Stop valves are an essential component in various industries, including oil and gas, mining, chemical industry, main water shut down, power plant, textile and sugar mill, etc. If you’re looking to buy a stop valve for your industrial application, it’s important to consider several factors that can impact the price and quality of the valve. In this post, we’ll list the price for stop valve, and explore what you need to know about stop valve price and what factors to consider when purchasing stop valves.
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Stop valves are essential components used in various industrial applications, including oil and gas, mining, and manufacturing. They are designed to isolate or control the flow of fluid within a pipeline, allowing operators to stop or start the flow as needed. Stop valves are an important part of any industrial system, as they help to regulate the flow of fluids, prevent leaks, and ensure the safety of workers and equipment.
At THINKTANK, we understand the importance of stop valves in industrial applications. We provide high-quality valves that are designed to meet the specific needs of each application, ensuring reliable performance and long-lasting durability. Our valves are precision-engineered using the latest technology and highest-quality materials and are tested to rigorous standards to ensure their quality and performance.
Whether you’re looking for a replacement stop valve for a specific application, or you’re looking for advice on the best valve for your needs, our team is here to help. We have a team of experts with years of experience in the valve industry, and we’re always happy to provide advice and guidance to help you make informed decisions about your industrial valves.
To learn more about our selection of stop valves and how they can benefit your industrial application, please explore our website. We offer a range of free resources, including video testimonials, technical specifications, and warranty details, to help you make the best choice shut off valve for your needs.
Stop valves are a crucial component in the flow control process, and there are several types available, each with different advantages and disadvantages. Understanding the different types of stop valves can help in selecting the right valve for specific industrial applications. Here are some commonly used types of stop valves.
Ball valves are used to control fluid flow and consist of a spherical disc inside the valve body. Ball valves offer precise control and are suitable for a wide range of industrial applications. They are also easy to operate and durable, making them ideal for high-pressure and high-temperature applications.
Gate valves, also known as sluice valves, are designed to open and shut off fully and quickly. They use a gate-like component to control fluid flow and provide a tight shutoff when closed. Gate valves are commonly used in applications where a full open or full close of the valve is required, such as pipeline isolation or emergency shutoff.
Globe valves are highly versatile valves designed to regulate the flow of fluid. They use a disk and a seat mechanism to control fluid flow, making them perfect for applications that require accurate flow control. Globe valves can handle high-temperature and high-pressure applications and are widely used in refining and petrochemical applications.
Check valves are designed to prevent backflow in a pipeline. They use a spring-loaded mechanism to allow fluid flow in one direction while preventing it from flowing in the opposite direction. Check valves can handle high-pressure and high-temperature applications, making them ideal for industries that require the prevention of backflow.
In-depth discussion of the different factors to consider when buying stop valves, including material, size, type, pressure rating, and certifications.
When it comes to purchasing stop valves, there are several crucial pricing factors to consider to ensure that you are getting the right valve for your industrial application. These factors include the material, size, type, pressure rating, and certifications.
Stop valves are made from a range of materials, including brass, stainless steel, cast iron, and plastics. The material that you choose will affect the valve’s durability, operating temperature, and pressure capabilities. Brass is an excellent choice for low-temperature and low-pressure applications, while stainless steel valves can withstand high-temperature and high-pressure applications. Cast iron is an affordable option that can withstand high pressure and temperatures, while plastics such as PVC and CPVC are ideal for corrosive applications.
The size of the valve you need will depend on the size of the pipe and the flow requirements of main water for your application. The larger the valve, the more expensive it will be. It’s important to choose the correct size valve to ensure optimal performance.
Stop valves come in many different types, including ball valves, gate valves, globe valves, and check valves. Each type has unique features and benefits that make it suitable for specific applications or environments. For example, ball valves are widely used in the oil and gas industry for their durability and ease of operation, while globe valves are commonly used in refining and petrochemical applications due to their precise flow control.
Valve pressure rating is the maximum allowed pressure that a valve can handle. This factor is crucial to consider because an overpressure can result in catastrophic consequences. The higher the rating, the more expensive the new valve is.
Valve certifications ensure that your valve meets specific safety standards and industry regulations. Certifications such as API 6D, ASME B16.34, and ISO demonstrate quality standards and compliance with industry regulations. It is important to choose a valve with the appropriate certification to guarantee that you are compliant with industry standards.
Stop valve price varies depending on factors such as material, size, type, pressure rating, and certifications. It’s essential to take these factors into account when selecting valves for your industrial application to ensure safety, reliability, and optimal performance. Please feel free to contact us for more information on our selection of high-quality stop valves.
When it comes to stop valves, there are many customization options available to meet specific needs and requirements. These customization options can affect the price of the valve. Here are some common customization options for stop valves and how they can affect the price:
There are various types of seals and connection options available, such as welded, threaded, or flanged connections, which can affect the price of the valve. Different seals and connections may be required depending on the specific application, and selecting the right ones can improve the valve’s performance and increase its lifespan.
Customizing the valve’s operation -such as manual, pneumatic, or electric-operated valves which can affect the price. Automated valves are easier to operate and more reliable than manual valves, but they can be more expensive to replace.
Customizing materials used in manufacturing the valve, such as choosing to install special alloys or coating to avoid corrosion, may affect the cost of the valve.
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Customizing testing requirements and valves certifications to meet specific safety standards and industrial regulations may add additional costs to the price of replacing the valve.
We provide many customization options for stop valves which can significantly influence the stop valve price. It’s important to discuss customization options with a valve expert to determine the best option that meets your specific needs and requirements without unnecessarily increasing the cost. At THINKTANK, we provide a wide range of customization options that suit most needs and guarantee the best valve performance, coupled with free resources that aid in your selection process. Contact us today to learn more about our selection of high-quality stop valves and get personalized advice on selecting the right valve for your industrial application.
What Are Codes, Standards, and Specifications?
On March 20, , a boiler explosion combined with a fire killed 58 people and injured 150 at the R. B. Grover shoe factory in Brockton, Massachusetts. Today, we do not hear much about boiler explosions, but in the late 19th century, they happened every other day in the United States.1 The Grover Shoe Factory disaster was the proverbial ‘straw that broke the camel’s back’ – as it rallied public opinion to the need of better industrial safety. The present ASME Boiler & Pressure Vessel Code (BPVC) was written by the American Society of Mechanical Engineers as a direct result from the Grover disaster.
According to ASME2, a “code is a standard that has been adopted by one or more governmental bodies and is enforceable by law. A standard can be defined as a set of technical definitions and guidelines that function as instructions for designers/manufacturers and operators/users of equipment.” Those definitions help, but they still leave many people scratching their heads. An example can be used to clarify this system.
Suppose one wants to build a new refinery. For that among other things, pressure vessels, piping, and valves are required. In the United States, most States have laws that dictate that pressure vessels must be designed, built, and installed according to the ASME BPVC. For piping, a refinery needs another code; the one most used is the ASME B31.3 (Process Piping). These codes specify the minimum engineering requirements deemed necessary for safe design and construction of pressure vessels and pressure piping. And what about valves?
One can think of codes as mandatory design guidelines, a set of instructions to be used when dealing with a ‘system’ such as pressure vessels or piping. ‘System’, in this instance, means that the final product is the sum of many parts. For example, both pressure vessels and piping require, among other things, flanges and gaskets. Codes do not detail everything that goes into the final ‘system’; any industrial product that is required for a system is referred to in a related standard. So, a standard is a document referred in a code that contains instructions on design, fabrication quality control, and testing of a particular item. By using standards, the code gets simplified and ensures that all items used in the ‘system’ are ‘standard’ (uniform in design and fabrication), preventing incompatibility issues and limiting the number of variations for a single item.
Looking again at the refinery example, future piping will follow the ASME B31.3. This code references several valve standards that can be used. For ball valves, for example, one can select API 608 (Metal Ball Valves-Flanged, Threaded, and Welding End) or API 6D (Specification for Pipeline and Piping Valves). For gate valves there is API 600 (Steel Gate Valves—Flanged and Butt-welding Ends, Bolted Bonnets), for butterfly there is API 609 (Butterfly Valves: Double-flanged, Lug- and Wafer-type), and so on.
When people talk about specifications, they can be referring to one of two things. One is a datasheet, that is, the technical requirements of an equipment. For example, annex ‘O’ of the edition of the API 6D is named ‘Purchasing Guidelines’. On this annex there is a proposed table for a valve datasheet and API 6D states that this table “can be used to assist with the specification of valves for ordering”.
The second possibility of the term ‘specification’ is related to materials. Equipment covered by ASME codes rely on a limited choice of materials. As a rule, pressure vessels, piping, and valves must be made using materials that have mechanical and chemical properties listed on the related ASME code.
Basically, every material listed on an ASME code has an ASTM specification such as ASTM A216/A216M-21 (Standard Specification for Steel Castings, Carbon, Suitable for Fusion Welding, for High-Temperature Service) or ASTM A182/A182M-21 (Standard Specification for Forged or Rolled Alloy and Stainless Steel Pipe Flanges, Forged Fittings, and Valves and Parts for High-Temperature Service). These specifications contain requirements for chemical and mechanical properties, heat treatment, manufacture, heat and product analyses, and methods of testing. Figure 1 provides examples of codes, standards, and materials specifications for an American refinery.
It is also worth mentioning that standards and materials specifications might be amended by the end user. For example, more stringent rules might be forced by contract upon the supplier via supplementary requirements. The S-562 (Supplementary Requirements to API Specification 6D Ball Valves) is a publication from the IOGP with a set of supplementary requirements for the specification for procurement of trunnion mounted ball valves (only) to API Specification 6D Twenty-Fourth Edition, . Ball valves complying with the S-562 have, among other things, more specific design rules and more extensive testing.
Basic Standards Related to Industrial Valves
The takeaway from the previous session is that one can only discuss valves after they have agreed upon which code/standard they must comply with. If talking about a refinery, ASME B31.3 is an option. If talking about valves for the water distribution in a city, then many of the valves listed on ASME B31.3 are of little use. Most likely, the city rely on valves complying with the standards issued by the AWWA (American Water Works Association). Different industries, different codes, different valves. However, that does not mean that we cannot find valves from AWWA listed on ASME codes.
Continuing with the refinery example, the edition of the ASME B31.3 lists the following standards related to valves. It is worth noting that there are valve standards from four regulatory bodies: ASME, API, AWWA, and MSS.
ASME B16.10: Face-to-Face and End-To-End Dimensions of Valves
ASME B16.34: Valves-Flanged, Threaded, and Welding End
API 6D: Pipeline Valves
API 526: Flanged Steel Pressure-Relief Valves
API 594: Check Valves: Flanged, Lug, Wafer and Butt-welding
API 599: Metal Plug Valves—Flanged, Threaded, and Welding Ends
API 600: Bolted Bonnet Steel Gate Valves for Petroleum and Natural Gas Industries
API 602: Gate, Globe, and Check Valves for Sizes DN 100 and Smaller for the Petroleum and Natural Gas Industries
API 603: Corrosion-Resistant, Bolted Bonnet Gate Valves — Flanged and Butt-Welding Ends
API 608: Metal Ball Valves-Flanged, Threaded, and Welding End
API 609: Butterfly Valves: Double-flanged, Lug- and Wafer-type
AWWA C500: Metal-Seated Gate Valves for Water Supply Service
AWWA C504: Rubber-Seated Butterfly Valves
MSS SP-6: Standard Finishes for Contact Faces of Pipe Flanges and Connecting-End Flanges of Valves and Fittings
MSS SP-25: Standard Marking Systems for Valves, Fittings, Flanges, and Unions
MSS SP-42: Class 150 (PN 20) Corrosion Resistant Gate, Globe, Angle and Check Valves with Flanged and Butt Weld Ends
MSS SP-70: Gray Iron Gate Valves, Flanged and Threaded Ends
MSS SP-71: Gray Iron Swing Check Valves, Flanged and Threaded Ends
MSS SP-72: Ball Valves with Flanged or Butt-welding Ends for General Service
MSS SP-78: Gray Iron Plug Valves, Flanged and Threaded Ends
MSS SP-80: Bronze Gate, Globe, Angle and Check Valves
MSS SP-81: Stainless Steel, Bonnet-less, Flanged, Knife Gate Valves
MSS SP-85: Gray Iron Globe and Angle Valves, Flanged and Threaded Ends
MSS SP-88: Diaphragm Type Valves
MSS SP-105: Instrument Valves for Code Applications
The list of valve standards on the ASME B31.3 is not exhaustive; If one studies the list above, it is apparent that some very common valve standards are missing. For example, the BS (Specification for Steel Globe Valves). BS globe valves are routinely used in refineries, but how is that possible if the standard is not listed on the ASME B31.3? The answer lies in dual certification. For the purposes of wall thickness, materials, and pressure-temperature rating, manufacturers use the ASME B16.34 as guidance, while also complying with the BS . That way, a BS valve is also in accordance with the ASME B31.3.
The standards listed above do not cover all aspects of valve performance required for a refinery application. A typical standard, API 6D for example, has in its table of contents the following sections:
1. Scope
2. Normative References.
3. Terms, Definitions, Acronyms, Abbreviations, Symbols, and Units
4. Valve Types and Configurations
5. Design
6. Materials
7. Welding
8. Quality Control
9. Pressure Testing
10. Coating/Painting
11. Marking
12. Preparation for Shipment
13. Documentation
14. Facility Requirements
15. Annexes
16. Bibliography
Missing from the list are some very important issues. For example, different standards for Fire Testing, Fugitive Emissions Testing, Cryogenic Testing, and Qualification / Prototype Cycle Testing are often required (See Table 1). These last standards are normally listed in the normative references of the main valve standard that is being used.
Conclusion
Industrial equipment is required by law, contracts, or good practices to rely on codes, standards, and specifications. These documents may vary in different countries – they may even vary within a country – and different industries. Before writing a valve specification or answering a ‘Request for Quotation’, make sure to understand which codes and standards are referred to.
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