, and replace parts, make them cost-effective and reducing downtime.
By taking these factors into account, you can select a globe valve that meets your application’s specific requirements and ensures efficient, reliable and long-lasting performance. Consult with valve manufacturers or engineers for expert advice on sizing and selecting the most suitable stainless steel globe valve for your needs.
Various standards and certifications govern the design, manufacturing, testing, and performance of globe valves to ensure their safety, reliability, and efficiency. Adherence to these standards is essential for maintaining quality and performance in the industry. Some of the most widely recognized standards and certifications for globe valves include:
ASME develops codes and standards for pressure-containing components, including valves. Key ASME standards related to globe valves include:
These standards cover aspects such as pressure-temperature ratings, materials, dimensions, and testing requirements for various valve types, including globe valves.
API is a leading organization that develops standards for the oil and gas industry, including valves. The following API standards are relevant to globe valves:
Although these standards primarily focus on gate valves, they may also apply to globe valves in certain situations, particularly for high-pressure and high-temperature applications.
ISO develops international standards for various industries, including valves. Some of the key ISO standards related to globe valves are:
These standards address aspects such as pressure testing and dimensional requirements for globe valves and other industrial valves.
MSS is an organization that develops standards for the valve and fittings industry. Some MSS standards that apply to globe valves include:
These standards cover requirements for corrosion-resistant valves and pressure testing procedures for globe valves and other valve types.
NACE develops standards related to the prevention and control of corrosion in various industries. The following NACE standard is relevant for globe valves used in corrosive environments:
This standard outlines material requirements and guidelines for valve control systems, including globe valves, used in sour service applications where hydrogen sulfide (H2S) is present.
This article provides an in-depth understanding of the various aspects of globe valves, including their design, types, functions, and key considerations for sizing, selection, and troubleshooting. This comprehensive guide aims to support professionals in making informed decisions when choosing the right valve for their application, ensuring optimal performance, reliability, and longevity.
As a reliable globe valve manufacturer in China, THINKTANK is committed to delivering high-quality products and unparalleled customer support. With our professional engineers ready to assist in sizing, selection, drawing, and other project requirements, we can provide customized solutions tailored to your specific needs. THINKTANK is known for offering affordable pricing without compromising on quality, making our cast steel globe valves a cost-effective choice for a wide range of applications.
Having exported to over 42 countries and provided OEM services for 25 international valve brands, THINKTANK has established a strong reputation for excellence in the global market. Our extensive experience and commitment to customer satisfaction make THINKTANK a trusted partner for your globe valve requirements.
By utilizing the information provided in this ultimate guide and partnering with a reputable manufacturer like THINKTANK, you can ensure the successful integration of globe valves in your applications, contributing to the efficiency, safety features, and reliability of your power systems.
1.ASME B16.34 – Valves – Flanged, Threaded, and Welding End: https://www.asme.org/codes-standards/find-codes-standards/b16-34-valves-flanged-threaded-welding-end
2. API 600 – Steel Gate Valves – Flanged and Butt-welding Ends, Bolted Bonnets: https://www.api.org/~/media/files/publications/whats%20new/600_e13%20pa.pdf
3.ISO – Industrial Valves – Pressure Testing of Valves: https://www.iso.org/standard/.html
4.ISO – Metal Valves for Use in Flanged Pipe Systems – Face-to-Face and Centre-to-Face Dimensions: https://www.iso.org/standard/.html
5.MSS SP-42 – Corrosion Resistant Gate, Globe, Angle, and Check Valves with Flanged and Butt Weld Ends: https://webstore.ansi.org/standards/mss/msssp
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