{"id":19959,"date":"2019-04-01T14:42:19","date_gmt":"2019-04-01T14:42:19","guid":{"rendered":"https:\/\/www.simscale.com\/?p=19959"},"modified":"2026-02-16T23:47:37","modified_gmt":"2026-02-16T23:47:37","slug":"globe-valve-pressure-drop","status":"publish","type":"post","link":"https:\/\/www.simscale.com\/blog\/globe-valve-pressure-drop\/","title":{"rendered":"How to Calculate the Pressure Drop across a Globe Valve"},"content":{"rendered":"

Understanding how a valve operates across a range of operating conditions is critical in characterizing its overall performance. Industry standards, such as Cv, have been developed to normalize how valve performance is evaluated. Cv is a relative value which measures flow rate for a given pressure delta across the valve. The bigger the Cv, the more flow a valve can pass for a defined pressure drop. Cv allows a design engineer to quickly compare different models or brands of valves, as well as find the best fit for their application.<\/p>\n

<\/span> What is a Globe Valve?<\/strong><\/h2>\n

A globe valve<\/a> regulates flow through vertical linear motion of a globe-shaped plug. Each globe valve consists of a main body, stem, plug (i.e., \u201cglobe\u201d), and bonnet. It is primarily used for regulating fluids which are corrosive or have high viscosity. Due to its inherent shape, most of the fluid will drain off on the discharge side if the valve is completely closed, which minimizes the chances of corrosion or clogging.<\/p>\n

\"parts
Parts of a globe valve<\/figcaption><\/figure>\n

Simulating Pressure Drop<\/span> Case Study: Predicting Pressure Drop through a Globe Valve<\/strong><\/h2>\n

The geometry used for the case simulation was taken from GrabCAD<\/a> as a standard globe valve, with flow going from left to right within the model as pictured below. The CFD simulation<\/a> answers two questions: What is the resulting flow rate for a given pressure drop? And how does this change with respect to plug position? Furthermore, fluid forces on the plug can be monitored to evaluate structural performance.<\/p>\n

\"CAD
CAD model of the globe valve chosen for this case<\/figcaption><\/figure>\n

With the given CAD model, the fluid domain has not yet been defined. For the next step, it is necessary to extract the flow volume based on the current geometry. This can be done automatically in the SimScale platform.<\/p>\n

\n

To learn more about the CFD simulation capabilities of the SimScale platform, download this features overview.<\/a><\/strong><\/p>\n

\n

The resulting body is the negative of the valve geometry, as shown below. In preparation for simulation, both an inlet and outlet pipe extension were added on to allow enough entrance length for fully developed flow.<\/p>\n

\"the
The negative of the valve geometry<\/figcaption><\/figure>\n

Globe Valve Optimization<\/span> What is The End Goal of The Simulation?<\/strong><\/h2>\n

The purpose of the simulation is to calculate the flow coefficient. As an industry standard, it describes the flow rate across an orifice, valve or another assembly for a given pressure drop. This equation uses gallons per minute for units of flow rate, and pounds per square inch for pressure. The specific gravity value is usually set to 1, which is the specific gravity of water. The standard simulation setup consists of defining a 1 psi pressure drop across the valve and then running a CFD simulation to evaluate the flow rate.<\/p>\n

\"formula<\/p>\n

Getting Started<\/span> Valve Simulation Setup<\/strong><\/h2>\n

A 1 PSI pressure boundary condition was defined at the inlet, and a 0 pressure boundary condition was defined at the outlet. A simulation was run to calculate the flow rate at 6 different plug positions: 1, 2, 4, 6, 8, and 10 mm. All six simulations were run simultaneously on 32-core machines, which rapidly increases the turnaround time when compared to traditional desktop CFD software.<\/p>\n

\"CAD<\/p>\n

A hex-dominant automatic mesh was used with a general fineness setting set to moderate. To increase the accuracy of the results, feature refinement, surface refinement, region refinement, and wall layers were also added to further enhance the mesh.<\/p>\n

\"Mesh
Mesh of the valve<\/figcaption><\/figure>\n

CFD Simulation<\/span> CFD: Incompressible Analysis of a Globe Valve<\/strong><\/h2>\n

The geometry was then uploaded to the SimScale platform and incompressible flow simulation\u2014which is used when fluid velocity is much less than the Mach number\u2014was selected. The SST k-omega turbulence model was used, and the analysis was run as steady state. Water was assigned to the single CAD body. The simulation was run for 1000s (or iterations) using 32 computing cores.<\/p>\n