PARAMETRIC STUDY ON GATE VALVE

INTRODUCTION

A gate valve, also called sluice valve, often installed in a pipe fitting, opens by lifting a barrier called gate out of the path of the fluid. Gate valves require very little space along the pipe axis and hardly restrict the flow of fluid when the gate is fully opened. The gate faces can be parallel but are most commonly wedge-shaped.

Gate valves are used to shut off the flow of liquids rather than for flow regulation. When fully open, the typical gate valve has no obstruction in the flow path, resulting in very low flow resistance.

OBJECTIVE

To perform a parametric study on the gate valve simulation by setting the opening from 10 % to 80%.

• Obtaining the mass flow rates at the outlet for each design point.
• Calculating the flow coefficient and flow factor for each opening.
• Discussing the results of the mass flow rate and flow coefficient.

OUTLINE

Since the is only one [parameter that varies, valve opening. The objective has been achieved by doing parametric study in ANSYS fluent. The input parameter has been ser at valve opening, output opening is the flow coefficient and mass flow rate. Various other variables are recorded for calculation.

The gate valve has been opened from 10% or 10mm to 80% or 80mm.

COMPUTATIONAL MODEL

The computational model has been developed in Ansys Workbench using Fluent Module. The geometry has been used from the given source.

GEOMETRY

The used geometry has been adapted from the source provided. Later modifications were done for development of computational domain. Ansys SpaceClaim has been used to modify the geometry for further development.

The imported geometry.

The face has been pulled to extend the volume domain.

The gate valve disk has been lifted by 10% or 10mm. The value has been set as parameter. Varying the parameter, the study has been done by increasing it to 80% or 80mm.

Volume Extracting using SpaceClaim volume-extract function.

The passage for fluid is the variable section, as the gate valve opens, the passage increases.

Above is the volume that has been extracted from the given geometry.

MESHING

The defined volumetric domain is then imported to Ansys meshing module for creating the computational mesh.

The faces of geometry have been appropriately named to apply boundary condition in the fluent module. The named selection has been shown below.

The element size of the domain is of 0.01m using tetrahedral of 4 faces.

The above picture shows the mesh in the fluid passage area.

The element quality has been presented below.

SOLVER SETTINGS

The simulation is run in steady state, with gravitation enabled to be along negative of z axis.

Standard initialization has been used in the present simulation.

Viscous Model

Since this is a pipe flow simulation, if our goal was to employ accurate solution of near boundary values, we would have gone through modelling the boundary more precisely, here our objective is to measure the bulk flow parameter so we are going to be using K – epsilon model with scalable wall function.

Material Model

Water is the material of choice for the present simulation. Water material is copied from the fluent database and applied to the volume cell zone.

Boundary Conditions

Inlet

Inlet has been defined as pressure inlet boundary with gauge pressure of 10Pa.

Outlet

Outlet is pressure-outlet type of boundary with a value of 0 Pa gauge pressure.

Variables Recording

Inlet-pressure (Pa)

Outlet-pressure (Pa)

Pressure-difference (psi)

Mass-flow-rate (Kg/s)

Flow – coefficient

Flow coefficient is calculated using the expression:

$C_v=Q\cdot \sqrt{\frac{S\mathrm{G/}}{\Delta P}}$

Where, Q is Volumetric flow rate in Gallons per minute.

$\Delta P$is the pressure difference in psi.

Mass flow rate has been converted to Gallon par minute using multiplication factor (15850.3/998.2) on mass flow rate(Kg/s)

SG is the specific gravity of fluid flowing, in this case its water, so its value is 1.

The mass Flow rate and Flow coefficient has been put as output parameter.

Flow Factor is calculated using,

$K_v=0.862\cdot C_v$

Where,

$K_v$ is the flow factor

$C_v$ is the flow coefficient

Result and Discussion

Residual for 10mm gate opening

The Parametric Values Gatherd from the simulation are:

The computed values with flow factor are:

Mass Flow Rate vs Valve Opening

Flow Coefficient Vs Valve Opening

Flow Factor Vs Valve Opening

As can be seen from the above plot, The lower is the valve, or lesser space is there for fluid flow, low is the mass flow rate.

Aslo, lower is the valve opening higher is the pressure difference. 

With increase in the valve opening, the mass flow rate also flow coefficient as well as flow factor also increases.