JPH0497404A - Electromagnetically proportional pressure reducing valve having switching function - Google Patents

Abstract

PURPOSE:To simplify a fluid circuit by using a spool to be driven by both of a proportional solenoid and an ON/OFF solenoid. CONSTITUTION:The spool 2 for switching the pump port of a valve body 1 to either one of a pair of switching ports 13, 14 is moved in one direction by controlling a current value inputted to the proportional solenoid 3 to control the pressure of a control line 4 to a pressure value proportional to the current value. Thereby, the spool 2 can be functioned as a pressure reducing valve and can be functioned also as a switching valve by moving the spool 2 by the ON/OFF solenoid 40 and switching the pump port 12. Consequently, the fluid circuit can be simplified as compared with a conventional case for switching a pump port by preparing an electromagnetic switching port independently of a pressure reducing valve.

Description

DETAILED DESCRIPTION OF THE INVENTION (Field of Industrial Application) The present invention relates to an electromagnetic proportional pressure reducing valve that has a switching function and a pressure reducing function suitable for controlling the operation of actuators and the like.

(Prior Art) Conventionally, a fluid control device having a switching function and a pressure reduction function is
This is already known as shown in Japanese Utility Model Application Publication No. 55-81805. As shown in FIG. 4, this fluid control device uses an electromagnetic switching valve (E) and a composite valve (H).
A composite valve (H) is connected to the a line of the electromagnetic switching valve (E), and b
The rod side chambers of the actuator (F) are connected to the lines, respectively, and the compound valve (H) includes a pressure reducing valve (A), a variable throttle (G), and a secondary control line (B) of the pressure reducing valve (A). ) and a check valve interposed between the control line (B) connected to the head side chamber of the actuator (F) and the a line. (D). Therefore, the switching valve (E), the pressure reducing valve (A) and the pressure reducing valve (A) are connected to the head side chamber of the actuator (F) from the pump.
), a controlled fluid is supplied through a pressure-compensated variable throttle (G), and the actuator (F
) is about to rise above the set pressure of the pilot valve (C), the pilot valve (C) opens and discharges the fluid in the control line (B) to the tank.

Therefore, the pressure in the head side chamber of the actuator (F) is reduced to the set pressure set by the pilot valve (C), and the actuator (F) moves forward at the set pressure.

Further, in order to move the actuator (F) back, the switching valve (E) is switched, and the head side chamber of the actuator (F) is communicated with the tank line via the check valve (D) and the a-line. This is done by communicating the rod side chamber with the pump line.

(Problem to be Solved by the Invention) However, in the composite valve configured as described above, the pressure of the control line (B) connected to the actuator (F) is controlled by the variable throttle (G) and the pilot valve (C). ), so in order to make the actuator (F) move back, it is necessary to connect the compound valve (H) to the downstream line of the compound valve (H). It is necessary to separately provide a solenoid switching valve (E), which causes problems such as a complicated fluid circuit and high cost.
) is controlled only by the operation of a pilot valve that allows the set pressure of the reduced pressure to be adjusted by operating a manual operation handle, so the pressure in the control line cannot be controlled with high precision and the hysteresis is poor. There was a problem.

The present invention was devised in view of the above points, and its purpose is to reduce the pressure in the control line connected to the switching port by using a single spool that operates both as a proportional solenoid and as an on/off solenoid. , ports can be switched, the fluid circuit can be simplified, and when used as a pressure reducing valve, the pressure control of the control line can be made highly accurate in proportion to the current value, and hysteresis can be improved. The point is to make it.

(Means for Solving the Problems) Accordingly, the present invention provides a valve body (1) having a pump port (12) and first and second switching ports (13) and (14), The spool (
2), and a control line (4) disposed on one side of the spool (2) that operates the spool (2) in proportion to the current and controls the pressure of a control line (4) connected to the first switching port (13). When controlling the pressure of the proportional solenoid (3) having a horizontal attraction force characteristic of
A controller (
7), a pressure detector (10) that detects the pressure of the control line (4) and feeds back pressure information to the controller (7), and a pressure detector (10) that is disposed on the other side of the spool (2) and that ) (12) to the second switching port (
14) and an on/off solenoid (40).

(Function) When a desired current value is applied to the proportional solenoid (4), the spool (2
), the pump port (12) is the first switching port (1
3), and the valve opening of the spool (2) is controlled proportionally, so that the spool (2) acts as a pressure reducing valve and the first switching Spool (2) of control line (4) connecting to port (13)
Therefore, the reduced pressure can be controlled to a desired pressure. When controlling the pressure of the control line (4), the pressure of the control line (4) is detected by the pressure detector (10),
Detection information from this detection is fed back to the controller (7), and the controller (7) adjusts the current value energized to the proportional solenoid (3) based on the pressure command based on the feedback detection information. It will be done. Therefore, even if the pressure in the control line (4) rises above a predetermined pressure due to a load such as an actuator, the pressure in the control line (4) can be controlled to a desired set pressure based on the detected information. Moreover, the pressure control of the control line (4) can be performed with high precision, and the control line (4) can be controlled with high precision for the pressure command value.
The pressure can be controlled linearly, and linearity of control can be expected, and hysteresis can be reduced.

Also, when the on/off solenoid (3) is turned on, the spool (2) moves to the right in Figure 2, and the switching valve switches the pump port (12) to the second switching port (14). function is obtained, and the pump port (1
The fluid of 2) is supplied to the chamber on the other side of the load, and the actuator moves back.

(Example) In Fig. 2, (1) shows a valve chamber (11) and a valve chamber (11).
1), a pair of switching bows (13), (14), and a tank port (15), the valve body having a pump port (12) continuous to the valve chamber (11), a pair of switching bows (13), (14), and a tank port (15); A spool (2) for switching the switching port (12) to one of the switching ports (13) and (14) is freely movable inside.

Further, at the right end of the valve body (1) in FIG. 2, there is a control line (4) that operates the spool (2) in proportion to the current value based on the pressure command and connects to the switching port (13). Proportional solenoid with horizontal suction force characteristics to control pressure (
3), and connect the electromagnetic coil (31) of this proportional solenoid (3) to the pressure command device (5) on the input side, as shown in Figure 1, and connect it to the pressure command from this pressure command device (5). a controller that controls the pressure of the control line (4) by adjusting the current value energized to the proportional solenoid (3) based on the
7) is connected to the output side. Further, a feed bank circuit (8) that detects the pressure in the control line (4) and feeds back pressure information is connected to the input side of the controller (7) via a first computing unit (9). It is. The feedback circuit (8) includes a pressure detector (10) that detects the pressure of the control line (4), converts the detected pressure value into a voltage signal, and outputs the voltage signal. A pressure-to-voltage converter (10a) for converting detected pressure information into a voltage value is provided, and the pressure detection value converted to voltage by the converter (10a) is transferred from the feedback circuit (8) to the first computing unit. Enter (9),
The pressure command value and the pressure detection value are calculated and the compensation circuit (6
) and a switch (S1) operated by the output from this compensation circuit (6), the current value energized to the proportional solenoid (3) is adjusted so that the pressure in the control line (4) becomes the pressure command value. I'm trying to adjust it accordingly.

The proportional solenoid (3) includes a movable iron core (32) and the electromagnetic coil (31) that drives the movable iron core (32).
and a fixed iron core (33), and a bushing rod (34) that comes into contact with the end face of the movable iron core (32), and the tip of the bushing rod (34) makes contact with the right end face of the spool (2). Then, by energizing the electromagnetic coil (31), a horizontal attraction force characteristic as shown in FIG. In the range in which the horizontal attraction force can be obtained, the attraction force and the pressing force of the offset spring (20) are balanced at one predetermined location for a certain current value, and balanced at another location for other current values. The spool (2) is controlled to this balanced position, and the first switching port (] is controlled depending on the position of the spool (2).
3) The opening degree of the valve is controlled proportionally.

Further, at the left end of the valve body (1) in FIG. Movable iron core (41
), and the tip of the push rod (44) of the on/off solenoid (40) comes into contact with the left end surface of the spool (2). At the same time, the electromagnetic coil (42) is connected to an input device (which inputs the switching voltage).
21) via an open/close switch (S2), and by energizing the electromagnetic coil (42), the movable iron core (41)
The end face of the fixed iron core (43) is attracted to the end face of the fixed iron core (43), and the spool (2) is moved against the offset spring (22) into the second
By moving the pump port (12) to the right in the figure, the pump port (12) is switched to the second switching port (14).

An interlock circuit (not shown) is connected between the switches (S, ) (SQ) to control both switches not to turn on at the same time, or to control both switches to turn off at the same time. It is set up.

Further, in FIG. 1, (23) is a voltage/current converter provided on the output side of the opening/closing switch (S,), and (24) is a feedback circuit, which connects the opening/closing switch (S,) and the voltage/current converter ( 23) via a second arithmetic unit (25).

The present invention is configured as described above, and when neither the proportional solenoid (3) nor the on/off solenoid (40) is energized, the spool (2) is moved by the offset springs (20) and (22). As shown in Figure 2, it is stopped at the neutral position.

Therefore, a pressure command is output from the pressure command device (5),
When the switch (S1) is turned on, the proportional solenoid (3
), when a desired current value is applied to the movable iron core (32
) is attracted to the fixed iron core (33), and the offset spring (2
This movement causes the spool (2) to move to the left in Figure 2, causing the pump port) (1
2) is connected to the first switching port (13), and the second switching port (1
4) opens into the tank port (15).

Due to this opening, pressure fluid flows from the pump port (12) to the first switching port (13), and the pressure fluid flows from the pump port (12) to the first switching port (13).
14), the return fluid flows to the tank port (15).

As shown in Fig. 3, the suction force and the pressing force of the offset spring (20) are balanced at a position where the horizontal suction force characteristic of the proportional solenoid (3) is obtained, and the spool (2) moves at this balanced position. stops. In this state, the pump is connected to the pump port (1) via the pump line (26).
2) is supplied to the head side chamber of the actuator (F) from the first switching port (13) via the control line (4), and the actuator (F) is moved to the right in Figure 1. Ru. In this case, the fluid pressure in the control line (4) is detected by a pressure detector (10), and pressure information is fed back as a voltage signal from the pressure detector (10) to the controller (7).
The current value applied to the proportional solenoid (3) is adjusted so that the pressure in the control line (4) becomes the pressure command value. Therefore, even if the pressure in the control line (4) rises above a predetermined pressure due to movement of the actuator CF), the pressure in the control line (4) can be reduced to a pressure corresponding to the pressure command value based on the detected information. It is. Moreover, since the pressure control of the control line (4) is performed by feeding back the pressure, it can be controlled with high precision, and the pressure can be controlled linearly with respect to the pressure command value, improving its linearity. In addition, hysteresis can be reduced.

Next, with the pump port (12) switched to the first switching port (13) as described above, the pump port (12) is switched to the first switching port (13).
2) to the second switching port (14), the input to the input device (21) turns off the switch (S1), turns off the proportional solenoid (3), and turns on and off the solenoid (40). ) is turned on, and the spool (2) is moved to the right in FIG. The fluid in the pump port (12) is supplied to the rod side chamber of the actuator (F) via the second switching port (14), and the head side chamber of the actuator (F) is switched to the tank port (14). 15) and is opened to the tank, and the actuator (F) moves back to the right in FIG.

(Effects of the Invention) As described above, according to the present invention, by controlling the current value input to the proportional solenoid (3), the pump port (12) of the valve body (1) is connected to the pair of switching ports (13) (14). )
By moving the spool (2) in one direction, the pressure in the control line (4) can be controlled to a pressure proportional to the current value, and the spool (2) can be operated as a pressure reducing valve. , on, off solenoid (40)
By moving the spool (2), the pump port (12) can be switched, thereby acting as a switching valve. Therefore, like the conventional example mentioned above,
Compared to a system in which an electromagnetic switching valve is provided separately from the pressure reducing valve to switch pump ports, the fluid circuit can be simplified and costs can be reduced.

Moreover, when controlling the pressure of the control line (4), a controller (7) adjusts the current value energized to the proportional solenoid (3) based on a pressure command to control the pressure of the control line (4). and a pressure detector (10) that detects the pressure of the control line (4) and feeds back pressure information to the controller (7), so that the pressure of the control line (4) is feedback-controlled. Therefore, the pressure control of the control line (4) can be made highly accurate, the pressure can be controlled linearly with respect to the pressure command value, linearity of control can be obtained, and hysteresis can be reduced.

[Brief explanation of the drawing]

Fig. 1 is a control circuit diagram showing one embodiment of the pressure reducing valve of the present invention, Fig. 2 is a partially cutaway front view, Fig. 3 is a suction car stroke characteristic diagram of a proportional solenoid, and Fig. 4 is a control circuit showing a conventional example. It is a circuit diagram. (1) Valve body (11) Valve chamber (12) Pump port (13) First switching port (14) Second switching port (2 )...Spool (3)...Proportional solenoid (4)...Control line (7)...Controller (10)...Pressure detector

Claims (1)

[Claims] 1) Pump port (12) and first and second switching ports (
13) and (14);
), and a spool (2) disposed on one side of the spool (2), which operates the spool (2) in proportion to the current, and the first switching port (13). a proportional solenoid (3) with a horizontal suction force characteristic that controls the pressure of a control line (4) connected to the control line (4);
); a controller (7) that controls the pressure of the control line (4) by adjusting the current value energized to the proportional solenoid (3) based on a pressure command; and the control line (4). The controller (7) detects the pressure of
) Pressure detector (10) that feeds back pressure information to
and an on/off solenoid (40) disposed on the other side of the spool (2) for switching the pump port (12) to the second switching port (14). Electromagnetic proportional pressure reducing valve with functions.