Flow Divider
(To be removed) Hydraulic two-path flow divider
The Hydraulics (Isothermal) library will be removed in a future release. Use the Isothermal Liquid library instead. (since R2020a)
For more information on updating your models, see Upgrading Hydraulic Models to Use Isothermal Liquid Blocks.
Library
Flow Control Valves
Description
The Flow Divider block simulates a hydraulic two-path flow divider, which consists of a spring-centered spool installed in a case, as shown in the figure.
The flow from the source enters the valve through port P and is split into two parts flowing through the P–A and P–B paths. Each path contains a fixed orifice and a variable orifice. The fixed orifices must be precisely matched to divide flow in equal parts, or arranged in a certain proportion if unequal division is required.
The purpose of variable orifices is to maintain a constant pressure drop across the fixed orifices, regardless of pressure fluctuations at valve outlets. The load increase on any outlet causes the pressure drop across the spool (and across fixed orifices) to change, and thus shift the spool. As a result, the passage areas of variable orifices change until the pressure drop values across the fixed orifices even out.
The model of the flow divider uses the Double-Acting Servo Cylinder, Fixed Orifice, and Orifice with Variable Area Round Holes blocks. The following figure shows the schematic diagram of the model. The Double-Acting Servo Cylinder detects the pressure drop and shifts the variable orifice control member accordingly.
Note
You cannot use this block as a flow combiner. Use the Flow Divider-Combiner block instead.
Assumptions and Limitations
Friction between moving parts is not taken into account.
Inertia effects are not taken into account.
Fluid compressibility is not taken into account.
Leakage flows are assumed to be negligible.
The hard stops in the Double-Acting Servo Cylinder are assumed to be fully inelastic.
Parameters
Fixed Orifices Tab
- Fixed orifice A area
The cross-sectional passage area of the fixed orifice in the P–A path. The default value is
1e-4
m^2.- Fixed orifice B area
The cross-sectional passage area of the fixed orifice in the P–B path. The default value is
1e-4
m^2.- Fixed orifice A flow discharge coefficient
Semi-empirical parameter defining the capacity of the fixed orifice in the P–A path. The value depends on the geometrical properties of the orifice, and usually is provided in textbooks or manufacturer data sheets. The default value is
0.7
.- Fixed orifice B flow discharge coefficient
Semi-empirical parameter defining the capacity of the fixed orifice in the P–B path. The value depends on the geometrical properties of the orifice, and usually is provided in textbooks or manufacturer data sheets. The default value is
0.7
.- Fixed orifice laminar transition specification
Select how the block transitions between the laminar and turbulent regimes:
Pressure ratio
— The transition from laminar to turbulent regime is smooth and depends on the value of the Laminar flow pressure ratio parameter. This method provides better simulation robustness.Reynolds number
— The transition from laminar to turbulent regime is assumed to take place when the Reynolds number reaches the value specified by the Critical Reynolds number parameter.
- Fixed orifice A laminar flow pressure ratio
Pressure ratio at which the flow transitions between laminar and turbulent regimes for the fixed orifice in the P–A path. The default value is
0.999
. This parameter is visible only if the Fixed orifice laminar transition specification parameter is set toPressure ratio
.- Fixed orifice B laminar flow pressure ratio
Pressure ratio at which the flow transitions between laminar and turbulent regimes for the fixed orifice in the P–B path. The default value is
0.999
. This parameter is visible only if the Fixed orifice laminar transition specification parameter is set toPressure ratio
.- Fixed orifice A critical Reynolds number
The maximum Reynolds number for laminar flow for the fixed orifice in the P–A path. The transition from laminar to turbulent regime is assumed to take place when the Reynolds number reaches this value. The default value is
10
. This parameter is visible only if the Fixed orifice laminar transition specification parameter is set toReynolds number
.- Fixed orifice B critical Reynolds number
The maximum Reynolds number for laminar flow for the fixed orifice in the P–B path. The transition from laminar to turbulent regime is assumed to take place when the Reynolds number reaches this value. The default value is
10
. This parameter is visible only if the Fixed orifice laminar transition specification parameter is set toReynolds number
.
Variable Orifices Tab
- Diameter of round holes
Diameter of the round holes in the two identical Variable Orifice with Round Holes blocks. The default value is
0.005
m.- Number of round holes
Number of holes in each of the Variable Orifice with Round Holes blocks. The default value is
4
.- Variable orifices flow discharge coefficient
Semi-empirical parameter defining the orifice capacity of the Variable Orifice with Round Holes blocks. The value depends on the geometrical properties of the orifice, and usually is provided in textbooks or manufacturer data sheets. The default value is
0.65
.- Variable orifice A initial opening
Initial opening of the variable orifice in the P–A path. The parameter can be positive (underlapped orifice), negative (overlapped orifice), or 0 for zero-lap configuration. The value of initial opening does not depend on the orifice orientation. The default value is
0.0025
m.- Variable orifice B initial opening
Initial opening of the variable orifice in the P–B path. The parameter can be positive (underlapped orifice), negative (overlapped orifice), or 0 for zero-lap configuration. The value of initial opening does not depend on the orifice orientation. The default value is
0.0025
m.- Variable orifice laminar transition specification
Select how the block transitions between the laminar and turbulent regimes:
Pressure ratio
— The transition from laminar to turbulent regime is smooth and depends on the value of the Laminar flow pressure ratio parameter. This method provides better simulation robustness.Reynolds number
— The transition from laminar to turbulent regime is assumed to take place when the Reynolds number reaches the value specified by the Critical Reynolds number parameter.
- Variable orifice A laminar flow pressure ratio
Pressure ratio at which the flow transitions between laminar and turbulent regimes for the fixed orifice in the P–A path. The default value is
0.999
. This parameter is visible only if the Variable orifice laminar transition specification parameter is set toPressure ratio
.- Variable orifice B laminar flow pressure ratio
Pressure ratio at which the flow transitions between laminar and turbulent regimes for the fixed orifice in the P–B path. The default value is
0.999
. This parameter is visible only if the Variable orifice laminar transition specification parameter is set toPressure ratio
.- Variable orifice A critical Reynolds number
The maximum Reynolds number for laminar flow through the variable orifice in the P–A path. The transition from laminar to turbulent regime is assumed to take place when the Reynolds number reaches this value. The default value is
10
. This parameter is visible only if the Variable orifice laminar transition specification parameter is set toReynolds number
.- Variable orifice B critical Reynolds number
The maximum Reynolds number for laminar flow through the variable orifice in the P–B path. The transition from laminar to turbulent regime is assumed to take place when the Reynolds number reaches this value. The default value is
10
. This parameter is visible only if the Variable orifice laminar transition specification parameter is set toReynolds number
.- Variable orifice leakage area
The total area of possible leaks in each variable orifice when it is completely closed. The main purpose of the parameter is to maintain numerical integrity of the circuit by preventing a portion of the system from becoming isolated after the orifice is completely closed. The parameter value must be greater than 0. The default value is
1e-9
m^2.
Servo Cylinder Tab
- Servo cylinder piston area
The face area of the piston in the servo cylinder. The default value is
1.6e-4
m^2.- Servo cylinder piston stroke
The full piston stroke in the servo cylinder, from one hard stop to another. The piston is located initially in the middle of the stroke and can travel half a stroke in the positive and negative direction. The default value is
0.005
m.- Servo cylinder spring rate
The spring rate of the centering springs in the servo cylinder. The default value is
1000
N/m.- Servo cylinder damping coefficient
The damping coefficient in the contact between the piston and the case of the servo cylinder. The default value is
150
N/(m/s).- Servo cylinder stop penetration coefficient
The penetration property of the piston hard stop in the servo cylinder. The hard stop is represented as absolutely inelastic, and its property is characterized by the penetration coefficient. The default value of the coefficient is
1e12
N/m/(m/s).
Global Parameters
Parameters determined by the type of working fluid:
Fluid density
Fluid kinematic viscosity
Use the Hydraulic Fluid block or the Custom Hydraulic Fluid block to specify the fluid properties.
Ports
The block has the following ports:
P
Hydraulic conserving port associated with the inlet port P.
A
Hydraulic conserving port associated with the outlet port A.
B
Hydraulic conserving port associated with the outlet port B.