Valves are essential components in various industrial applications, including the processing of oil and gas, water treatment, power generation, and chemical manufacturing. They control the flow of liquids, gases, and other materials through pipelines, ensuring that the process runs smoothly and safely. When it comes to purchasing industrial valves, it’s essential to consider several factors to ensure you’re making the right decision. In this blog post, we’ll guide you through the process of buying industrial valves and help you make an informed purchase.
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The first step in buying industrial valves is to determine the type of valve that is appropriate for your application. There are several types of industrial valves, including ball valves, gate valves, globe valves, check valves, and diaphragm valves, among others. Each type of valve is designed to perform specific functions, and choosing the right type will depend on the characteristics of the fluid or material you’re handling, the temperature and pressure of the system, and the level of control you need.
Another important factor to consider when buying industrial valves is the size and pressure rating. Valves come in different sizes and pressure ratings, and you must choose the appropriate size and pressure rating for your system. The size of the valve is determined by the diameter of the pipeline it will be installed on, and the pressure rating will depend on the maximum pressure the valve can withstand without failing. It’s essential to choose a valve with the correct size and pressure rating to ensure it operates safely and effectively.
When purchasing industrial valves, it’s essential to ensure that they meet relevant certifications and compliance requirements. This will help you avoid purchasing substandard products that may fail prematurely or pose a safety hazard. The most common certifications for industrial valves include API, ISO, and CE. Make sure the valve you choose meets the necessary certifications and standards for your industry and application.
The reputation of the manufacturer is another important factor to consider when buying industrial valves. You want to purchase valves from a reputable manufacturer with a history of producing high-quality products. Look for manufacturers with a solid track record of producing valves that are reliable, safe, and durable. You can research the manufacturer’s history and customer feedback to get a better understanding of its reputation.
The cost of industrial valves is another important factor to consider, and it’s essential to find a balance between price and quality. While it may be tempting to opt for the cheapest option, this may not always be the best decision in the long run. High-quality valves can be more expensive, but they are typically more reliable and will last longer, saving you money in the long run.
Valve material selection can be likened to fighting the mythical hydra. You focus on one head and think you have it beaten, and then suddenly, you are being attacked by two others. The problem is multifaceted because there are often several different physical and chemical processes at play. In addition, each valve component may have a different set of critical property requirements.
However, it is important to note that the mechanisms that cause valve components to degrade are complex and interconnected. While this discussion provides general guidance and strives to increase awareness of the various factors involved in material selection, each process and product needs to be thoroughly reviewed and understood to select the best material.
The first step in fighting a dragon is to identify which monster to face first, and this can be the most difficult part of the material selection process. There are many reasons for control valve component degradation, including erosion, adhesive wear, flashing, cavitation, corrosion, temperature extremes, and others. Several of these challenges often occur simultaneously, so it is important to identify and understand each problem.
Erosion (Figure 1) is the physical removal of material from a part due to particulate in the process fluid. This effect is common with slurries or liquids carrying abrasive particles, and it is usually countered by using hard materials or high strength coatings.
Despite the misleading name, adhesive wear is not related to aggressive glue, but results when metals rub against each other. This can be particularly troublesome for high cycle valves that must operate continuously for long periods of time. The key to addressing this problem is selecting the right combination of materials so they do not damage each other. Different materials have varying predispositions for galling — another name for adhesive wear — but there are some general guiding principles. Two soft materials in contact tend to gall, but a hard material paired with a relatively soft material will last much longer.
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Flashing damage (Figure 2, left) occurs when a liquid passes through a valve and the downstream pressure is below the vapor pressure of the liquid. The liquid effectively boils as it moves through the throat of the valve, wearing metal in the process. Cavitation (Figure 2, right) is similar to flashing but is usually much more destructive. In this case, the liquid drops below the vapor pressure as it goes through the valve, but then the pressure rises, collapsing the bubbles. The resulting microjets and shock waves strike the valve walls, trim and downstream piping, inflicting damage.
Strength (or hardness) is a measure of how a material resists cutting, scratching or bending. Wear resistance indicates how well a material absorbs energy and avoids fracture or damage. Thermal expansion and corrosion resistance are self-explanatory, but the concept of “creep” is less common. Creep resistance is a solid material’s ability to avoid slowly deforming over long periods of stress while exposed to high temperatures. The best material for a particular application depends on how that component is being used in the valve, and this is why different valve components are often fabricated from varying materials.
Now that you have identified your adversary and know your goals, it is time to consider the array of arrows available in your quiver. The number of materials is expansive, and the breadth of proprietary and generic names often leads to confusion. For instance, “Hastelloy” is a common trade name, but there are over 20 versions of Hastelloy metals. There are at least six different alloys that are called Inconel. When referring to alloys, it is often best to use the generic names such as a UNS number or ASTM standard when possible to avoid confusion.
It is also important to understand how a particular metal protects against corrosion. Some materials employ passive corrosion resistance by forming a protective oxide layer which resists continued attack. Examples are stainless steel (SST), C-276 Hastelloy C and titanium. These materials tend to work well in oxidizing environments but work poorly in reducing environments, which attack the oxide layer. Other materials are more inert and do not readily react in many environments or do not rely as strongly on an oxide layer for protection. Examples of these materials include Monel, gold and Hastelloy B-3.
The Figure 5 table lists a variety of materials and their various strengths and weaknesses. It is important to note that this is an abbreviated list and only meant to illustrate the varying capabilities of the various material groups. This table should not be used as a guide for material selection.
Clearly, the number of options is huge, and the price differential from one alloy to another can be significant. When faced with a difficult material selection decision, it is advisable to discuss the options with your valve vendor. Often, several alloys may work, and the best choice for your particular application may be a combination of valve design and valve component material selection.
When faced with a difficult valve application, it is important to carefully and fully evaluate the situation to understand exactly what issues are at play. Often, there is a combination of physical processes (erosion, cavitation, etc.), as well as one or more corrosive processes, and it takes a complete understanding of the whole picture to fully address the problem. Once armed with that information, users can work with control valve vendors to select the best combination of valve design and component materials of construction to provide reliable, long-term service.
Fighting the hydra of material selection does not have to be a herculean effort when one is forearmed with process knowledge and has strong technical support in their corner. Using these skills, designers can solve vexing control valve headaches in their plant and become a process hero in no time.
Brett Hofman is an additive materials engineer for Emerson, researching how to realize the potential of additive manufacturing technologies in Emerson’s products. He previously held the role of materials engineer for Emerson’s flow control products, providing materials technical support on a global level to various departments across the company. He graduated from Iowa State University with Bachelor of Science in materials engineering in .
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