Patent Grant
7631663
1. Field of the Invention
The invention relates to a pilot valve, especially for servo valves.
2. Description of Related Art
In electro-hydraulic servo valves the hydraulic output (fluid flow or pressure) is proportional to the electrical input signal. In the case of larger pressure fluid volume flows, usually, two-stage servo valves are employed in which a main stage is adjusted via a hydraulic pilot stage. Such a two-stage servo valve is distributed by the applicant, for instance, under the product name 4WS.2DM. The pilot stage substantially consists of a control motor by means of which the position of a bounce plate is variable between two control nozzles. By approximation of the bounce plate to one of the control nozzles a control oil flow is reduced by the latter, while the control oil flow is increased by the other control nozzle. In the flow path of the control oil to each nozzle a respective diaphragm is arranged so that also the pressure drop is appropriately reduced or increased via the respective diaphragms by varying the control oil volume flow.
The pressure adjusting downstream of the diaphragms is tapped off by means of a control duct and guided to control surfaces pressurizing a main slide of a main stage on the front side so that the main slide is displaced into a control position in response to the pressure difference occurring. The bounce plate and the control nozzles thus act as hydraulic booster by means of which the displacement of position caused by the control of the actuating motor is converted to a pressure difference.
In some applications it is necessary, for instance when taking the system into operation in accident (emergency stop) or in troubleshooting, to put the servo pilot valve manually into a predetermined position so that the main slide is appropriately adjusted and the system is switched to be pressureless or the like.
Servo adjusting systems are offered by Moog under the designation D062-900 in which the mechanical emergency actuation is effected by a lever disposed at a cap of the servo valve enclosing the actuating motor and acting directly upon the actuating motor.
It is a drawback of said solution that in the case of violent operation of the lever the actuating motor can be damaged and that the lever mimic is also relatively sensitive to pollution and vibrations of the system.
Compared to this, the object underlying the invention is to provide a pilot valve, especially for a servo valve, which has an elegant design while permitting a reliable manual operation.
The preferred embodiments are directed to a pilot valve including an actuating motor and a hydraulic preamplifier that includes a bounce plate disposed between two control nozzles and is movable by the actuating motor. A control oil volume flow guided via a respective nozzle duct and an inlet diaphragm to the control nozzles is variable by varying the distance of the bounce plate from the control nozzle and wherein the two nozzle ducts branch off a pressure terminal (P′) guiding a supply pressure of a main stage and downstream of the inlet diaphragms a respective control duct branching off the nozzle ducts is connected to a respective control terminal A′, B′ to which the control chambers of a main stage can be connected. The pilot valve also includes a manual actuation by which a control pressure difference can be applied to the control terminals A′, B′ independently of the control of the actuating motor, characterized by a manually actuated blocking mechanism by means of which one of the nozzle ducts can be closed.
In accordance with the invention, the pilot valve is designed to have a manually operable blocking mechanism by which at least one of those nozzle ducts can be closed by control through which control oil is guided to control nozzles between which a bounce plate or the like of the pilot valve is disposed. By operating said blocking mechanism the control oil volume flow to a control nozzle is blocked and thus a pressure drop is generated by which the directional control valve is brought into its desired position to be adopted in the case of “emergency stop” or for maintenance purposes.
Such an actuating means integrated in a hydraulic preamplifier of the pilot valve requires no direct access to the servo motor so that said sensitive component is protected against damage. Moreover, such a blocking mechanism can be integrated in the servo valve with a minimum expenditure on apparatuses so that the latter can have a very compact design without any protruding components such as, for instance, the levers in prior art.
In an especially preferred embodiment the blocking mechanism comprises a double-acting piston upon actuation of which a nozzle duct leading to a control nozzle can be closed, while the nozzle duct leading to the other control nozzle remains open. I.e. depending on the actuating direction the control oil volume flow to the one control nozzle or to the other control nozzle can be interrupted so as to adjust the main stage either in the one direction or in the other direction.
It is particularly preferred when the piston is a rotary piston which is rotatably disposed in a housing of the pilot valve.
The piston preferably includes at its outer circumference two recesses which in a home position of the piston release a nozzle duct flow cross-section and which in a locking position of the rotary piston close the cross-section of a nozzle duct by a control edge delimited by the recess, while the flow cross-section of the other nozzle duct remains substantially unchanged. When rotating the piston in the opposite direction, the other nozzle duct is correspondingly closed and the first-mentioned nozzle duct remains in its open position.
The servo valve has an especially compact design when the piston and the piston bore receiving the same form part of the control oil flow path so that complex additional duct bores can be dispensed with.
The piston is preferably biased by means of one or more reset springs into its home position in which both control oil cross-sections are opened. In an especially preferred embodiment a spring-biased reset bolt immerses in a radial recess of the rotary piston so that the latter can be rotated against the force of the reset spring and upon release is returned into its home position again.
The pilot valve according to the invention preferably comprises an electric return of the bounce plate which arranges for the bounce plate to be returned into a central position between the control nozzles upon reaching the predetermined control position.
The housing of the pilot valve can have an especially compact design when the piston and the nozzle member forming the control nozzles are arranged to be axially in parallel to each other.
Other advantageous further developments of the invention are the subject matter of further subclaims.
Hereinafter a preferred embodiment of the invention is illustrated in detail by way of schematic drawings, in which
The pilot stage includes an actuating motor 6 by which a bounce plate 8 of a hydraulic preamplifier is movable. The bounce plate 8 is arranged between two control nozzles 10, 12 which are connected by means of a respective nozzle duct 14 and 16 to a pressure terminal P′ of the pilot stage 2. Said pressure terminal P′ is connected to a pressure line 18 which is supplied with pressure fluid via a pump 20. In each of the two nozzle ducts 14, 16 a respective inlet diaphragm 22, 24 is provided to which a blocking mechanism 26 is allocated. The latter is designed such that in its shown home position it is arranged in a through position in which the control oil branched off the pressure line 18 can flow through the nozzle ducts 14, 16. By manual actuation of the blocking mechanism 26 either the nozzle duct 14 or the nozzle duct 16 can be blocked, the respective other nozzle duct 16 or 14 remains opened. That is to say, depending on the actuating direction one of the nozzle ducts 14, 16 is blocked, the control oil can flow through the other one.
A respective control line 28 or 30 leading to the terminals A′ and B′ of the pilot stage 2 and from there to the control chambers of a valve slide 32 of the main stage 4 branches off the two nozzle ducts 14, 16. Thus, the valve slide 32 is displaced into a control position in response to the control pressure difference in the two control lines 28, 30.
In the home position of the blocking mechanism 26 the control oil flows from the pressure terminal P′ of the pilot stage 2 via the two nozzle ducts 14, 16 and the opened blocking mechanism 26 to the two control nozzles 10, 12 and from there against the bounce plate 8 and back into the tank T. As long as the bounce plate 8 is in its central position, the control oil volume flow is equal by means of the two control nozzles 10, 12 and, correspondingly, the pressure drop above the two inlet diaphragms 22, 24 is equal so that the same control pressure is prevailing at the control chambers of the valve slide 32 of the main stage 4—the valve slide 32 remains in its home position.
For adjusting the control position, the actuating motor 6 is controlled by a not represented control so that the bounce plate 8 is swiveled and approaches one of the control nozzles 10, 12. In this way, the control oil volume flow is reduced via the respective nozzle—for instance the control nozzle 10—so that the pressure difference above the allocated control diaphragm 22 is reduced. At the same time, the control oil volume flow increases via the other control nozzle 12 so that the pressure drop above the allocated inlet nozzle 24 is increased—the control pressure difference tapped off by means of the control ducts 28, 30 varies so that the valve slide 32 is displaced into an appropriate control position. By an electric feedback the axial displacement of the valve slide 32 resulting therefrom is detected and, upon reaching the predetermined desired value, the bounce plate is returned to its central position by an appropriate control of the actuating motor 6 so that the valve slide 32 remains in the desired control position.
The manually operable blocking mechanism 26 permits to operate the blocking mechanism 26 in the case of emergency or for maintenance purposes such that one of the nozzle ducts 14, 16 is blocked so that a control pressure difference is generated which displaces the valve slide 32 into a predetermined end position. The bounce plate 8 does not remain in its central position, because it is approached on one side only and, correspondingly, swivels in the direction of the blocked control nozzle 12 (when the actuating motor 6 is not operated). Accordingly, the control oil volume flow increases via the other control nozzle 10 and thus also the pressure drop above the allocated inlet diaphragm 22 is increased so that the pressure difference acting upon the valve slide 32 is somewhat lowered—however, the valve slide is nevertheless displaced into the predetermined end position provided for maintenance or for emergency shut-down.
The
Said control nozzles 10, 12 are connected by control passages hereinafter described in detail to the pressure terminal P′ which is formed at the large surface of the housing 34 distant from the actuating motor 6. The closed end portion of the bounce plate bore 42 is connected by means of a tank duct 56 indicated in the cut side view according to
In accordance with
Each of the two flattened portions 86, 88 of the rotary piston 74 forms a control edge 110, 112, wherein the control edge 110 of the flattened portion 86 closes the connecting chamber 102 by a rotation of the rotary piston 74 in the arrow direction R, while the control edge 112 of the flattened portion 88 closes the connecting chamber 104 by rotation in the opposite direction. Said rotation is performed against the resetting moment which is transmitted from the spring-biased reset bolt 96 to the rotary piston 74. The spring deflection of the reset bolt 96 and the force of the spring 98 are chosen such that the rotary piston 74 can be rotated only by a predetermined angle in the direction of rotation R or in the opposite direction. Said angle of rotation is selected such that it is safely prevented that both connecting chambers 102, 104 are blocked. The reset bolt 96 also serves as an axial protection for the rotary piston 74.
In the area of the annular groove 80 a radial groove 94 is formed which extends from the outer circumference of rotary piston 74 to the axis so that the radial groove 94 is delimited by a plane base surface the width of which corresponds to the diameter of the piston land stepped back by the annular groove 80. The side walls are semi-circular and the height corresponds to the radius of said piston land. Of course, also other dimensions can be chosen.
As one can take especially from
In accordance with
During normal operation, i.e. when the rotary piston 74 is not rotated out of its home position shown in
The control position then is adjusted in accordance with the remarks on
In the case of an emergency stop, for maintenance purposes or when starting up the system, the rotary piston 74 is rotated, for instance, in the arrow direction R (
The use of the pilot stage 2 according to the invention is not restricted to servo valves, said pilot stage basically could also be used in other applications, for instance in pilot-operated valves or the like. On principle, the solution according to the invention including the blocking mechanism for blocking a control duct could also be mounted in an intermediate plate between a pilot stage and a main stage so that the pertinent valve is manually operable. In this way, an emergency actuation at the magnets of the pilot valve could be dispensed with under certain circumstances. The applicant reserves itself the right to direct a separate independent claim (without bounce plate etc.) to blocking a control duct by a blocking mechanism of a pilot stage. Instead of the electric return also a mechanical or barometric return of the bounce plate 8 may be provided.
There is disclosed a pilot valve, especially for a servo valve, comprising an actuating motor and a hydraulic preamplifier via which a control pressure difference can be created that acts upon a main slide of a main stage. According to the invention, a blocking mechanism is embodied in the flow path of the control oil. A control duct that is connected, either directly or via a branch, to a control chamber of the main stage can be blocked by manually actuating said blocking mechanism, while the other control duct remains open. The other control duct can be blocked by actuating the blocking mechanism in the opposite direction while the first control duct remains open. A control pressure difference by means of which the main slide can be displaced into a predetermined position can be created manually by actuating said blocking mechanism.
Although the best mode contemplated by the inventors of carrying out the present invention is disclosed above, practice of the present invention is not limited thereto. It will be manifest that various additions, modifications and rearrangements of the features of the present invention may be made without deviating from the spirit and scope of the underlying inventive concept.
| Number | Date | Country | Kind |
|---|---|---|---|
| 10 2004 038 380 | Aug 2004 | DE | national |
| Filing Document | Filing Date | Country | Kind | 371c Date |
|---|---|---|---|---|
| PCT/EP2005/008368 | 8/2/2005 | WO | 00 | 2/6/2007 |
| Publishing Document | Publishing Date | Country | Kind |
|---|---|---|---|
| WO2006/015771 | 2/16/2006 | WO | A |
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| 3029830 | Klover et al. | Apr 1962 | A |
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| 3554211 | Bernstein | Jan 1971 | A |
| 3712339 | Bartholomaus et al. | Jan 1973 | A |
| 3759485 | Mills | Sep 1973 | A |
| 3899002 | Hayner | Aug 1975 | A |
| 4137825 | Leonard | Feb 1979 | A |
| Number | Date | Country |
|---|---|---|
| 2532668 | Feb 1977 | DE |
| 3627425 | Feb 1988 | DE |
| 40 32 811 | Apr 1992 | DE |
| 102004038380.4 | Dec 2004 | DE |
| Number | Date | Country | |
|---|---|---|---|
| 20070215222 A1 | Sep 2007 | US |
