KR200317928Y1 - Oil pressure hammer enabled beating frequency controll - Google Patents

Abstract

The present invention relates to a hydraulic hammer that can adjust the number of strokes to be able to arbitrarily adjust the number of strokes per minute by allowing the variable stroke of the piston striking the tool freely.

Conventional hydraulic hammer has a problem that the amount of fluid passing through the bypass passage 6 is not able to freely adjust the number of blows of the hydraulic hammer, that is, the number of blows or the bypass passage set at the time of manufacturing the hydraulic hammer There is a disadvantage in that only one of the number of blows obtained by passing through has been selected, the present invention is formed in the hammer body (1) and the piston (3) is installed therein, and is delivered to the cylinder Comprising a switching valve (2) for controlling the hydraulic pressure, the bypass flow path (6) is formed between the reverse chamber 31 of the cylinder (3) and the fifth flow path (255) for connecting the conversion valve (2) In this case, by installing the flow rate control valve (7) in the bypass passage (6), the number of blows per minute of the tool can be freely adjusted according to the conditions of the work site, which can greatly improve the work productivity Owl with the effect Adjustment will be hit with an easy-effects that can freely adjust the driver can strike without leaving the driver's seat.

Description

Oil pressure hammer enabled beating frequency controll

The present invention relates to a hydraulic hammer that fractures rock or concrete by operating with hydraulic force. More specifically, the stroke number per minute of the tool can be arbitrarily adjusted by freely adjusting the stroke distance of the piston striking the tool. It relates to a hydraulic hammer capable of adjusting the number of strokes.

In general, the hydraulic hammer is mounted on equipment such as an excavator, loader, etc. having a hydraulic pump to control the high-pressure fluid supplied from the hydraulic pump with a predetermined flow path and a valve to raise and lower the piston installed inside the hydraulic hammer. A tool that strikes a tool and causes the tool to crush a rock or concrete floor with its reaction force.

1 is a cross-sectional view showing a typical hydraulic hammer.

As shown in FIG. 1, the hydraulic hammer is composed of a hammer body 1, a cylinder 3 formed inside the hammer body, and a conversion valve 2 for controlling the hydraulic pressure delivered to the cylinder.

A piston 4 is installed inside the cylinder 3, a tool 40 is installed below the piston, and a compression gas chamber 35 is installed above the piston 4.

The cylinder 3 has a first flow path 251 connecting the reverse chamber 31 and the hydraulic pump 25, a second flow path 252 connecting the forward chamber 30 and the conversion valve 2, The third flow passage 253 connecting the cylinder 3 and the oil tank 26 is provided and configured, respectively.

And the conversion valve (2) is provided with a piston 21 which is elevated by hydraulic pressure inside the cylinder 20 of the valve body, the piston 21 of the pipe having a hollow portion 211 in the center thereof It is formed in a shape, the through-hole 2112 communicating with the first passage 251 is formed on the upper side of the piston 21 is configured.

In addition, a fourth passage 254 communicating with the third passage 253 is installed at the intermediate portion of the cylinder 20, and a lower portion of the cylinder 20 communicating with the intermediate portion of the cylinder 3 at the hydraulic hammer side. Five flow paths 255 are provided and configured.

In such a hydraulic hammer, when the fluid flows into the reverse chamber 31 of the cylinder 3 through the first flow path 251 by the operation of the hydraulic pump 25, the piston 4 moves up by the pressure of the fluid. Will be

The upper end of the piston 4 in the ascending operation is raised while compressing the gas of the compressed gas chamber 35, and the pressure of the compressed gas chamber is gradually increased in accordance with the ascending operation of the piston 4.

When the fifth flow path 255 is opened by the upward movement of the piston 4, the fluid flows into the cylinder 20 of the conversion valve 2 and raises the piston 21 installed inside the cylinder 20.

The lower end of the piston 21 is spaced apart from the bottom surface of the cylinder 20 by the upward movement of the valve-side piston 21, and the fluid flowing into the cylinder 20 is separated from the hollow portion 211 of the piston 21. It flows into the advance chamber 30 of the hammer side cylinder 3 through the 2 flow path 252. As shown in FIG.

When the through-hole 212 formed in the upper side of the piston 21 communicates with the first flow path 251 by the subsequent upward movement of the valve-side piston 21, the fluid supplied from the hydraulic pump 25 is no longer reverse chamber 31. It is not supplied to the) and flows only to the advance chamber 30 through the cylinder 20 and the second flow path 252 of the conversion valve (2).

When the fluid pressure of the reverse chamber 31 and the forward chamber 30 reaches almost the same level, the hammer-side piston 4 descends at a high speed due to the expansion pressure of the compression gas chamber 35 and the upper end of the tool 40. Will hit.

At this time, the descending piston 4 opens the third passage 253, and the fluid flowing into the advance chamber 30 is discharged into the oil tank 26 through the third passage 253. 254 is introduced to lower the piston 21 on the valve side, and the fluid supplied from the hydraulic pump 25 flows into the reverse chamber 31 to repeat the operation of raising the piston 4.

However, such a hydraulic hammer has a disadvantage of operating only by a constant force and a constant number of hits.

That is, the force hitting the tool 40 and the number of times hitting the tool 40 cannot be adjusted according to the conditions of the work site.

If the object to be crushed is hard, it must be hit with a small number of times, but if the object to be crushed is soft, it must be hit with a large number of times but it can be improved in productivity.

As a conventional one for solving the above disadvantages, as shown in FIG. 2, a bypass allowing a certain amount of fluid to flow between the reverse chamber 31 of the hydraulic hammer side cylinder 3 and the fifth flow path 255. It has been provided that the flow path 6 is formed and the cock 600 is provided in the bypass flow path 6.

Such a conventional hydraulic hammer has a small force, but if more hits are required, a portion of the fluid that opens the bypass passage 6 and raises the piston 4 in advance is transferred to the conversion valve 2 side to the piston 4. By shortening the stroke distance, the number of hits can be increased.

However, such a conventional apparatus has a problem in that the amount of fluid passing through the bypass passage 6 is fixed so that the number of strokes of the hydraulic hammer cannot be freely adjusted.

That is, there is a disadvantage in that only one of the number of blows set during the production of the hydraulic hammer or the number of hits by passing the bypass passage 6 is selected.

In addition, such a conventional hydraulic hammer has a cock 600 for blocking and opening the bypass passage 6 is installed in the hydraulic hammer body (1), the driver stops the equipment and adjusts out of the driver's seat whenever the number of blows is changed. There is discomfort that should be.

The present invention is to solve the conventional problems as described above, the present invention to be able to freely variable stroke stroke of the piston striking the tool to be able to adjust the number of strikes per minute of the tool arbitrarily adjustable hydraulic pressure The purpose is to provide a hammer.

Another object of the present invention is to provide a hydraulic hammer that allows the driver to freely adjust the number of strokes without leaving the driver's seat when adjusting the number of strokes.

The present invention is configured as follows to achieve the above object. That is, the present invention is composed of a cylinder formed in the hammer body and a piston is installed therein, and a conversion valve for controlling the hydraulic pressure transmitted to the cylinder, the fifth passage connecting the reverse chamber and the conversion valve of the cylinder The bypass passage is formed therebetween, characterized in that the flow passage control valve is provided in the bypass passage.

1 is a cross-sectional view showing a general hydraulic hammer

2 is a cross-sectional view showing a conventional hydraulic hammer.

3 is a cross-sectional view showing the hydraulic hammer according to the present invention

Figure 4 is a cross-sectional view showing an extract of the main portion of the flow control valve of the present invention

<Explanation of symbols for the main parts of the drawings>

1. Hammer body 2. Switching valve

3, 20. Cylinder 4, 21, 80. Piston

6. Bypass Flow 7. Flow Control Valve

8. Regulator 82. Solenoid valve

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

3 is a cross-sectional view showing an extract of the hydraulic hammer according to the present invention, Figure 4 is a cross-sectional view showing an extract of the flow control valve that is the main part of the present invention.

As shown in Figure 3 and 4, the present invention is a cylinder (3) formed in the hammer body (1) and the piston 4 is installed therein, and a switching valve for controlling the hydraulic pressure delivered to the cylinder ( 2), and the bypass passage 6 is formed between the reverse chamber 31 of the cylinder 3 and the fifth passage 255 for connecting the conversion valve 2 to the bypass passage. It is comprised by installing the flow regulating valve 7 in the flow path 6.

The flow control valve 7 has an inlet 71 connected to the hydraulic hammer side bypass flow path 601 at one end of the valve body 70, and an outlet connected to the conversion valve side bypass flow path 602 at one side. A valve body 73 is formed, and a valve body 73 having sides 731 and 732 contacting the inlet 71 and the outlet 72, respectively, is provided inside the valve body 70. The adjusting device 8 which adjusts the opening degree of each side 731, 732 is provided in the sieve 73, and is comprised.

In addition, the adjusting device 8 forms a flow path 81 in the valve body 70, and installs a piston 80 forward and backward by hydraulic pressure at the rear end of the valve body 73. The spring 74 is installed between the spring support 77 fixedly installed in the valve body 70, the solenoid valve 82 is installed in the flow path 81, and the solenoid valve 82 is controlled. The adjusting device 83 is configured to be installed in the driver's seat of the equipment.

When the object to be crushed is thus hardened, the present invention is constructed so that the hydraulic hammer has the maximum force, ie, the stroke length of the longest piston.

At this time, the flow control valve 7 installed in the bypass passage 6 is blocked to prevent the fluid in the reverse chamber 31 from passing through the bypass passage 6, and only through the fifth passage 255. To (2).

If the workpiece is weak, it is a small force, but it must be crushed with a large number of hits to increase the work productivity.

In this case, the fluid is introduced into the valve body 70 through the flow path 81 by opening the solenoid valve 82 of the adjusting device 8 by the driver using the adjusting device 83 of the driver's seat. The piston 80 advances by compressing the spring 74, and the valve body 73 is advanced by the forward operation of the piston 80, and the side 731 which has blocked the inlet 71 is opened.

As the side 731 of the inlet 71 is opened, a part of the fluid in the reverse chamber 31 passes the bypass passage 601 of the hydraulic hammer side, the outlet 72 of the flow regulating valve, and the bypass valve side of the conversion valve 602. Inflow into the conversion valve (2) through the ().

At this time, the fifth channel 255 is blocked by the piston 4.

As a part of the fluid in the reverse chamber 31 is transferred to the conversion valve 2 through the bypass flow path 6, the conversion operation of the conversion valve 2 proceeds quickly.

The fluid flowing into the conversion valve 2 raises the piston 21 installed inside the cylinder 20, and the lower end of the piston 21 is raised by the raising action of the valve side piston 21. The fluid that is spaced apart from the bottom surface and flows into the cylinder 20 flows into the advance chamber 30 of the hammer-side cylinder 3 through the hollow portion 211 and the second flow path 252 of the piston 21.

When the through-hole 212 formed in the upper side of the piston 21 communicates with the first flow path 251 by the subsequent upward movement of the valve side piston 21, the fluid supplied from the hydraulic pump 25 is no longer reverse chamber ( It is not supplied to 31 and only flows to the advance chamber 30 through the cylinder 20 of the changeover valve 2 and the second flow path 252.

When the fluid pressure of the reverse chamber 31 and the forward chamber 30 reaches almost the same level, the hammer-side piston 4 descends at a high speed by the expansion pressure of the compression gas chamber 35, thereby Hit the top.

That is, the stroke distance of the piston 4 can be freely adjusted according to the degree which passes the fluid of the reverse chamber 31 to the conversion valve 2 side through the bypass flow path 6.

If the stroke distance of the piston 4 is shortened, the force hitting the tool 40 is reduced, but the number of hits hitting the tool is increased, so that a large number of soft objects can be hit.

When the hydraulic hammer is to be returned to its original stroke, that is, to obtain a large force at a long stroke, the piston 80 controls the solenoid valve 82 through the adjustment period 83 so that the piston 80 Retracted by the return force, the side 731 of the valve body 73 blocks the inlet 71 so that fluid does not pass through the bypass flow path 6 so that the stroke distance of the piston 4 returns to its original state. Will be.

The present invention is not limited to the above-described embodiments, and various modifications can be made within the range permitted by the technical idea of the present invention.

As described above, according to the present invention, the number of strokes per minute of the tool can be freely adjusted according to the conditions of the work site, which greatly improves the productivity of the work, and the number of hits without the driver leaving the driver's seat when adjusting the number of strokes. There is a convenient effect that can be adjusted freely.

Claims (3)

It is composed of a cylinder (3) formed on the hammer body (1) and a piston (4) installed therein, and a conversion valve (2) for controlling the hydraulic pressure transmitted to the cylinder, the reverse chamber of the cylinder (3) In the bypass passage 6, which is formed between the 31 and the fifth passage 255 connecting the switching valve 2, the flow passage adjusting valve 7 is provided in the bypass passage 6. Hydraulic hammer capable of adjusting the number of blows, characterized in that the configuration. According to claim 1, wherein the flow control valve (7), the inlet 71 is formed at one end of the valve body 70, the outlet 72 is formed on one side, the valve body in the valve body 70 (73) is provided, the hydraulic hammer capable of adjusting the number of blows, characterized in that the valve body 73 is provided with an adjusting device (8) for adjusting the opening degree of the valve body. 3. The control device (8) according to claim 2, wherein the regulating device (8) forms a flow path (81) in the valve body (70), installs a piston (80) at the rear end of the valve body (73), and the piston (80) and An adjustment device 83 for installing a spring 74 between the spring receiver 77, a solenoid valve 82 in the flow path 81, and controlling the solenoid valve 82 is installed in the driver's seat. Hydraulic hammer capable of adjusting the number of blows, characterized in that the installation is configured.