KR100506640B1 - Servo regulator of variable displacement swash plate type piston pump controlled in positive-negative direction - Google Patents

Abstract

The present invention can accurately maintain and maintain the swash plate at a desired angle, and the forward and reverse variable swash plate piston that can accurately maintain the swash plate angle in the desired position by feeding back the movement of the servo piston operating through the feedback lever Provides a servo control regulator for the pump. The servo control regulator includes a pilot pump for receiving power from an engine to generate and transmit operating hydraulic pressure; A direction control valve connected to the first branch line of the pressure oil delivery line for delivering the pressure oil generated by the pilot pump, and selectively controlling the supply direction of the pilot pressure according to the inclination direction of the swash plate; It communicates with the second branch line branched from the hydraulic oil delivery line, selectively receives the pilot pressure supplied from the directional control valve, moves in a predetermined direction, and the pilot spool surrounded by the pilot sleeve is movable. A regulator body for selectively discharging pilot pressure according to a moving direction of the controller; A servo cylinder in which a servo piston is moved in a predetermined direction by a pressure supplied from a regulator body; A feedback lever for feeding back the operation of the servo piston to the pilot sleeve; And a tilting lever fixed to the servo piston and fixed to the swash plate.

Description

Servo regulator of variable displacement swash plate type piston pump controlled in positive-negative direction

The present invention relates to a regulator for controlling the swash plate angle of the forward and reverse variable swash plate piston pump in both directions, and more specifically, the inclination direction of the swash plate can be adjusted in both directions and the inclination angle can be precisely adjusted to a desired direction and angle. The present invention relates to a servo control regulator of a forward and reverse variable swash plate piston pump that can accurately maintain a swash plate.

In general, various types of machine tools or actuators are used in industrial fields, and machines or apparatuses are equipped with actuators such as pumps or motors for their operation. Among such devices, for example, in the case of the swash plate axial piston pump, the adjustment of the discharge amount thereof can be performed simply by changing the inclination angle of the swash plate, and for this purpose, a separate swash plate angle controller, that is, a regulator is provided.

However, such a regulator has a form or control method that is different for each hydraulic pump manufacturer, but in most cases it is composed of a large number of various components, as well as its operation and mechanism has a very complicated problem.

In addition, a mechanical-hydraulic control method is adopted as a control method of such a regulator. Recently, due to the development of electronic engineering, an electro-hydraulic control method has been proposed, and active research is being conducted. As the angle of inclination of the swash plate can be controlled, advanced technologies capable of adjusting in both directions exist as still challenges for those skilled in the art.

Accordingly, the present invention has been invented to solve the problems and problems described above, an object of the present invention is to provide a servo control regulator for a forward and reverse variable swash plate piston pump that can adjust the inclination or inclination angle of the swash plate in both directions. .

Another object of the present invention is to provide a servo control regulator for a forward and reverse variable swash plate piston pump which can be maintained by a worker or a user by adjusting a swash plate at a desired angle.

It is still another object of the present invention to provide a servo control regulator for a forward and reverse variable swash plate piston pump which can feed back the movement of a servo piston operating through a feedback lever so that the swash plate angle is maintained at a desired position. have.

Such objects include: a servo control regulator of a forward and reverse variable swash plate piston pump, comprising: a pilot pump for supplying power from an engine to generate and supply hydraulic pressure; A direction control valve connected to the first branch line of the pressure oil delivery line for delivering the pressure oil generated by the pilot pump and for selectively controlling the supply direction of the pilot pressure according to the inclination direction of the swash plate; A pilot sleeve communicating with a second branch line branched from the pressure oil delivery line, and receiving pilot pressure supplied from the direction control valve and moving in a predetermined direction; A regulator body for selectively releasing pilot pressure; A servo cylinder in which a servo piston is moved in a predetermined direction by a pressure supplied from a regulator body; A feedback lever movably fixed to both the servo piston and the pilot sleeve for feeding back the operation of the servo piston to the pilot sleeve; And a tilting lever fixed to the servo piston and to which the swash plate is movably fixed.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

First, referring to Figures 1 and 2, the servo control regulator of the forward and reverse variable swash plate piston pump according to the present invention is the engine 10 and the engine 10 is formed of an actuator such as a motor for generating the control power first And a pilot pump 12 for generating the hydraulic pressure and supplying power from the power supply.

The pilot pump 12 is connected to the direction control valve 16 by the first branch line 14a of the hydraulic oil supply line 14. The direction control valve 16 is preferably configured to include a direction switching spool 18 so as to change or adjust the direction of the swash plate in the neutral, left and right directions as will be described later. In addition, the direction control valve 16 is preferably provided with an operating lever 20 so that the operator or user can operate the direction control valve arbitrarily or automatically. According to this configuration, it is possible to convert the swash plate angle in both directions by switching the supply direction of the hydraulic pressure to the operation lever 20 and eventually to change or adjust the discharge direction of the pump. In addition, it is preferable that the drain line 24 is guided to the direction control valve 16 to guide the pressure oil discharged therefrom to the tank 22.

The regulator body 30 is connected to the direction control valve 16 by a first supply line 26 and a second supply line 28 to which hydraulic pressure controlled therefrom is transmitted and supplied. The main body 30 is formed in a housing or cylinder shape, and the second branch line 14b of the pressure oil delivery line 14 described above is directly connected to the main body 30.

The regulator body 30 will be described in more detail, and a center thereof is provided with a pilot pressure supply port 32 in communication with the pressure oil delivery line 14. In addition, a first control pressure supply port 34 is formed at one side of the regulator body 30 with the supply port 32 as the center, and a second control facing the first control pressure supply port 34 at the other side. The pressure supply port 36 is formed.

A central cylinder 38 communicating with the pilot pressure supply port 32 is formed inside the center of the regulator body 30, and a first pressurizing chamber 40 communicating with the first control pressure supply port 34 is formed at one side thereof. On the other side, a second pressurizing chamber 42 through which the second control pressure supply port 36 communicates is formed.

On the other hand, a pilot sleeve 43 is inserted into the central cylinder 38 of the main body 30 to slide left and right by the operation of the lever by the operation of the servo piston to be described later. The pilot sleeve 43 has a hydraulic oil passage 43a at regular intervals so that the hydraulic oil can pass therethrough.

The pilot sleeve 43 is inserted with a pilot spool 44 sliding left and right by the first control pressure supply port 34 and the second control pressure supply port 36 of the regulator body 30. On the central outer circumferential surface of the pilot spool 44, a first pressure passage 44a and a second pressure passage which can be selectively communicated with the pilot pressure supply port 32 through the pressure passage 43a of the pilot sleeve 43; It is preferable that 44b is formed spaced at predetermined intervals.

A pilot piston 46 which is in contact with one end of the pilot spool 44 and which can be reciprocated from side to side is inserted into the first pressure chamber 40 of the regulator body 30. In addition, a pilot spring 48 is provided in the first subscription chamber 40 to pressurize the pilot piston 46 or to provide a restoring force. The pilot spring 48 is stably supported in the first pressurizing chamber 40 by the spring holder 50. In particular, the outer end of the spring holder 50 is preferably provided with a pilot spring adjustment nut 52 to control the tension or elastic force of the pilot spring (48).

Correspondingly, a pilot piston 56 which is in contact with the other end of the pilot spool 44 and which can be reciprocated from side to side is inserted into the second pressurizing chamber 42 of the regulator body 30. In addition, a pilot spring 58 is installed in the second pressurizing chamber 42 to pressurize the pilot piston 56 or to provide a restoring force. The pilot spring 58 is stably supported in the second pressurizing chamber 42 by the spring holder 60. In particular, the outer end of the spring holder 60 is preferably provided with a pilot spring adjustment nut 62 to control the tension or elastic force of the pilot spring (58).

Two discharge ports, that is, the first discharge line 64 and the second discharge line 66 are connected to the regulator body 30. Here, the first discharge line 64 communicates with the first pressure passage 44a of the pilot spool 44, and the second discharge line 66 communicates with the second pressure passage 44b.

On the other hand, the servo cylinder 68 is communicated to the regulator main body 30 by the respective discharge lines 64 and 66. One side of the servo cylinder 68 is formed with a first chamber 70 in communication with the first discharge line 64 communicating with the main body 30, and a second chamber (communication with the second discharge line 66) at the other side. 72) is formed.

In addition, the servo piston 74 is inserted into the servo cylinder 68 so as to reciprocate or slide left and right.

On the other hand, one side of the servo cylinder 68 is provided with a bolted stopper 76 for limiting the maximum movement angle of the servo piston 74 and consequently the maximum movement of the swash plate angle described later. The stopper 76 is provided with an adjusting nut 78 to adjust the length from the outside.

According to the servo control regulator for the forward and reverse variable swash plate piston pump according to the present invention, a feedback lever 80 for achieving feedback between the servo piston 74 and the pilot sleeve 43 is provided. In particular, the lower end of the feedback lever 80 for feeding back the pilot sleeve 43 in accordance with the displacement of the servo piston 74 is fixed to the servo piston pin 82 fixed to the servo piston 74, and the upper end thereof is the pilot sleeve. It is rotatably fixed to the groove formed in the 43. According to such a configuration, when the servo piston 74 is displaced as it is operated, its movement or displacement is transmitted to the pilot sleeve 43 and eventually fed back to the displacement of the pilot sleeve 43, whereby the pilot sleeve 43 is The flow path formed by moving in the same direction as the movement direction of the pilot spool 44 is closed. That is, the feedback lever 80 has a function of determining the momentum of the pilot sleeve 43 in accordance with the momentum of the servo piston 74.

In addition, the tilting lever 84 is fixed to the lower portion of the servo piston 74. The swash plate 88 is coupled to the lower end of the tilting lever 84 by a joint 86. The tilting lever 84 is moved by the hydraulic pressure acting on either end of its servo piston 74 in the servo cylinder 68 so that this movement moves the swash plate 88 through the tilting lever 84. Configured to rotate.

Hereinafter, the operation and operation mode of the servo control regulator of the forward and reverse variable swash plate piston pump according to the present invention configured as described above will be described.

First, when the swash plate angle is neutral (0 °), as shown in Figs. 1 and 2, the direction switching spool 18 of the directional control valve 16 is located in the neutral position. At this time, of the pilot pressure generated by the pilot pump 12 by the operation of the engine 10 and sent out through the pressure oil delivery line 14 is sent through the first branch line (14a) to the direction control valve (16) The pressure supplied is returned to the tank 22 through the drain line 24 as it is without operating the diverting spool 18. In addition, the pressure supplied to the pilot pressure supply port 32 through the second branch line 14b is such that the pilot pressure supply port 32 communicates with the pressure oil passage 43a of the pilot sleeve 43, but the pilot spool Each of the hydraulic oil passages 44a and 44b of the 44 is closed by the pilot sleeve 43 so as to maintain the standby state in the pilot pressure supply port 32. Accordingly, the pilot pressure is not supplied to the first chamber 70 or the second chamber 72 of the pilot cylinder 68 through the first discharge line 64 or the second discharge line 66. Therefore, the pilot spool 44 is held stationary by the pilot springs 48 and 58 provided on both sides thereof at the center original position, and the servo piston 74 is held at the center original position and tilted. The swash plate 88 fixed to the lever 84 can be held in a neutral position.

On the other hand, in such a state, when the inclined swash plate in the right (+) direction, as shown in Figure 3, the direction switching spool of the direction control valve 16 by pulling the operation lever 20 automatically or by the operator As shown in the figure, 18 is moved to the left and the first branch pipe 14a communicates with the direction change spool 18 to operate the pilot spool 44. In more detail, some of the pilot pressure generated in the pilot pump 12 by the operation of the engine 10 and discharged through the pressure oil delivery line 14 may be directed through the first branch line 14a. After passing through the direction switching spool 18, the first supply line 26 is supplied to the first pressure chamber 40 of the main body 30 through the first control pressure supply port 34. The pressure supplied to the first control pressure supply port 34 presses the pilot piston 46 to be compressed in the direction of the arrow A1 and the pilot spring 48 is compressed and at the same time the pilot spool ( 44) It is also moved in the direction of arrow A1. At this time, the pilot sleeve 43 into which the pilot spool 44 is inserted remains in a stopped state.

As such, when the pilot spool 44 continuously slides in the direction of the arrow A1 so that the first pressure passage 44a formed on the center outer circumferential surface of the pilot spool 44 communicates with the central supply port 32, the delivery line The pilot pressure which is sent out to the central supply port 32 through the 2nd branch line 14b of (14), and is waiting to be discharged | emitted to the 1st discharge line 64 through the 1st pressure flow path 44a, and pilot cylinder It is supplied into the first chamber 70 of 68. The servo piston 74 is moved in the direction of the arrow A2 by the pressure supplied into the first chamber 70.

When the servo piston 74 is moved in the direction of the arrow A2, the feedback lever 80, which is freely fixed to both the pilot sleeve 43 and the servo piston 74, is rotated in the direction of the arrow A3, whereby the servo piston ( The displacement amount of 74 is transmitted to the pilot sleeve 43 by the feedback lever 84 so that the pilot sleeve 43 is moved in the same direction as the pilot spool 44.

As a result, the first pressure passage 44a formed in the pilot spool 43 in communication with the first discharge line 64 is closed by the feedback pilot sleeve 43 and the pressure is applied to the first chamber 70. This trapping causes the movement of the servo piston 74 to stop. As a result, the inclination angle is determined by the tilting lever 84 attached to the servo piston from the position where the servo piston 74 moves and stops, and the swash plate 88 is fixed and maintained at the inclination angle.

Conversely, in the case where the swash plate is inclined to the left side (-) as shown in FIG. 4 in the neutral state of FIG. 1, the direction of the direction control valve 16 is automatically or when the operation lever 20 is pushed by an operator. As the diverting spool 18 is moved to the right as seen in the figure, the first branch pipe 14a communicates with the diverting spool 18 to operate the pilot spool 44. In more detail, some of the pilot pressure generated in the pilot pump 12 by the operation of the engine 10 and discharged through the pressure oil delivery line 14 may be directed through the first branch line 14a. After passing through the second switching line (28) of the direction through the second supply line (28) through the second control pressure supply port 36 is supplied to the second pressure chamber 42 of the main body (30). When the pressure supplied to the second control pressure supply port 36 presses the pilot piston 56 and compresses it in the direction of the arrow A4, the pilot spring 58 is compressed and the pilot spool ( 44 is also moved in the direction of arrow A4. At this time, of course, the pilot sleeve 43 is to be stopped.

As such, when the pilot spool 44 continues to slide in the direction of the arrow A4 so that the second pressure flow passage 44b formed on the center outer circumferential surface of the pilot spool 44 communicates with the center supply port 32, the delivery line The second pressure passage 44b in which the pilot pressure which is sent out to the central supply port 32 through the second branch line 14b of (14) and communicates with the pressure passage 43a of the pilot sleeve 43 is communicated. It is discharged to the second discharge line 66 through the supplied into the second chamber 72 of the servo cylinder (68). The servo piston 74 is moved in the direction of the arrow A5 by the pressure supplied into the second chamber 72.

When the servo piston 74 is moved in the direction of the arrow A5, the feedback lever 80 whose both ends are freely fixed to the pilot sleeve 43 and the piston 74 is rotated in the direction of the arrow A6, whereby the servo piston 74 ), The displacement amount of) is transmitted to the pilot sleeve 43 by the feedback lever 80 to eventually move the pilot sleeve 43 in the same direction as the pilot spool 44.

As a result, the second pressure passage 44b formed in the pilot spool 44 in communication with the second discharge line 66 is closed by the movement of the fed back pilot sleeve 43 and the pressure is reduced in the second chamber ( It is trapped in 72, and the movement of the servo piston 74 is stopped. As a result, the inclination angle is determined by the tilting lever 84 attached to the servo piston from the position where the servo piston 74 moves and stops, and the swash plate 88 is fixed and maintained at the inclination angle.

On the other hand, when the operating lever 20 of the direction control valve 16 is operated to the neutral position of FIGS. 1 and 2 in the left inclined state or the right inclined state as described above to position the swash plate in the neutral position, The direction change spool 18 of the control valve 16 is returned to the neutral position, whereby the first branch line 14a of the pilot pressure generated by the pilot pump 12 and sent out through the pressure oil delivery line 14 is provided. The pressure supplied through the directional control valve 16 is returned to the tank 22 through the drain line 24 as it is. In addition, the pressure supplied to the pilot pressure supply port 32 through the second branch line 14a is such that the supply port 32 is closed by the pilot sleeve 43, and thus the first discharge line 64 or the second discharge line. Pressure is not supplied through line 66 to the first chamber 70 or the second chamber 72 of the servo cylinder 68.

At the same time, the pressurized oil trapped in the first chamber 70 or the second chamber 72 of the servo cylinder 68 is discharged to the tank 22 through the drain port 70a or 72a shown in FIG. Accordingly, the servo piston 74 is returned to the neutral position and at the same time, the pilot sleeve 43 is returned to the original position by the feedback lever 84, and the pilot spools 44 are provided at both sides of the pilot pistons 46 and 56. And by the pilot springs 48 and 58, they are moved to their original positions and kept in a stopped state. Accordingly, the swash plate 88 fixed to the tilting lever 84 is returned to the neutral position and maintained.

Accordingly, the driver or operator can operate the swash plate in the forward, reverse or neutral position by simply operating the control lever of the direction control valve, and the displacement of the servo piston which directly inclines the swash plate through the feedback lever can be controlled. It can be delivered to the pilot sleeve to control the operation of the servo piston as well as to stop it to maintain the swash plate at the desired inclination angle.

As a result, according to the servo control regulator of the forward and reverse variable swash plate piston pump according to the present invention, the operator or user can accurately adjust and maintain the swash plate at a desired angle, and the movement of the servo piston operated through the feedback lever can be maintained. By the feedback, the operator can maintain the swash plate angle accurately at the desired position, thereby improving the product quality.

In addition, it is possible to simply and easily adjust the inclination direction or the inclination angle of the swash plate in both directions has the effect of improving workability and convenience.

While a preferred embodiment according to the present invention has been described above, it will be understood by those skilled in the art that various modifications and changes can be made without departing from the scope of the appended claims.

1 is a block diagram showing a servo control regulator of the forward and reverse variable swash plate piston pump according to the present invention, showing a state in which the swash plate is maintained in a neutral position.

Figure 2 is a hydraulic circuit diagram of the servo control regulator of the forward and reverse variable swash plate piston pump according to the present invention.

Figure 3 is a block diagram showing a state in which the swash plate is inclined in the right direction by the operation of the servo control regulator of the forward and reverse variable swash plate piston pump according to the present invention.

Figure 4 is a block diagram showing a state in which the swash plate is inclined in the left direction by the operation of the servo control regulator of the forward and reverse variable swash plate piston pump according to the present invention.

♣ Explanation of symbols for the main parts of the drawing ♣

10: engine 12: pilot pump

14: pressure oil delivery line 16: directional control valve

20: operation lever 26, 28: pressure oil supply line

30: regulator body 32: pilot pressure supply port

40, 42: pressure chamber 43. pilot sleeve

44: pilot spool 46,56: pilot piston

48,58: pilot spring 50,60: spring holder

64, 66: discharge line 70, 72: chamber

74: servo piston 80: feedback lever

84: tilting lever

Claims (8)

delete delete It is connected to the pilot pump for generating and supplying hydraulic pressure by receiving power from the engine, and the first branch line of the hydraulic oil delivery line for delivering the hydraulic oil generated by the pilot pump, and supplying the pilot pressure according to the inclination direction of the swash plate. Directional control valve for selectively controlling the direction, and the pilot spool communicating with the second branch line branched from the hydraulic oil delivery line and the pilot spool selectively supplied with the pilot pressure supplied from the direction control valve is moved in a predetermined direction is built-in A servo cylinder having a pilot sleeve and having a regulator body for selectively discharging pilot pressure according to a moving direction of the pilot spool, a servo piston moving in a predetermined direction by a pressure supplied from the regulator body, and the servo The pilot sleeve to operate the piston A forward and reverse variable swash plate piston pump including a feedback lever movably fixed to the servo piston and the pilot sleeve for feeding back, and a tilting lever fixed to the servo piston and swash plate movably fixed to the servo piston. In servo control regulator, The regulator body is provided with a pilot pressure supply port communicating with the pressure oil delivery line at a central portion, a first control pressure supply port at one side with the pilot pressure supply port as the center, and a supply of the first control pressure at the other side. A second control pressure supply port facing the port is provided; A central cylinder communicating with a pilot pressure supply port is formed inside the center of the regulator body, and a first pressure chamber communicating with the first control pressure supply port is formed at one side, and a second control pressure supply port is communicated at the other side. A servo control regulator of a forward and reverse variable swash plate piston pump, wherein a second pressurizing chamber is formed. 4. The first pressure flow passage according to claim 3, wherein the center circumferential surface of the pilot spool is selectively communicable with the pressure passage of the pilot sleeve and the pilot pressure supply port, and connected to one side of the servo cylinder by a first discharge passage. And a second pressure flow path selectively connected to the pilot pressure supply port and connected to one side of the servo cylinder by a second discharge path is formed. Control regulator. According to claim 3, The first pressure chamber of the main body is in contact with one end of the pilot spool and the left and right reciprocating pilot piston is inserted, the pilot spring for pressurizing and restoring the pilot piston is installed; Forward and reverse variable swash plate piston pump is inserted into the second pressure chamber is a pilot piston for contacting one end of the pilot spool and reciprocating from side to side and a pilot spring for pressurizing and restoring the pilot piston. Servo control regulator. 6. The servo control regulator of claim 5, wherein each pilot spring is supported by a spring holder having a pilot spring adjustment nut for controlling its tension or elastic force. . According to claim 4, One side of the servo cylinder is provided with a first chamber in communication with the first discharge line in communication with the regulator body and formed on one side of the pilot piston, the second side in communication with the regulator body Servo control regulator of the forward and reverse variable swash plate piston pump is provided with a second chamber in communication with the discharge line formed on the other side of the pilot piston. The forward and reverse variable swash plate type of claim 7, wherein one side of the servo cylinder is provided with a bolted stopper for limiting the maximum movement of the servo piston, and an adjusting nut for adjusting the length of the stopper. Servo control regulator of piston pump.