JP2619635B2 - solenoid valve - Google Patents

Description

Description: BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a solenoid valve that switches a spool in accordance with an exciting current of a solenoid.

Conventional solenoid valves V _u shown in (prior art) 4-6 Figure, the solenoid 1
Alternatively, the spool section 3 is switched in accordance with the exciting current for 2.

Thus, the spool 3 is when in the neutral position shown, the pump passage 4 and the tank passage 5 is communicated with the electromagnetic valve V _U.

Then, for example, when the solenoid 1 is excited, the spool portion 3 is switched to the left position, and the pump P communicates with the left chamber 6 of the cylinder S, and the right chamber 7 communicates with the tank T. Therefore, the piston 8 of the cylinder S moves rightward in FIG.

When the other solenoid 2 is excited, the spool portion 3 is switched to the right position, and the piston 8 of the cylinder S is moved leftward.

(Problems to be Solved by the Present Invention) In the conventional solenoid valve as described above, for example, the larger the piston 8 of the cylinder S moves and the larger the consumed flow rate, the more the solenoid 8 excites the exciting current of the solenoid. The control pressure, that is, the gain is reduced. Figure 5 is the flow consumption of the cylinder S is gradually increased to Q ₃ from Q _1, shows that the pressure gain decreases accordingly.

Also, as shown in FIG.
The pressure gain is reduced. That is, when the oil temperature decreases, the viscosity increases. However, when the oil viscosity increases, the stroke of the spool portion 3 is
The working stroll of the cylinder S increases. Conversely, if the oil temperature increases, the viscosity decreases, but if the oil viscosity decreases in this way, the stroke of the spool portion 3
The working stroke of the cylinder becomes smaller.

SUMMARY OF THE INVENTION An object of the present invention is to enable constant control to be performed irrespective of changes in the consumption flow rate of a cylinder and changes in oil temperature.

(Means for Solving the Problems) In order to achieve the above object, the present invention provides a solenoid valve which switches the spool by positioning push rods provided on a solenoid at both ends of the spool and exciting the solenoid. Assuming that a pair of spring chambers facing each end of the spool, a through hole formed along the axis of the spool and communicating these spring chambers, and each end of the spool parallel to the axis. And a control pin slidably inserted into each of the pin holes. When the spool is switched, the operating pressure of the actuator port is guided to the pin hole on the movement direction side, and The outer ends of the control pins inserted into these pin holes abut against stoppers outside the spool to act on the spool in a reaction force in the direction of movement. It is characterized by the following points.

(Operation of the Present Invention) Since the present invention is configured as described above, when the solenoid is excited to switch the spool, the operating pressure at that time acts as a reaction force on the spool end.

Therefore, the relative difference between the reaction force acting on the spool end and the pressing force of the push rod due to the exciting current of the solenoid changes according to the operating pressure, and the switching amount of the spool is controlled according to the relative difference. Will be done.

(Effect of the Present Invention) According to the solenoid valve of the present invention, the switching amount of the spool is automatically adjusted in accordance with the operating pressure. become.

Also, a through hole is formed in the spool along the center of the shaft,
Since the two spring chambers are communicated with each other, the pressure acting on the end of the spool can be constantly balanced to suppress the occurrence of damping. Moreover, when the spool moves, the pressure acting on the spool does not change even if the volume of the spring chamber changes, so that the spool can be moved stably.

Furthermore, at each end of the spool, two or more pin holes are formed in parallel with the axis, so that the control pins are arranged so as to surround the through-holes. Can be stabilized.

(Embodiment of the present invention) The spool 14 has a pin hole parallel to the axis.
Two pins 29 to 32 are formed on the left and right sides, and the inner ends of the pin holes 29 to 32 are bent at substantially right angles to open around the lands 33 and 34 of the spool 14.

Control pins 35 to 38 are provided in the pin holes 29 to 32 as described above.
Is slidably inserted, and its outer end penetrates through the second spring seats 25, 26 and protrudes into the spring chambers 12, 13, so as to abut the first spring seats 23, 24.

Note that when the spool 14 is at the neutral position, the lands 33 and 34 have cylinder ports 39 and 39 formed in the valve body a.
The underlap state is maintained for 40.

If the spool 14 is at the neutral position in the drawing, the pump port 41 communicates with the tank ports 42 and 43, so that the discharge oil of the pump P flows to the tank T.

Now, when one of the proportional solenoids 17 is excited, the push rod 19 pushes the spool 14 and moves the spool 14 against the centering spring 28. When the spool 14 moves in this manner, the actuator port 39 and the tank port 42 communicate with each other, and the pump port 41 and the actuator port 40 communicate with each other. Therefore, the discharge oil of the pump P is supplied to the right chamber 45 of the cylinder S, and the hydraulic oil of the left chamber 44 is returned to the tank T.

However, depending on the amount of movement of the spool 14, the above-mentioned underlap is not sufficiently shut off.
A part of the discharged oil flows out of the tank port 43 and returns to the tank. That is, in this solenoid valve, the supply flow rate to the cylinder S is controlled according to the amount of movement of the spool 14, in other words, the exciting current to the solenoid.

If the spool 14 is switched as described above, the cylinder S
Operates, but the load pressure of the cylinder S at this time is guided to the pin holes 31 and 32 and acts on the control pins 37 and 38.

When pressure is applied to the control pins 37 and 38, the control pins always contact the first spring seat 24. Therefore, the force acting on the control pins 37 and 38 exerts a force on the spool 14 in the moving direction. Acts as a reaction force against Then, the magnitude of the reaction force at this time is (P ₁ × 2A) + F. In this equation, P ₁ is the load pressure of the cylinder S, A is the pressure receiving area of the control pin, and F is the spring force of the centering spring 28.

As described above, the reaction force corresponding to the load pressure of the cylinder S acts on the spool 14, so that the spool 14
The actuator moves to a position where the pressing force of the push rod 19 determined by the exciting current of 17 and the reaction force determined by the load pressure of the cylinder S are balanced.

Therefore, the smaller the pressure gain with respect to the exciting current of the solenoid 17, the smaller the reaction force becomes. I do. That is, if the pressure gain is small, the spool is moved accordingly and the gain is increased.

Conversely, if the pressure gain is large, the reaction force overcomes the pressing force of the push rod, so that the spool 14 is pushed back, reducing the flow rate of supply to the actuator, and reducing the pressure gain.

When the other solenoid 18 is excited, the spool 14 moves to the left in the drawing to supply pressure oil to the left chamber 44 of the cylinder S, and the control mode is to excite the one solenoid 17. Same as above.

Reference numeral 46 in the figure denotes a through hole formed along the axis of the spool 14 and connects the spring chambers 12 and 13 to each other. The reason why the spring chambers 12 and 13 are communicated in this way is that the movement of the spool 14 changes the volume of the spring chambers 12 and 13.

Furthermore, the first spring seats 23, 24 of the above embodiment
Are also functioning as stoppers for the control pins 35 to 38.

[Brief description of the drawings]

1 to 3 show an embodiment of the present invention.
FIG. 2 is a sectional view, FIG. 2 is a sectional view of a spool corresponding to line II-II in FIG. 1, FIG. 3 is a circuit diagram, FIG. 4 is a circuit diagram of a conventional solenoid valve, and FIGS. 9 is a graph showing a pressure gain of a conventional solenoid valve. 17, 18 …… Solenoid, 19, 20 …… Push rod, 2
3, 24: The first spring seat that also functions as a stopper, 29 to 32: Pin holes, 35 to 38: Control pins.

 ──────────────────────────────────────────────────続 き Continuation of the front page (56) References JP-A-51-17025 (JP, A) JP-A-47-22516 (JP, A) Actually open Showa 50-70396 (JP, U) Actually open Showa 61- 73803 (JP, U) Jiko 44-465 (JP, Y1)

Claims (1)

(57) [Claims] 1. A solenoid valve for switching a spool by energizing a push rod provided on a solenoid at both ends of a spool, and a pair of spring chambers facing each end of the spool. , Formed along the shaft center line of the spool and communicating with these spring chambers, and at each end of the spool, two or more pin holes formed in parallel with the axis, and slidable in these pin holes When the spool is switched, the operating pressure of the actuator port is guided to the pin hole on the moving direction side, and the outer ends of the control pins inserted into these pin holes are connected to stoppers outside the spool. An electromagnetic valve, wherein the solenoid valve is configured to abut on the spool to act on the spool in a reaction force against the moving direction.