TEP4195 TURBOMACHINERY

5 VALVE ACTUATOR SYSTEMS

SIMPLIFIED ANALYSIS

1Linear Actuators

Linear actuators operate by producing a force as a result of a pressure difference across the area of the piston where the level of the pressures acting will be dependent on the method used to supply the flow to the actuator.

Figure 1 Linear equal area actuator.

Referring to Figure 1, for an equal area, or double-ended, actuator, the force on the piston is:

Therefore, so long as ( P1 - P2 ) has the same value, the force produced will be the same and will not be affected by the level of the pressure.

The actuator converts pressure into force and flow into velocity where:

The power transmitted by the fluid due to pressure and flow is converted into mechanical power due to force and velocity.

Equal area actuators are often used in closed loop control systems because of the force and velocity symmetry when working in either direction. Unequal area, or single-ended, actuators are also used in many applications but these have non-symmetry of force and velocity in relation to the direction of the valve opening. This inevitably leads to an increase in the complexity of the dynamic equations for such a valve operated system and the analytical methods used in this course relate to equal area actuators only. The steady state performance of unequal area actuators will, however, be considered.

2Ratings

2.1 Pressure

The maximum pressure is limited by the:

• Bursting strength of the cylinders (to include the effects of fatigue - around 1/4 to 1/5 of the maximum static burst pressure)

• Seals on the piston and the rod. These are also the main limitation to the maximum velocity. This is usually in the region of 5 to 10 m/s.

2.2Thrust

For a given piston size there will be a limit to the maximum permissible thrust which is dependent on the actuator stroke. This is because, during extension against an opposing load, the rod is acting as a strut.

In applications of unequal area actuators in which the load can change direction, the diameter of the rod will limit the available reverse thrust because of the reduced annulus area compared to that of the piston. The structural strength of the rod is considerably affected by the method employed to mount the actuator and on how the driven load is located (eg possible generation of side loads etc...)

In applications where limited movement is required hydraulic actuators have distinct advantages over other types which include:

• High thrust to weight ratio

• Ability to place the driving force where it is required

• Low wear of the moving components giving good life

• Reasonably high velocity

• Self braking capability with blocked ports

2.3. Valves for controlling actuators

2.3.1 Valve Characteristics

Valves are used to introduce a reduced area into the flow path that creates an increase in the fluid velocity and a consequent reduction in its pressure. The fluid velocity is then reduced downstream as the flow area is increased but the amount of pressure increase downstream of the restriction is dependent on the way in which the area reduction has been effected.

In the simple orifice the equation for the flow in relation to the overall pressure is given by:

Here:

a is the area of the orifice

CQ is the flow coefficient (usually around 0.7)

 is the density of the fluid

P is the orifice pressure drop.

For the actuator extending against the opposing force the way in which flow varies with pressure drop is shown in Figure 2.

Figure 2 Valve pressure drop

Here the pressure drops across the valve metering lands are:

and and assuming

2.3.2Valve metering area

The metering area of the valve opening can be fully annular as shown in the Figure 3 or, by using a slot, have reduced opening.

Figure 3 Valve area

Valve metering area =  dx

or for a slot = b x where b is the total width of the slot.

The most common type of control valve is a four- way valve with a metering section to each service outlet and for each service to tank. A standard test for the valve is with the A and B ports connected together. For the valve shown in Figure 4 with supply pressure PS the port pressures = PS /2 because the metering areas are the same as are the flows.

Figure 4 – Valve test

This is shown from the pressure/flow characteristics for each of the two restrictions in Figure 5. The pressure drop across each metering restriction is the same and = PS /2 at the intersection of the two flow characteristics for equal flow.

Figure 5 Pressure-flow characteristics

For a given supply pressure the relationship between flow and valve position will be as shown in Figure 6.

Figure 6 Flow variation with X (Valve gain)

Here:

P = PS /2

and:

Or:

where:

K = = a constant

CQ = valve metering flow coefficient (usually 0.65 to 0.7)

The flow gain is given by:

If PS is constant then the flow gain (KQ) is constant.

2.3.3 Valve lap

Figure 7 Valve lap

Valves can be arranged to have different lap conditions, which refer to the width along the valve centreline of the valve land in relation to that of the port as shown in Figure 7.

• Underlap is created when the valve land width is less than that of the port. This causes leakage in the central, or neutral position, and modifies the valve characteristics whilst the spool is operating in the underlap region.

• Zero lap refers to valves having a land width which is the same as that of the port, the valve being just closed in the neutral position.

• Overlap applies to valves in which the land width is greater than that of the port. This reduces leakage in the neutral position but creates a deadband.

These three conditions are shown in Figure 8.

Figure 8 Valve lap

2.3.4 Pressure gain measurement

Valves are tested with both service ports blocked to assess the amount of leakage in the neutral position and this is shown in Figure 9.

Figure 9 Pressure gain test

This is an important characteristic of the valve as it has a strong influence on the accuracy of the closed loop position control of a linear actuator. The force generated by the actuator is proportional to the pressure difference P1-P2. It can be seen, therefore, that if the pressure difference required by the load force varies then the valve position must change to maintain the static pressure conditions.

Valves having zero lap will always have some leakage in the null position because of manufacturing tolerances and wear of the metering edges during use. The pressure gain is measured with the A and B ports blocked so that the pressure in each port will vary with the valve position as shown in the next Figure.

Figure 10 Valve pressure gain

3Valve actuator system - simple control analysis

3.1Open loop system

Figure 11 Valve Actuator Circuit.

The valve actuator circuit in Figure 11 has an equal area, or double ended, actuator that is frequently used for closed loop control systems because of its symmetry with regard to the hydraulic force and velocity in both directions of movement. For a force, F, that is acting against the movement of the actuator rod as shown in Figure 11 the pressures are given by:

ExtendRetract

Figure 12 Valve Characteristics

The force F is positive for the direction shown in Figure 11. For the equal area actuator, the valve flows are the same on each side of the valve and the pressure differences, (Ps - P1) and P2 respectively, will therefore be the same.

For zero force, P1 = P2 = PS/2 that, as can be seen from Figure 12, is the pressure at which the flow characteristics intersect.

The flows through the valve is given by:

For the simple system assume that the moving components have negligible inertia so that, as a consequence, the actuator pressures will remain constant during transient changes caused by displacement of the valve.

Thus:

(1)

where:

And, for an actuator area A the actuator velocity, U is:

(2)

As , then (3)

The use of the Laplace Transform allows the equation to be written as:

(4)

Here the initial conditions for Y are zero. Thus and .

The actuator displacement is the integral of the valve opening and, as a consequence, it is referred to as an integrator. A step opening of the valve will, therefore, cause the actuator to move at a constant velocity, stopping when the valve is closed. This describes the open-loop performance of the system.

The time response of the actuator, or integrator, to a step change in valve position is shown in Figure 13.

Figure 13 Open loop time response.

3.2Closed loop system

Closed loop systems operate by comparing the output position with an input demand signal such systems being referred to as feed back control. In electrohydraulically operated valve actuator systems, the input signal is a voltage and the output position is fed back as a voltage signal from a position transducer. The comparison of the two signals produces a voltage difference referred to as the error signal that is amplified as a current signal and supplied to the electrohydraulic valve. In this analysis the relationship between the input and output is obtained from the following equations.

The valve position is given by:

(5)

KT = position transducer gain, V/m

KV = valve gain, m/A (or m/V)

KA = amplifier gain, A/V (or V/V)

Vi = input signal, V

Equations 2, 3 and 5 give:

Expressing by the Laplace operator ‘s’ allowing this equation to be treated algebraically.

Thus:

This gives:(6)

This is a first order differential equation where the time constant which has the units of time (s).

Note that electrohydraulic manufacturer’s literature will usually specify the valve performance in terms of flow for a given input current (or voltage) at a specific valve pressure drop, which will enable the gain product KVKQ to be obtained.

3.3System response

The time response from equation 6 can be obtained for a range of input signals by referring to a dictionary of standard inverse Laplace transforms. The response to a step input gives the solution:

(6)

This exponential variation of Y with time reaches 63.2% of the final value in one time constant as shown in Figure 14.

Figure 14 Step response

We have seen that the flow through a valve depends upon the valve opening and the pressure drop across the opening. Thus, under specified pressure conditions, the valve can be used as a flow source when connected to an actuator.

For the situation where the supply pressure is constant and there is zero force acting on the actuator, the valve pressure drop will be constant and consequently, the velocity of the actuator will be proportional to the valve opening.

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P Chapple April 2004. 5 Valve ActuatorSystems – Simplified Analysis