JPS591802A - Cylinder controller - Google Patents

Abstract

(57) [Summary] This bulletin contains application data before electronic filing, so abstract data is not recorded.

Description

DETAILED DESCRIPTION OF THE INVENTION The present invention relates to a hydraulic cylinder control device for a working machine, such as a hydraulic breaker, a pile driver, or a punching press, which uses the kinetic energy of a cylinder piston to strike an object to be struck.

Fluid pressure 7 The kinetic energy of the cylinder piston is given by the product of the piston operating stroke, the effective pressure receiving area of the cylinder, and the fluid pressure acting on the piston. The operating stroke and effective pressure receiving area of the piston are determined by the size of the cylinder, but the fluid pressure is generated by the load on the piston. By the way, in the conventional hydraulic cylinders of this type of work equipment, for example, the hydraulic cylinders of hydraulic breakers, fluid pressure is only generated when the piston collides with the object to be crushed via the chisel near the bottom dead center. . Therefore, there is a drawback that the kinetic energy of the piston during the forward stroke of the piston, which is the crushing process, is small.

The present invention aims to eliminate the above-mentioned drawbacks, and consists of a cylinder control system in which a double-rod type double-acting cylinder is selectively connected to a pump and a tank using a pilot-operated two-position switching valve. In the device, the double rod type double acting/cylinder has a first valve mechanism that communicates with the tank 11111 line only when the piston is located at the upper limit and near the upper limit, and a first valve mechanism that communicates with the tank 11111 line only when the piston is located at the lower limit and near the lower limit. A second valve mechanism that communicates with the pump side pipe is arranged, and one pilot chamber of the two-position switching valve is connected to the first valve mechanism via a sequence valve that takes the pressure of the pump side pipe as the pilot pressure. In addition, the upstream side of the sequence valve is connected to the second valve mechanism.

Hereinafter, embodiments of the present invention will be described with reference to the drawings. In Figure 1, (1) connects one liquid chamber (2) to pipes (3) and (4).
) to the pump (5), and selectively connect the other liquid chamber (6) to the pipe (force, filter boat 2 position 1) to the pipe (4) and return pipe (9) via the switching valve (8). With the differential cylinder connected,
An annular groove (12) is formed at the base end of the piston rod (group) located on the side of the hit object (10), and the casing (
A piston (
15) Is it annular only when it is located at the lower limit (left travel end in the figure) and near the lower limit? M(+2+, a chamber (I6) communicating with the pump side pipe line (3) via the liquid chamber (2) is formed, and this chamber (I6) and the piston rod (the annular groove (marked)
12) constitute a second valve mechanism. In addition, an annular groove (I8) is formed at the tip of the other piston rod (17), which has a smaller diameter than the piston rod (11), and the upper limit of this annular groove is the piston (15) (the right stroke end in the figure). ) and the casing (13
The chambers (2+1+ and (21) are formed at appropriate intervals in the piston rod insertion hole (19) of J), and the chamber +2F+1 is connected to the passage (22) and the return line which is the tank side pipe. It communicates with the tank f23) via the pipe line (9). The annular groove (18) of the piston rod (17) and the chamber +20), f21) constitute a first valve mechanism.

The 6-point 2-position switching valve (8) is equipped with pilot chambers t24) and +25+ with different pressure receiving areas, and the pilot chamber (24) with a large pressure receiving area is connected by a passage (27) in which a sequence valve (2fil) is inserted. It is connected to the chamber (20) and to the chamber (16) by a passage (28) branching from between the pilot chamber (24) and the sequence valve (26), and is connected to the pilot chamber with a small pressure-receiving area. (29) connects to pipe (3).This filter boat 2-position switching valve (8
) is set to position B when no hydraulic pressure is applied to the pylon 1 chamber (24), and to position A when hydraulic pressure is applied. The pilot chamber C3 (++ of the sequence valve (solo) is connected to the pump side pipe line (3) through a passage (3I).

In addition, the pilot chamber (2) of the 6-bottom 2-position switching valve (8)
5) may be replaced with a spring. Further, the first valve mechanism may be a switching valve with a detection rod that switches from closed to open when the end of the piston rod (17) is detected with a detection rod.

Next, the operation of the present invention will be explained. The 6-point 2-position switching valve (8) is in position A due to the hydraulic pressure acting on the pilot chamber (2a), and communicates the liquid chamber (6) of the differential 7 cylinder (1) with the tank +231 so that the piston ( 15) is moving to the right in the figure due to pump operation @ liquid in the liquid chamber (2), the liquid pressure in the pump side pipe line (3) is the 7-can valve t2.
[Il is lower than the set pressure (setting power)/-can valve +261 is blocking the passage (27).

When the piston (15) reaches near the -1- limit, the chamber (2 (
The sword is ring-shaped) [II Chapter 18) and is connected to room (21) Tank (2: (+), but Z Ironoto (21) is cut off from communication with room f2f11, Robot 2
The position switching valve (8) is still in position A. Then, when the piston (15) stops at the upper limit, the pump hydraulic pressure increases, and when the hydraulic pressure exceeds the set pressure of the sequence valve (26), the sequence valve (26) takes position B and opens the pilot chamber (24).
In order to communicate with the tank (23), a two-position switching valve (8) is installed.
takes position B due to the hydraulic pressure in the pilot chamber (25) and communicates the liquid chamber (6) with the pump (5). As a result, the piston (15) receives high-pressure liquid on both sides thereof, and moves to the left from the upper limit to the lower limit based on the difference in pressure-receiving area between the two sides. That is, the piston (15) receives high-pressure pump working fluid from the leftward stroke, and as a result, generates large kinetic energy, which causes the piston (15) to reach a point near the lower limit
The i/C reaches the hit object (10). When the piston moves to the left, chambers +20) and (21) are connected to the annular groove (18).
When the piston rod (11) collides with the object (10), the chamber (Ifi) passes through the annular groove (12) and the liquid chamber (2). Communicates with pump side pipe line (3), pilot chamber (24)
Directs the pump hydraulic pressure to. This causes the switching valve (8) to move to position A.
and connect the liquid chamber (6) to the tank (23),
As soon as the piston 05) reaches its lower limit, it turns around and moves to the right in the figure, repeating the above-described operation.

Although the pump hydraulic pressure when the piston moves to the right is lower than the hydraulic pressure when the piston starts moving to the left, it still maintains a fairly high pressure.On the other hand, the sequence valve (2G) indicates that the piston (15) It returns to position A during one round trip.

As explained above, in the present invention, the piston automatically reciprocates between the set upper and lower piston limits L7, and during the reciprocating process, the piston is regulated by the sequence valve from the beginning of the forward stroke. By applying the high-pressure hydraulic fluid, it is possible to generate the desired large kinetic energy in the piston of this type of ring.

[Brief explanation of drawings]

FIG. 1 is a hydraulic circuit diagram showing an embodiment of the present invention. 1...Differential cylinder, 5...Pump, 8...Robot 2-position switching valve, 10...Object to be hit, 12.18...
・Annular groove, 15... Piston, 16, 20.21...
・Room, 24. Ro0...Pilot room, 26...Sequence valve. Special W “Applicant Kawasaki Heavy Industries Co., Ltd. Agent Patent Attorney Kenzo Ota

Claims (1)

[Claims] In a cylinder control device that uses a pilot-operated two-position switching valve to selectively connect a double-rod type double-acting/cylinder to a pump and a tank, the double-rod type double-acting cylinder has a piston located at the upper limit and near the upper limit. A first valve mechanism that communicates with the tank side pipe only when the piston is located at the lower limit and a second valve mechanism that communicates with the pump side pipe only when the piston is at the lower limit or near the lower limit are provided, and the two-position switchover mechanism is provided. The pilot chamber on one side of the valve takes the pressure of the pump side pipe as the pilot pressure/- is connected to the first valve mechanism via the can valve, and /- is connected upstream of the can valve to the second valve mechanism. A cylinder control device characterized by: