Gas-Charged Accumulator

Gas-Charged Accumulator (IL)

Spring-Loaded Accumulator

Spring-Loaded Accumulator (IL)

The isothermal liquid block does not model hard-stop damping.

Centrifugal Force in Rotating Cylinder

Rotating Cylinder Force (IL)

The Fluid density parameter is replaced with port X, which senses the network density.

Cylinder Cushion

Cylinder Cushion (IL)

The Cylinder Cushion (IL) block is parameterized by plunger diameter, area, and length. The Hydraulics (Isothermal) block is parameterized by tabulated area and displacement.

The conversion tool calculates the plunger length, or the orifice control member travel, from the Hydraulics (Isothermal) block as opening(end) - opening(1).

Cylinder Friction

Cylinder Friction (IL)

The Cylinder Friction (IL) block does not assign beginning values to variables.

Single-Acting Rotary Actuator

Single-Acting Rotary (IL)

The conversion tool converts the Single-Acting Rotary Actuator block to a subsystem. If the Hydraulics (Isothermal) block models leakage, or the Leak coefficient is nonzero, port A of the Single-Acting Rotary (IL) connects to port A of a Laminar Leakage (IL) block, which connects to a Reservoir (IL) block at atmospheric pressure.

Double-Acting Rotary Actuator

Double-Acting Rotary Actuator (IL)

The conversion tool converts the Double-Acting Rotary Actuator to a subsystem. If the Hydraulics (Isothermal) block models leakage, or the Leak coefficient is nonzero, ports A and B of the Double-Acting Rotary Actuator (IL) block connect in parallel to ports A and B, respectively, of a Laminar Leakage (IL) block.

Single-Acting Hydraulic Cylinder

Single-Acting Actuator (IL)

Single-Acting Hydraulic Cylinder (Simple)

Single-Acting Actuator (IL)

The conversion tool sets the Hard stop model parameter to Stiffness and damping applied smoothly through transition region, damped rebound, with default hard stop parameters.

Double-Acting Hydraulic Cylinder

Double-Acting Actuator (IL)

Double-Acting Hydraulic Cylinder (Simple)

Double-Acting Actuator (IL)

The conversion tool sets the Hard stop model parameter to Stiffness and damping applied smoothly through transition region, damped rebound, with default hard stop parameters.

Hydraulic Fluid

Isothermal Liquid Predefined Properties (IL)

Reservoir

Reservoir (IL)

Elbow

Elbow (IL)

Gradual Area Change

Area Change (IL)

The conversion tool converts the Gradual Area Change block to a subsystem to maintain the original port orientation.

Local Resistance

Local Resistance (IL)

Pipe Bend

Pipe Bend (IL)

The Initial liquid pressure parameter in the Pipe Bend block is in gauge. In the Pipe Bend (IL) block, this parameter is in absolute pressure.

The conversion tool converts the Critical Reynolds number parameter into two internally fixed threshold Reynolds numbers in the Pipe Bend (IL), where 2000 indicates a fully laminar flow and 4000 indicates a fully turbulent flow.

Sudden Area Change

Area Change (IL)

Hydraulic Pipe LP

Resistive Pipe LP

Resistive Pipe LP with Variable Elevation

Segmented Pipe LP

Pipe (IL)

Hydraulic Pipe LP with Variable Elevation

Pipe (IL)

Port EL is exposed for elevation change as a physical signal input.

Partially Filled Vertical Pipe LP

Partially Filled Pipe (IL)

The Partially Filled Pipe (IL) block receives a liquid level instead of a liquid volume at its physical signal port. The conversion tool add a PS Constant block to divide the original fluid volume by a constant tank cross-section within a subsystem. Modify the assumed tank cross-section in the added PS Constant block.

Constant-Head Tank

The conversion tool converts the Constant-Head Tank block to a subsystem that includes Reservoir (IL), Orifice (IL), PS Integrator, and Flow Rate Sensor blocks.

Tank

The conversion tool converts the Tank block to a subsystem that includes a Tank (IL) block and a Flow Resistance (IL) block for each inlet port.

Annular Orifice

Annular Leakage (IL)

Fixed Orifice

Fixed Orifice With Fluid Inertia

Fixed Orifice Empirical

Variable Orifice

Orifice (IL)

Journal Bearing Pressure-Fed

The conversion tool converts the Journal Bearing Pressure-Fed block to a subsystem that includes two Annular Leakage (IL) blocks.

Orifice With Variable Area Round Holes

Orifice With Variable Area Slot

Spool Orifice (IL)

Variable Orifice Between Round Holes

Variable Overlapping Orifice (IL)

Rotating Pipe

Rotating Channel (IL)

Hydraulic Pipeline

Pipe (IL)

Segmented Pipeline

Pipe (IL)

Angle Sensor

The conversion tool converts the Angle Sensor block to a subsystem that contains an Ideal Rotational Motion Sensor block.

Centrifugal Pump

Centrifugal Pump (IL)

Fixed-Displacement Motor

Fixed-Displacement Motor (IL)

The Fixed-Displacement Motor (IL) block uses the network fluid properties. You may need to modify the Volumetric efficiency at nominal conditions parameter to match the Hydraulics (Isothermal) block functionality.

Fixed-Displacement Pump

Fixed-Displacement Pump (IL)

The Fixed-Displacement Pump (IL) block uses the network fluid properties. You may need to modify the Volumetric efficiency at nominal conditions parameter to match the Hydraulics (Isothermal) block functionality.

Jet Pump

Jet Pump (IL)

Porting Plate Variable Orifice

Valve Plate Orifice (IL)

Swash Plate

Swash Plate

Variable-Displacement Motor

Variable Displacement Motor (IL)

The Variable Displacement Motor (IL) block uses the network fluid properties. You may need to modify the Volumetric efficiency at nominal conditions parameter to match the Hydraulics (Isothermal) block functionality.

Variable-Displacement Pressure-Compensated Pump

Pressure-Compensated Pump (IL)

The conversion tool converts the Variable-Displacement Pressure-Compensated Pump block to a subsystem.

The Pressure-Compensated Pump (IL) block uses the network fluid properties. You may need to modify the Volumetric efficiency at nominal conditions parameter to match the Hydraulics (Isothermal) block functionality.

Variable-Displacement Pump

Variable Displacement Pump (IL)

The Variable Displacement Pump (IL) block uses the network fluid properties. You may need to modify the Volumetric efficiency at nominal conditions parameter to match the Hydraulics (Isothermal) block functionality.

2-Way Directional Valve

2-Way Directional Valve (IL)

The 2-Way Directional Valve (IL) block behavior and parameterization are based on the spool position at the maximum orifice area and the maximum spool travel distance, while the 2-Way Directional Valve uses initial spool position. Changing the valve parameterization after conversion can lead to inconsistencies. See Upgrade Considerations When Converting Hydraulic to Isothermal Liquid Models.

3-Way Directional Valve

3-Way Directional Valve (IL)

The 3-Way Directional Valve (IL) block behavior and parameterization are based on the spool position at the maximum orifice area and the maximum spool travel distance, while the 3-Way Directional Valve uses initial spool position. Changing the valve parameterization after conversion can lead to inconsistencies. See Upgrade Considerations When Converting Hydraulic to Isothermal Liquid Models.

4-Way Ideal Valve

4-Way 3-Position Directional Valve (IL)

The 4-Way 3-Position Directional Valve (IL) block behavior and parameterization are based on the spool position at the maximum orifice area and the maximum spool travel distance, while the 4-Way Ideal Valve uses initial spool position. Changing the valve parameterization after conversion can lead to inconsistencies. See Upgrade Considerations When Converting Hydraulic to Isothermal Liquid Models.

4-Way Directional Valve

4-Way 3-Position Directional Valve (IL)

The 4-Way 3-Position Directional Valve (IL) block behavior and parameterization are based on the spool position at the maximum orifice area and the maximum spool travel distance, while the 4-Way Directional Valve uses initial spool position. Changing the valve parameterization after conversion can lead to inconsistencies. See Upgrade Considerations When Converting Hydraulic to Isothermal Liquid Models.

4-Way Directional Valves A-K

4-Way 3-Position Directional Valve (IL)

The 4-Way 3-Position Directional Valve (IL) block behavior and parameterization are based on the spool position at the maximum orifice area and the maximum spool travel distance, while the 4-Way Directional Valves A-K use initial spool position. Changing the valve parameterization after conversion can lead to inconsistencies. See Upgrade Considerations When Converting Hydraulic to Isothermal Liquid Models.

Cartridge Valve Insert

Cartridge Valve Insert With Conical Seat

Cartridge Valve Insert (IL)

Check Valve

Check Valve (IL)

When you set Opening dynamics to Include valve opening dynamics for the Check Valve block, the setting affects the valve area. However, when Opening dynamics is On for the Check Valve (IL) block, the setting affects only the valve pressure.

Hydraulically Operated Remote control Valve

Pressure Compensator Valve (IL)

Pilot-Operated Check Valve

Pilot-Operated Check Valve (IL)

Shuttle Valve (IL)

Ball Valve

Poppet Valve (IL)

Counterbalance Valve

Counterbalance Valve (IL)

Flow Divider

The conversion tool converts the block to a subsystem.

Flow Divider-Combiner

The conversion tool converts the block to a subsystem.

Gate Valve

Variable Overlapping Orifice (IL)

Needle Valve

Needle Valve (IL)

Poppet Valve

Poppet Valve (IL)

Pressure-Compensated 3-Way Flow Control Valve

Pressure-Compensated 3-Way Flow Control Valve (IL)

Pressure-Compensated Flow Control Valve

Pressure-Compensated Flow Control Valve (IL)

Pressure Compensator

Pressure Compensator Valve (IL)

When you set Opening dynamics to Include valve opening dynamics for the Check Valve block, the setting affects the valve area. However, when Opening dynamics is On for the Check Valve (IL) block, the setting affects only the valve pressure.

Pressure Reducing Valve

Pressure-Reducing Valve (IL)

When you set Opening dynamics to Include valve opening dynamics for the Check Valve block, the setting affects the valve area. However, when Opening dynamics is On for the Check Valve (IL) block, the setting affects only the valve pressure.

Pressure Relief Valve

Pressure Relief Valve (IL)

When you set Opening dynamics to Include valve opening dynamics for the Check Valve block, the setting affects the valve area. However, when Opening dynamics is On for the Check Valve (IL) block, the setting affects only the valve pressure.

Pressure Reducing 3-way Valve

Pressure-Reducing 3-Way Valve (IL)

When you set Opening dynamics to Include valve opening dynamics for the Check Valve block, the setting affects the valve area. However, when Opening dynamics is On for the Check Valve (IL) block, the setting affects only the valve pressure.

2-Position Valve Actuator

3-Position Valve Actuator

Multiposition Valve Actuator

Double-Acting Servo Cylinder

Double-Acting Servo Valve Actuator (IL)

The conversion tool sets the Hard stop model parameter to Stiffness and damping applied smoothly through transition region, damped rebound, with default hard stop parameters.

Hydraulic 4-Port Cartridge Valve Actuator

Cartridge Valve Actuator (IL)

The conversion tool converts the block to a subsystem.

The Cartridge Valve Actuator (IL) block calculates area at port B as the sum of the area at ports X and Y minus the area at port A. The hydraulics block calculates the difference between the areas at port X and port A.

Hydraulic Cartridge Valve Actuator

Cartridge Valve Actuator (IL)

Hydraulic Single-Acting Valve Actuator

Hydraulic Double-Acting Valve Actuator

Pilot Valve Actuator (IL)

Proportional and Servo-Valve Actuator

The conversion tool converts the block into a subsystem that contains physical signal blocks.

Valve Actuator

Proportional Valve Actuator

Spool Orifice Hydraulic Force

Spool Orifice Flow Force (IL)

Valve Hydraulic Force

The conversion tool converts the Valve Hydraulic Force block to a subsystem.

Interface (TL-IL)

Interface (TL-IL)

The conversion tool sets the Interface (TL-IL) parameter Fluids domain interface to Thermal Liquid (TL) - Isothermal Liquid (IL).

Double-Acting Actuator (H-G)

Double-Acting Actuator (G-IL)

The conversion tool converts the Double-Acting Actuator (H-G) block to a subsystem.

Variable-Displacement Hydraulic Machine

Variable-Displacement Motor (IL)

The conversion tool converts the Variable-Displacement Hydraulic Machine block to a subsystem and sets the Variable-Displacement Motor (IL) Leakage and friction parameterization to Input signal - volumetric and mechanical losses.

Variable-Displacement Hydraulic Machine (External Efficiencies)

Variable-Displacement Motor (IL)

The conversion tool converts the Variable-Displacement Hydraulic Machine (External Efficiencies) block to a subsystem and sets the Variable-Displacement Motor (IL) Leakage and friction parameterization parameter to Input signal - volumetric and mechanical efficiencies.