EP0419946A1 - Valve motor - Google Patents

Abstract

This actuating drive (1) has a main piston (4) which can be operated by means of an oil pressure and a pilot control system in effective connection to the main piston (4) by means of a linkage (15). The pilot control system includes a control orifice (14) controlling the oil pressure at the main piston (4) and a pilot control piston arrangement (18) which can be operated hydraulically. The actuating drive (1) is to be designed in such a way that it has improved dynamic characteristics during operation. This is achieved by the fact that the pilot control piston arrangement (18) can be operated by means of an electrohydraulic valve which is triggered by an electronic control unit (31).

Description

TECHNICAL AREA

The invention is based on an actuator for a control valve with a main piston which can be operated with oil pressure and with a pilot control which is operatively connected to the main piston via a linkage and which has at least one control orifice regulating the oil pressure on the main piston and at least one hydraulically actuated pilot piston arrangement.

STATE OF THE ART

An actuator for the actuation of a control valve with which, for example, the steam supply to a turbine is regulated, has a main piston which is acted upon on the one hand by spring force and on the other hand by oil pressure. When the oil pressure drops, the spring force securely closes the control valve, which therefore definitely cuts off the steam supply. This ensures that the turbine cannot reach an uncontrollable operating state if the oil pressure for the control valve should fail. In this version, a control signal is generated as an oil pressure by a central electrohydraulic converter, which actuates several actuators at the same time. This requires comparatively long pulse pipelines for the oil that transmits the control signal, so that this inevitably generated line volume has a negative influence on the dynamic behavior of the actuator.

The main piston of the actuator is connected via a linkage to a control orifice which interacts with a pilot piston arrangement and the flow of the oil to the main piston regulates. If a special stroke characteristic of the actuator is required, this can only be achieved by a complex device integrated in the linkage, such as a link or cam with a corresponding mechanism. The stroke of the actuator is usually monitored during operation, which is only possible here using a comparatively complex measuring device. Another disadvantage is that the actuator function cannot be directly secured by a safety oil circuit.

PRESENTATION OF THE INVENTION

The invention seeks to remedy this. The invention, as characterized in the claims, solves the problem of creating an actuator for a control valve which has a higher dynamic range during operation.

The advantages achieved by the invention are essentially to be seen in the fact that any changes in the control characteristic can be implemented quickly and without changes to mechanical parts. Furthermore, impulse pipelines are no longer necessary, so that on the one hand the dynamics deteriorating line volumes in the hydraulic system are kept to a minimum and on the other hand the structure of this system is greatly simplified. The stroke of the actuator can easily be monitored separately, so that shorter working times can be achieved, particularly during a commissioning phase. The safety of the actuator is increased because this version can be operated via a safety oil circuit.

The further developments of the invention are the subject of the dependent claims.

The invention, its further development and the advantages which can be achieved therewith are explained in more detail below with reference to the drawing, which only represents one possible embodiment.

BRIEF DESCRIPTION OF THE DRAWING

The single figure shows a schematic representation of an actuator according to the invention.

WAYS OF CARRYING OUT THE INVENTION

The figure shows an actuator 1, which actuates a control valve 2, which can open and close a schematically illustrated superheated steam line 2a. The control valve 2 is connected to a main piston 4 via a rod 3. Below the main piston 4 there is a drive volume 5 with oil pressure. A spring 6, which counteracts the oil pressure, is provided above the main piston 4. A schematically indicated master cylinder 7 includes the spring 6, the master piston 4 and the drive volume 5. On the side of the spring 6, a further rod 8 is connected to the main piston 4. This rod 8 penetrates, just like the rod 3, the master cylinder 7. The construction of these pressure-tight penetrations will not be described here. The rod 8 is guided by a guide 9, it is articulated to a rocker 11 via an articulated intermediate piece 10. The rocker 11 is rotatably mounted in an indicated fixed bearing 12. The other end of the rocker 11 is articulated to a rod 13 which interacts with a control panel 14. The rod 13 is provided in the upper area with a part, not shown, which, like the intermediate piece 10 between the rod 8 and the rocker 11, implements the rotary movement of the rocker 1 in a linear movement of the rods 13 and 8 facilitated. The assembly consisting of the rod 8, the intermediate piece 10, the rocker 11, the bearing 12 and the rod 13 is referred to as the linkage 15. In this linkage 15, which is shown in a greatly simplified manner, non-linear links such as, for example, cam disks or link controls can also be provided.

The control orifice 14 has a schematically indicated closure piece 16, which is rigidly connected to a piston 17 of a pilot piston arrangement 18. The pilot piston arrangement 18 has an actuating volume 19 acted upon by oil pressure above the piston 17 and a spring 20 provided underneath the piston 17 and acting thereon. The position of the piston 17 is controlled by a displacement measuring device 21 rigidly connected to it. As indicated by a dashed line of action 30, path-proportional electrical signals output by the path measuring device 21 are fed into an electronic controller 31. The controller 31 is, as indicated by a dashed line of action 32, in operative connection with a proportional directional control valve 33. This operative connection comprises, on the one hand, the electromagnetic actuation of the proportional directional control valve 33, which is controlled by the electronic controller 31 according to certain predetermined criteria, and on the other hand, the path-proportional electrical signals fed back into the controller 31 of a distance measuring device 34, which monitors the position of the proportional directional control valve 33. A defined starting position of the proportional directional valve 33 is achieved with the aid of a spring, not shown. The proportional directional control valve 33 also has an additional stroke feedback, not shown, which, together with an electronic position control, also not shown, achieves a proportional control behavior of this proportional directional control valve 33, namely an oil flow rate is set proportional to an electrical signal acting on it.

Oil is fed in under pressure through a line 40, and the necessary oil pressure is generated by a pump (not shown). The flow rate of the oil is regulated by an orifice 41 arranged in the line 40. The aperture 41 can either have an opening with a constant cross section or an opening with a controllable cross section. The oil flows into the drive volume 5 and from there, as indicated schematically by the branching line 42, to the control orifice 14, through this further into a line 43 which leads to a drain device, not shown. From this drain device, the oil continues through the aforementioned pump back into line 40. From line 40, a line 44 branches off with an orifice 44 a, which leads to an inlet 45 of the proportional directional valve 33. An outlet 46 of the proportional directional control valve 33 is connected by a line 47 to the actuating volume 19 of the pilot piston arrangement 18. A line 48 branches off from this line 47 and opens into line 43. A line 50 leads from a further outlet 49 of the proportional directional control valve 33, which also opens into line 43.

The proportional directional control valve 33 is advantageously arranged in the immediate vicinity of the pilot piston arrangement 18 or flanged together to form a monolithic assembly, as a result of which the line 47 and thus the line volume to be filled with oil are small. The dynamics of the control system are greatly increased by the elimination of pulse lines. All lines that are pressurized with oil pressure are designed with the smallest possible longitudinal extension in order to reduce line volumes and thereby increase the dynamics of the actuator.

In line 48, a safety valve 60 designed as a plate valve is used, which has an actuation volume 61. The safety valve 60 is in the Re Gel closed, since the actuating volume 61 is so strongly acted upon by a line 62 from a safety oil circuit (not shown) with the pressure of the safety oil that a spring 63 acting in the opening direction of the safety valve cannot relax. The line 48 is also made as short as possible.

To explain the mode of operation of the actuator 1, the figure is considered in more detail. The proportional directional control valve 33 is switched in such a way that oil can flow from the actuating volume 19 of the pilot piston arrangement 18 through the lines 47 and 50 into the line 43 and through this into the drain device. The result of this is that the spring 20 can push the piston 17 and with it the closure piece 16 of the control orifice 14 upwards, as a result of which the flow cross-section of the control orifice 14 is enlarged. The orifice 41 limits the flow rate of the oil, but since more orifice can now flow out through the orifice 14, the oil pressure in the drive volume 5 drops and the spring 6 presses the main piston 4 down and the control valve 2 is moved in the closing direction. This process continues until the electronic controller 31 determines on the basis of the incoming path-proportional signals from the path measuring device 21 that the desired target position of the control valve 2 has been reached. Any non-linearities in the closing behavior of the control valve 2 are compensated in the controller 31. These non-linearities are entered into the controller 31 when this actuator 1 is started up, and any necessary fine adjustments can also be made via an entry into the controller 31. One and the same type of controller can therefore be used for a wide variety of control valves, since only corresponding programming is necessary to adapt the controller. In addition, any closing and opening characteristics of the control valve 2 can be set with the aid of the controller 31. In this way, complex mechanical modifications to the linkage 15 can be avoided those that would otherwise be necessary to change the drive characteristics of the actuator 1.

If the control valve 2 is now to be opened again, so that more steam can get into a turbine through the hot steam line 2a, the proportional directional control valve 33 is switched over by a command from the controller 31, specifically in such a way that the circuit diagram shown at the top of this valve applies. In this case, the inlet 45 is connected to the outlet 46, so that oil, the amount of which is controlled by the proportional directional control valve 33, can flow through the lines 44 and 47 into the actuating volume 19 of the pilot piston arrangement 18 and can increase the oil pressure there, since through the Line 48 does not drain any oil. The opening speed of the pilot piston arrangement 18 is limited by the aperture 44a. The pilot piston arrangement 18 closes or reduces the flow cross-section of the control orifice 14, so that, fed by the line 40, the oil pressure in the drive volume 5 rises, as a result of which the main piston 4 is moved upward and at the same time the control valve 2 is moved in the opening direction. As soon as the predetermined target value is reached, the controller 31 recognizes this and controls the proportional directional control valve 33, so that no additional oil gets into the actuating volume 19.

The function of the control valve 2 must be checked at regular intervals in order to be sure that it can also carry out its closing movement at any time in the event of a fault. In conventional actuators, an additional oil pressure line had to be led into the pilot piston arrangement 18 for this purpose, so that it could be actuated against the pressure prevailing in the actuating volume 19. In this case, the piston 17 was then moved upward, the control orifice 14 was opened, the pressure from the drive volume 5 was able to escape via the control orifice 14 and the control valve 2 carried out a closing movement which was independent of the rest of the control system. This additional oil pressure line had to be fitted with valves and securely sealed off from the rest of the control system in order to avoid unwanted, dangerous actuations of the pilot piston arrangement 18. This elaborate solution is no longer required, since this control can be initiated directly via the controller 31 by appropriate electrical control of the proportional directional valve 33.

The safety requirements for technical systems, especially thermal power plants, are constantly increasing. A comparatively high level of safety is achieved if a separate safety oil circuit allows all safety-relevant valves to be operated almost simultaneously. The safety valve 60 opens immediately when the pressure of the safety oil in the line 62 drops. The oil from the actuating volume 19 of the pilot piston arrangement 18 flows out very quickly through the line 48 and the actuator 1 closes the control valve 2 immediately. This closing takes place even in the event of a power failure, since the springs 63, 20 and 6 safely reach the switch-off position without additional Ensure energy. In this way, a safe final state of the actuator 1 is always achieved; unstable operating states cannot occur.

Claims (5)

1.Actuator (1) for a control valve (2) with a main piston (4) which can be operated with an oil pressure and with a pilot control which is operatively connected to the main piston (4) via a linkage (15) and which controls at least one oil pressure on the main piston ( 4) has a regulating orifice plate (14) and at least one hydraulically actuable pilot piston arrangement (18),
characterized,
- That the at least one pilot piston arrangement (18) is designed such that it can be actuated via at least one electro-hydraulic valve,
that a displacement measuring device (21, 34) emitting an electrical signal is provided on the at least one pilot piston arrangement (18) and on the at least one electrohydraulic valve,
- That these electrical signals are passed into an electronic controller (31) and compared there with a target value, and
- That the electronic controller (31) has a corrective action on the electrohydraulic valve in the event of setpoint deviations. 2. Actuator according to claim 1, characterized in
- That the at least one electro-hydraulic valve is designed as a proportional directional valve (33). 3. Actuator according to claim 1, characterized in
- That the proportional directional valve (33) is connected to the pilot piston arrangement (18) to form a monolithic unit. 4. Actuator according to claim 1, characterized in
- That non-linearities of the control valve (2) are compensated for by non-linear elements in the linkage (15) or by entering the valve characteristics in the electronic controller (31) or by a combination of both measures. 5. Actuator according to at least one of the preceding claims, characterized in that
- That in the event of faults by means of a safety valve (60) the control valve (2) is closed.

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