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Swagelok® Steam-Heated Vaporizing Pressure-Reducing Regulators
Steam-heated vaporizing regulators are designed to meet unique application needs.
Request More InformationSteam-heated gas vaporization regulators are designed to accommodate phase changes, such as the heating or vaporizing of gases or liquids before it enters a downstream system.
Swagelok® steam-heated vaporizing pressure-reducing regulators have a low internal volume and can be used to vaporize liquid samples or to preheat gas samples to prevent them from condensing.
Specifications
Maximum Inlet Pressure | 3600 psig (248 bar) |
Pressure Control Ranges | 0 to 10 psig (0.68 bar) through 0 to 500 psig (34.4 bar) |
Flow Coefficient (Cv) | 0.06 or 0.20 |
Maximum Steam Pressure and Temperature | 650 psig (44.7 bar) and 500°F (260°) |
Maximum Operating Temperature | 392°F (200°C) |
Vaporizing Regulators Catalogs
Find comprehensive details on our, steam-heated vaporizing pressure-reducing regulators covering construction materials, accessories, pressure, and temperature ratings.
Swagelok offers pressure-reducing and vapor recovery (back-pressure) tank blanketing regulators for systems requiring an inert gas in the vapor space of a storage tank.
Swagelok offers pressure-reducing, back-pressure, dome-loaded, and spring-loaded pressure regulators to control pressure and minimize droop in instrumentation systems.
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Need Help Selecting the Right Regulators?
Evaluate the performance of various vaporizing regulators across diverse applications conditions using our Regulator Flow Curve Generator tool.
Find the Right RegulatorSwagelok Regulator Resources
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Managing Supply Pressure Effect (SPE) in a Regulator
Supply pressure effect, also known as dependency, is an inverse relationship between inlet and outlet pressure variables within a regulator. Learn how to manage this phenomenon in your pressure regulators with tips from Swagelok.
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How Thorough Testing Ensures Reliable Regulator Performance
Have you ever wondered what testing goes into a product designed to operate in extreme conditions? Take a look behind the lab doors, following the development journey of RHPS Series industrial regulators rated for use at temperatures well below zero.
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How to Flatten a Regulator Flow Curve to Reduce Droop
Droop is an issue for every pressure-reducing regulator. Learn how to minimize droop and flatten regulator flow curves with various dome loaded regulator configurations.
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How to Use a Regulator to Reduce Time Delay in an Analytical Instrumentation System
Time delay is often underestimated or misunderstood in analytical systems. One way to mitigate this delay is with a pressure-controlled regulator. Learn how to manage your analytical system’s time delay with these tips.