KR200183464Y1 - Hydraulic breaker - Google Patents

Abstract

The present invention relates to a hydraulic breaker, comprising: a valve housing (B) having a valve (B1) for distributing oil pressure;

The inlet hole (1), the return hole (8) and the outlet hole (2) of the external hydraulic pressure are respectively installed in communication with the valve housing (B), the connecting passage (9) in the inlet hole (1) and the return hole (8) A cylinder body A each of which is formed across the 10;

The back head configured to fill the gas chamber 16 with the gas pressure in the head-side space of the piston 24;

The entry direction of the inlet hole (1) formed in the cylinder body (A) and the entry direction of the return hole (8) are alternately formed so that the size of the return hole (8) and the hole (15) can be designed large As a result, the movement speed of the high pressure oil can be increased by increasing the size of the return hole 8 and the hole 15, and the hydraulic resistance thereof can be reduced when the piston is lowered, and the impact force of the chisel can be increased by the rapid piston lowering.

It is also a very useful design such that the efficiency of the entire breaker is increased.

Description

Hydraulic breaker

The present invention relates to a hydraulic breaker, and is particularly designed to increase the blow energy by increasing the feed rate of high pressure flow when the piston descends.

Nitrogen gas is injected into the gas chamber of the back head in the upper part of the piston of the breaker, and this is the head of the piston 24, and the crushing well, or chisel 25, is placed on the same line in the lower part of the piston 24, so that the high pressure fluid Is supplied to the upper end portion (X) of the piston through the valve (B1), the piston is lowered with the compressed gas force to hit the chisel and the chisel is to crush the rock.

When the high pressure oil reaches the Y part of Fig. 2 via the inlet hole 1, the lower part of the piston becomes high pressure so that the piston 24 rises to compress the gas on the head side and the valve B1 when the maximum position is reached. As the pressure rises and the high pressure enters the piston upper end X, the piston upper end X is converted into high pressure, and the piston 24 is momentarily lowered by the high pressure hydraulic force and the expansion force in which the compressed gas in the gas chamber is returned to strike the chisel top. do.

Therefore, it is configured to impact the chisel 25 by the lowering of the piston 24, and to fracture the rock or the like by the impact force.

Here, the process of raising and lowering the piston by the action of hydraulic pressure will be described in more detail.

The cylinder body (A) is an accumulator (C) and a hydraulic passage in which the piston 24 and the chisel 25 are installed in the same line as shown in FIG. 2, and the hydraulic pulsation decreases and supplies insufficient oil when the piston descends. The control valve housing B is provided in the one side, respectively.

As shown in FIGS. 1 and 2, the hydraulic inlet hole 1, the return hole 8, and the discharge hole 2 are respectively disposed in the cylinder body A and the valve housing B across the connecting passages 9 and 10, respectively. It is installed in communication with).

When the high pressure oil acts inside the cylinder body A through the inlet hole 1, the piston 24 is raised to the position of FIG. 3. When the piston 24 is moved to the position of the front end jaw 24a, the high pressure oil is stored in the cylinder. The pressure is applied to the groove 3 'around the valve B1 as shown in FIG. 4 through the passage 6 communicated with the oil hole 5 and the valve housing B, which is dug into the body A.

The valve B1 is slidably installed between the dispensing housing B and the valve plug B2 and has two holes 11 and 37 communicating with the passages 7 and 22 of the valve housing B. Dig up.

When the high pressure oil acts on the groove portion 3 ', the stepped area of the groove portion 3' is larger than the step area of the hole 11, so that the force is greater than the pressure acting around the hole 11 of the valve B1. Since the valve (B1) is actuated, at this time, the passage (7) dug into the valve housing (B1) has a state in which the high pressure is continuously applied via the connecting passage (9) (10).

On the other hand, since the high pressure continues to act around the hole 11 before the valve B1 rises, and the passage 6 of the valve housing B1 maintains the low pressure, the valve B1 is at the bottom dead center. As shown in Fig. 4, the hole 11 has a state blocked by the valve plug B3.

When the valve B1 rises as described above due to the action of the high pressure oil, as shown in FIG. 5, the position of the hole 11 is located between the communication hole 12 of the valve plug B2 and the valve cover B4. ) And the high pressure oil is moved to the uppermost space X of the cylinder body A through the passage 14 of the valve housing B1 and the hole 15 drilled in the cylinder body A.

At this time, since the high pressure oil is applied to the head side of the piston 24 together with the gas pressure compressed by the rise of the piston 24, the piston 24 descends quickly.

Therefore, the force which strikes the chisel 25 has a result which falls proportionally.

When the piston 24 descends, the high pressure oil acting on the lower end side of the piston and the high pressure gas compressed on the accumulator C push out the high pressure oil positioned under the diaphragm of the accumulator C. It is moved to the hole 11 dug in the valve B1 via the connecting passage 9 of the return hole 8 and the connecting passage 10 of the inlet hole 1.

As the piston 24 descends, the high pressure oil acting on the groove part 3 while passing through the 'W' point is connected to the low pressure oil of the 'Z' part, and the high pressure is continuously applied by the connecting passages 9 and 10. The distribution valve also begins to descend due to the area difference of the holes 11, and the piston continues to descend so that the lower end of the piston 24 hits the upper end of the chisel. When B1) descends to the bottom dead center, the high pressure oil is closed and the upper head portion 'X' of the piston 24 is always in communication with the passage 22 connected at low pressure.

The piston 24 operated in this way has less pressure loss depending on how quickly the high pressure oil located in the downward direction moves to the head side when the piston 24 is lowered, so that the lowering speed of the piston 24 is increased.

Therefore, the most important blow hydraulic efficiency in the valve device of the hydraulic breaker is determined by whether the high pressure oil at the lower end of the piston 24 is quickly transferred to the head side gas chamber 16 without resistance.

Conventionally, the oil passage formed in the cylinder body A has a structure as shown in FIG.

That is, on both sides, a plurality of bolt holes (h), inlet holes (1), return holes (8), discharge holes (2), etc., for fixing the accumulator (C) are successively provided, and the inlet holes (1) The hole 15 is provided between and the return hole 8.

In addition, the connecting passages 9 and 10 are formed in the inlet hole 1 and the return hole 8 so as to communicate with each other.

It is inevitable that the bolt hole (h), the inlet hole (1), the return hole (8), the discharge hole (2), etc., respectively, are provided within the limited width as described above. The diameter of the connecting passage 9 which is to be drilled becomes narrow.

As shown in FIG. 6, since the directions of the inlet hole 1 and the return hole 8 are each formed on the right side in the same direction from the cylinder body A in the drawing, the arrangement of spaces and the strength between the flow paths are maintained. In order to maintain a minimum appropriate spacing for the hole 15 and the connecting passage 9 it was not possible to design a large size.

Therefore, when the piston 24 descends, it is impossible to expect a rapid movement of the high pressure oil, and thus there is a closed end such that the impact strength of the chisel 25 cannot be increased.

The purpose of the present invention is that when the piston descends, the space 'Y' high pressure oil formed at the lower end of the piston is quickly moved to the upper space 'X' of the piston to reduce the pressure drop in the upper space 'X', which can significantly improve the hitting force of the chisel. To provide one hydraulic breaker.

1 is a plan view showing an oil passage structure of a conventional cylinder body

Figure 2 is a longitudinal cross-sectional view showing a change in the piston movement in the hydraulic breaker

Figure 3 is an operation of Figure 2 showing the piston raised by the supply of high pressure oil

Figure 4 is an enlarged cross-sectional view showing the oil passage structure formed in the valve and the valve plug in the conventional valve housing

Figure 5 is an operating state of Figure 4 showing the state of movement of the valve

Figure 6 is an enlarged plan view showing the oil passage structure of the conventional cylinder body

7 is a plan view showing the oil passage structure of the cylinder body according to the present invention

8 is a cross-sectional view of FIG.

9 is a plan view showing an oil passage structure in another embodiment corresponding to FIG. 7;

Explanation of symbols for the main parts of the drawings

A-Cylinder Body B-Valve Housing

C-Accumulator 1-Entry Hole

2-discharge hole 6,7,22-passage

8,8 '-Return hole 12-Communication hole

15,15 '-Hole 16-Gas Chamber

24-Piston 25-Chisel

The object of this invention is a valve housing (B) having a valve (B1) for distributing oil pressure;

The inlet hole (1), the return hole (8) and the outlet hole (2) of the external hydraulic pressure are respectively installed in communication with the valve housing (B), the connecting passage (9) in the inlet hole (1) and the return hole (8) A cylinder body A each of which is formed across the 10;

The back head configured to fill the gas chamber 16 with the gas pressure in the head-side space of the piston 24;

The entry direction of the inlet hole (1) formed in the cylinder body (A) and the entry direction of the return hole (8) are alternately formed so that the size of the return hole (8) and the hole (15) can be designed large Is achieved by.

Therefore, by increasing the size of the return hole 8 and the hole 15, the moving speed of the high pressure oil can be increased to reduce the hydraulic resistance when the piston is lowered, and the impact force of the chisel can be increased by the rapid piston lowering.

Moreover, the efficiency of all the breakers is increased.

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

1 to 6 show a relationship in which the piston 24 is operated by the cylinder body A of the conventional hydraulic breaker, and the configuration of the valve B1 and the accumulator C. FIG.

7 is a plan view showing the cylinder body (A) according to the configuration of the present invention, the connecting passage (9) and the hole (10) to secure the space according to the change of the formation direction of the inlet hole (1) and the return hole (8) It shows the state that can design large size.

That is, the cylinder body (A) has the piston 24 and the chisel (25) installed in the same line, the accumulator (C) and the hydraulic passage control valve housing to compensate for insufficient oil during hydraulic pulsation reduction and piston lowering (B) is provided in the one side, respectively.

In the cylinder body (A), the hydraulic inlet hole (1), the return hole (8) and the discharge hole (2) are respectively installed in communication with the valve housing (B), the inlet hole (1) and the return hole (8) The connecting passages (9) and (10) are installed across each, and when the high pressure oil is acted into the cylinder body (A) through the inlet hole (1), the piston (24) is raised and the high pressure by the operation of the valve (B1) The high pressure oil is applied to the upper end space 'X' of the piston along with the gas pressure of the gas chamber 16 compressed by the rise of the piston 24 by changing the flow of the oil, so that the piston 24 descends quickly. The pressure exerted on the space 'X' drops.

At this time, according to the revolving performance of the high pressure oil which is located at the lower end 'Y' side of the piston 24, the high pressure oil resistance is decreased, thereby increasing the descending speed of the piston 24 and consequently increasing the hitting force of the chisel 25. will be.

In the present invention, the entry direction of the inlet hole (1) formed in the cylinder body (A) and the entry direction of the return hole (8) is characterized in that the configuration opposite to each other alternately as shown in FIG.

Therefore, since the installation positions of the return hole 8 and the hole 15 are formed at different positions without overlapping with each other, the size of the return hole 8 and the hole 15 can be largely designed, so that the pressure is reduced when returning to the upper end of the piston of the high pressure oil according to the descending of the piston 24. By reducing the part, the breaker piston speed can be increased.

Meanwhile, as shown in FIG. 9, it is preferable to form another plurality of return holes 8 ′ and holes 15 ′ in parallel on one side of the return hole 8 and the hole 15.

In this case, another connection passage 9 'is formed in the return hole 8' formed side by side on the same side as the connection passage 9 drilled in the return hole 8.

As a result, a plurality of return holes 8, 8 ', connecting passages 9, 9', and holes 15, 15 'are respectively formed, thereby doubling the hydraulic displacement capacity, thereby greatly improving the overall hydraulic efficiency. It can be.

Therefore, the breaker strike energy is improved.

According to the configuration of the present invention as described above, by increasing the size of the return hole (8) and the hole (15) to increase the moving speed of the high pressure oil to reduce the hydraulic resistance when the piston descends to increase the impact force of the chisel by the rapid piston down. You can.

It is also a very useful design such that the efficiency of the entire breaker is increased.

Claims (2)

A valve housing (B) having a valve (B1) for distributing oil pressure; The inlet hole (1), the return hole (8) and the outlet hole (2) of the external hydraulic pressure are respectively installed in communication with the valve housing (B), the connecting passage (9) in the inlet hole (1) and the return hole (8) A cylinder body A each of which is formed across the 10; The back head configured to fill the gas chamber 16 with the gas pressure in the head-side space of the piston 24; The entry direction of the inlet hole (1) formed in the cylinder body (A) and the entry direction of the return hole (8) are alternately formed so that the size of the return hole (8) and the hole (15) can be designed large Hydraulic breaker, characterized in that. The method of claim 1, wherein the return hole 8 and the hole 15 and the plurality of return holes 8 ', the hole 15' and the connection passage 9 'are parallel to one side. Hydraulic breaker, characterized in that the plurality is formed in parallel.