Standards Clarification: Pressure Rating Standards for Flanged Valves

42” rotary cone valve and metal seated ball valves are used in a raw water pumping station, San Vicente, CA

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Overview

In any industry, one of the most challenging tasks is often keeping up-to-date and compliant with a complicated and changing set of performance standards. In an ideal world, performance standards serve a vital purpose by guiding employees and end users to the most efficient application of their equipment. Unfortunately, good intentions can often turn into overzealousness, creating a situation in which performance standards create as many problems as they solve. To make matters worse, many industries feature multiple agencies and advocacy groups that publish competing sets of standards, making it even more difficult to understand and employ their suggestions. An ideal set of performance standards should be unambiguous and easy to interpret, leading industry stakeholders to proper decision making.

In water works service, pressure rating standards are used to define the acceptable use of flanged valves. However, because of the multiple sets of variables involved in the use of flanges, including material of construction and temperature, pressure rating standards can be complicated and difficult to interpret. Compounding the issue is the fact that workers in the water service industry must contend with standards issued by multiple organizations, the American Society of Mechanical Engineers (ASME), whose work has been accredited by the American National Standards Institute (ANSI), and the American Water Works Association (AWWA). If you are already confused, you are not alone; the complex and often contradictory standards issued by these two organizations, in addition to manufacturer literature that can muddy the waters further, can lead to misunderstandings or improper application.

High Stakes

For a piping system to perform reliably and successfully, each of its component parts must function properly. Any weakness or improper application at any point in the piping system could result in higher construction and maintenance costs as well as decreased efficiency. Those responsible for the construction, maintenance and performance of pressurized systems must have a complete grasp on the pressure ratings of every component in their system.

Deciphering the Standards

In considering pressure rating standards for valve flanges, it is essential to understand the various factors involved. Each of these factors (material, size, and temperature) impacts the resultant pressure rating. Pressure ratings are measured in pounds per square inch gauge (psig). Valve flanges are constructed of different materials, including steel, stainless steel, gray iron and ductile iron. As each of these materials offers a different strength, they each correspond with a different pressure rating. Ductile iron is stronger than gray iron, while steel is considerably stronger than either iron alloy.

Flange sizes are measured by the size of the pipe and are expressed as Nominal Pipe Size (NPS). This measurement does not correspond precisely to the size of the pipe in inches; rather, it is a dimensionless reference to the nominal diameter (DN) in inches used in international standards. DN standards are also dimensionless. The relationship of NPS to DN can roughly be calculated as DN = NPS x 25. As NPS increases, the pressure rating of the flange decreases.

In addition to flange sizes as measured in NPS, flange thickness can also vary and must be taken into account. Flange gaskets are also variable and can be found in one of three variations: smooth gasket, flange tyte gaskets, and triple seal gaskets. For a comprehensive report on these factors, one should consult AWWA C111, “Rubber-Gasket Joints for Ductile-Iron Pressure Pipe and Fittings.”

Temperature is the final key to determining the pressure rating of valve flange. Because metals are weaker at higher temperatures, high pressure ratings correspond with lower temperatures. The noticeable disparity in pressure ratings between high temperature situations and low temperature situations is what prompted the American Water Works Association to issue its own set of standards specific to cold water service.

ASME/ANSI Standards

The American Society of Mechanical Engineers recognized the importance of reliable standards and were the first to create a set of performance standards for valves, flanges, and fittings in . There are three relevant sets of ASME/ANSI standards for flanged valves and fittings, each of which corresponds to construction material. Gray iron flanges and fittings correspond to ASME B16.1. Ductile iron flanges and fittings correspond to ASME B16.42. Steel flanges and fittings correspond to ASME B16.5.

AWWA Standards

The American Water Works Association issued its own set of standards specifically for cold water service. AWWA C110 applies to ductile iron and gray iron flanges and fittings. AWWA C207 was developed more recently and applies to steel flanges and fittings. As these standards are designed for cold water service, their pressure ratings are higher than ASME/ANSI ratings for a fitting of similar size and material; this is because ASME/ANSI fittings are expected to deal with more hazardous service situations.

Table 1: Applicable Flange and Fitting Standards

Flange and Fitting Standard Construction Material ASME B16.1 Gray and Ductile Iron ASME B16.42 Ductile Iron ASME B16.5 Steel and Stainless Steel AWWA C110 Gray and Ductile Iron AWWA C207 Steel

Classes

Perhaps the most outwardly confusing aspect of pressure rating standards is the inclusion of classes. These classes are designations based on a specific pressure and temperature for saturated steam. Pressure classes are not, as is often misconceived, based on pressure ratings from the flange. The determination of pressure classes was clearly described in a November Valve Magazine article, “Understanding and Selecting Valve Flanges, Pt. I: Design and Standards.”

In all sets of standards, as the class rating increases, the pressure rating increases. As can be observed in the ASME/ANSI Standards found in Table 2, class rating never corresponds exactly to pressure rating at temperatures of 100°F, 200°F, or 300°F.

It is important to note that Class 125 and Class 150 flanges use the same bolting pattern and can be bolted together, despite the fact that they have different pressure ratings. The same principle holds true for Class 250 and Class 300 flanges. Gray iron flanges are “flat-faced,” ductile iron flanges are typically flat-faced, and steel flanges can have either raised or flat faces. Because of this potential incongruity, gray iron flanges can only be bolted to ductile iron or steel flanges if the raised face of the mating flange is removed or if the mating flange is also flat-faced. This precaution prevents the breaking of the gray iron flange when tightening the bolts.

Table 2: Flange Pressure Ratings According to ASME/ANSI Standards (psig)

Gray Iron ASME B16.1 Ductile Iron ASME B16.42 Class 125 Class 250 Class 150 Class 300 Max Temp. NPS 1-12 NPS 14-24 NPS 1-12 NPS 14-24 NPS 1-12 NPS 14-24 NPS 1-12 NPS 14-24 100° F 200 150 500 300 250 250 640 640 200° F 190 135 460 280 235 235 600 600 300° F 165 110 375 240 215 215 565 565

Table 3: Flange Pressure Ratings According to AWWA Standards (psig)

Gray Iron AWWA C110 Ductile Iron AWWA C110 Steel AWWA C207 Class 125 Class 125 Class D Class E Class F Max Temp. NPS 3-12 NPS 14-24 NPS 3-12 NPS 14-24 NPS 3-12 NPS >12 NPS 3-12 NPS >12 NPS 4-48 100° F 250 250 350 350 175 150 275 275 300

Tables 2 and 3 provide a clear reference for the various pressure rating standards assigned by the ASME/ANSI and AWWA. ASME B16.5 prescribes several tables for different materials and temperatures, the details of which are beyond the scope of this paper. To ensure compliance, consult the tables found in the published standard. It is important to note that the AWWA Standards are only listed with a maximum temperature of 100°F because of their exclusive design for cold water service.

Complicating Matters Further: Valve Pressure Ratings

Even after developing a clear understanding of the ASME/ANSI and AWWA pressure rating standards for flanges, it must be acknowledged that the flange is not the only part of the piping system. Just as crucial is the valve itself, and unfortunately, valve pressure ratings can differ entirely from the pressure ratings of a flange in the same class.

The American Water Works Association has issued standards for many of the valves used in water service, but users must take caution when using these standards in combination with AWWA pressure rating standards for flanges. The pressure ratings often differ within a given class, and a responsible service provider must understand these differences to prevent accidents. The key tenet to recognize is that a piping system is only as strong as its weakest component; therefore, all decisions related to pressure should be built around the pressure rating of the system’s weakest link.

A tilting disc check valve is used at a raw water pumping station in Bakersfield, CA

Table 4: Flange Compatibility

Class of Flange Flange Material Pressure Rating Compatibility ANSI B16.1 Cl. 125 ASTM A 126 Cl. B Iron 1”-12” 175 psi; 14”-48 150 psi AWWA* Cl. B, D, E; ANSI B16.5 Cl.150, ANSI B16.42 CL. 150 ANSI B16.1 Cl. 250 Same as above 1”-12” 400 psi; 14”-48” 300 psi AWWA Cl. F, ANSI B16.42 Cl. 300 ANSI B16.5 Cl. 150 Carbon or Stainless Steel 275 psi @ 100 deg. F AWWA Cl. B, D, E; ANSI B16.1 Cl.125, ANSI B16.42 CL. 150 AWWA Cl. B Carbon Steel 86 psi AWWA Cl. D, E; ANSI B16.1 Cl.125 B16.5 Cl. 150, ANSI B16.42 CL. 150 AWWA Cl. D Carbon Steel 1”-12” 175 psi; 14”-144 150 psi AWWA Cl. B, E; ANSI B16.1 Cl.125 B16.5 Cl. 150, ANSI B16.42 CL. 150 AWWA Cl. E Carbon Steel 275 psi AWWA Cl. D; ANSI B16.1 Cl.125, ANSI B16.42 CL. 150 AWWA Cl. F Carbon Steel 300 psi ANSI B16.1 Cl.250 , ANSI B16.42 Cl. 300

Also of Significance: Minimum Wall Thickness Standards

In addition to ASME/ANSI and AWWA standards applicable to pressure ratings, one other set of standards to remain aware of are those relating to the minimum wall thickness of resilient gate valves. AWWA Standard C509 was created to cover resilient seated gate valves made of gray cast iron, the most common metal used at the time of publishing in . As manufacturers turned to ductile iron, Standard C515 was issued to compensate for the higher strength of the new material. The following table defines the applicable wall thickness standards.

Table 5: Minimum Wall Thickness Standards According to AWWA

Size (in.) AWWA C509 – Gray Iron AWWA C515 – Ductile Iron Minimum Wall Thickness (in.) Minimum Wall Thickness (in.) 3 0.37 0.30 4 0.40 0.31 6 0.43 0.32 8 0.50 0.34 10 0.63 0.36 12 0.68 0.38

In the world of industrial piping and fluid systems, flanges are critical components that allow for the connection, maintenance, and pressure management of pipelines. However, not all flanges are created equal — especially when you’re dealing with international projects. Two of the most widely used flange standards are JIS (Japanese Industrial Standards) and ANSI (American National Standards Institute).

At Hebei Leading, we manufacture and supply flanges according to JIS, ANSI, DIN, EN, and other global standards. In this article, we’ll explain the major differences between JIS and ANSI flanges, helping you make the right decision for your piping project.

What Is a Flange Standard?

A flange standard defines the dimensions, pressure class, face type, bolt hole patterns, and materials used for a specific type of flange. It ensures interchangeability and compatibility between pipeline components, regardless of the manufacturer.

Flange standards are important because:

• They determine connection size and pressure rating

• They affect installation tools and torque values

• Using the wrong flange type can lead to leakage or mechanical failure

Overview: JIS and ANSI Flange Standards

JIS Flanges

• Full Name: Japanese Industrial Standards

• Pressure Ratings: 5K, 10K, 16K, 20K, 30K

• Units Used: Metric (mm, kg/cm²)

• Common Applications: Asia-based industries, marine piping, water treatment

JIS flanges are often used in countries like Japan, South Korea, Taiwan, and in systems that were originally built with metric standards.

ANSI Flanges

• Full Name: American National Standards Institute

• Also Known As: ASME B16.5 flanges

  If you are looking for more details, kindly visit ANSI Standard Flange Type Gate Valve.

• Pressure Ratings: CL150, CL300, CL600, CL900, CL, CL

• Units Used: Imperial (inches, PSI)

• Common Applications: Oil & gas, petrochemical, power generation, US-based projects

ANSI flanges dominate in North America and are commonly used worldwide for API pipelines, high-pressure steam, and industrial machinery.

Key Differences Between JIS and ANSI Flanges

Here’s a side-by-side comparison table to highlight the technical and dimensional differences:

Why It Matters: Compatibility Issues

You cannot directly connect a JIS flange to an ANSI flange because of:

• Different bolt circle diameters

• Varying thickness and pressure ratings

• Inconsistent gasket size requirements

If mismatched, it can lead to:

• Leaks

• Bolt misalignment

• Unsafe pressure containment

To connect JIS and ANSI systems, you must use adapter flanges or custom-machined transition pieces — which can be costly and time-consuming.

Application Examples

Example 1: Water Treatment Facility in Japan

A municipal water system uses JIS 10K flanges for stainless steel pipe lines. The system operates under low to medium pressure, and all valves and pumps are JIS-compatible.

Example 2: Oil Refinery in the U.S.

A high-pressure steam pipeline uses ANSI CL600 flanges, built according to ASME B16.5 standards, designed for temperatures up to 538°C (°F).

Hebei Leading has supplied both types of systems, offering custom flange solutions for international EPC projects and retrofit systems.

Hebei Leading: One-Stop Flange Supplier

At Hebei Leading, we manufacture and export flanges according to JIS, ANSI/ASME, DIN, BS, and EN standards. Our flange products cover:

• Materials: Carbon Steel (A105), Stainless Steel (304/316), Alloy Steel

• Sizes: ½" to 48"

• Types: Slip-on, Weld neck, Blind, Socket weld, Threaded, Lap joint

• Face Types: RF, FF, RTJ

• Pressure Ratings: From 5K to CL

 Services We Offer:

• Custom flange machining (hole drilling, surface finish)

• Material certification (EN 3.1)

• Third-party inspection support (SGS, BV)

• Seaworthy wooden packing and international shipping

Visit our Product Page to explore flange categories and specifications.

Final Advice: Choosing the Right Standard

Here’s how to decide:

• ✔ If your project is in Japan or East Asia, or connects to metric components → use JIS flanges

• ✔ If your system is ANSI/ASME-based or used in oil, gas, or power → go for ANSI flanges

• ❌ Never mix both without using specially engineered adapters

Still unsure which flange type you need? Contact Hebei Leading's engineering team for expert advice, drawings, and quick quotations based on your application needs.

Conclusion

Understanding the difference between JIS and ANSI flange standards is crucial for international project success. While both are reliable in their own right, their technical specifications and dimensional requirements are not interchangeable.

With Hebei Leading, you gain access to a global flange supplier that understands regional standards, ensures compliance, and delivers with precision.

Let us help you simplify your flange procurement today — reliable quality, technical support, and fast delivery are just a message away.

For more information, please visit DIN Standard Check Valves.