CN112780624A - Reversing valve structure of hydraulic breaking hammer - Google Patents

Abstract

The invention provides a reversing valve structure of a hydraulic breaking hammer, and belongs to the technical field of breaking hammers. It has solved the problem of current well cylinder body cavitation. This switching-over valve structure of hydraulic breaking hammer, which comprises a valve body, the case of setting in the valve body and the switching-over valve of slip setting between valve body and case, the switching-over chamber has been seted up along the circumference of valve body to the inner peripheral surface of valve body, high-pressure chamber and low pressure chamber, high-low pressure switching chamber has in the case, the oilhole one in intercommunication high-low pressure switching chamber is seted up at the middle part of case, the switching-over valve has the oilhole two that can communicate high-pressure chamber and oilhole one, can communicate low-pressure chamber and oilhole three of oilhole one, the position that the inner peripheral surface of switching-over valve is located oilhole two and oilhole three has the shutoff portion, when the shutoff portion remove to just to the time with oilhole one, this switching-over valve structure is still including the oily structure of intercommunication high-pressure chamber and. The structure solves the problem of cavitation of the middle cylinder body.

Description

Reversing valve structure of hydraulic breaking hammer

Technical Field

The invention belongs to the technical field of breaking hammers, and particularly relates to a reversing valve structure of a hydraulic breaking hammer.

Background

The hydraulic breaking hammer is a high-efficiency breaking machine tool for converting hydraulic energy into mechanical impact energy, can effectively expand the function of a host machine serving as bearing equipment, and is widely applied to railways, roads, mines, water conservancy projects, national defense projects and municipal construction projects. The breaking hammer comprises a front cylinder body, a middle cylinder body, a rear cylinder body, a drill rod, a piston, an energy accumulator and a reversing valve, wherein the reversing valve is mainly used for changing the flow direction of hydraulic oil, so that the piston can reciprocate up and down to strike the drill rod, and the breaking function is realized.

As shown in fig. 1, a front oil chamber 100, a high-low pressure conversion chamber 101 and a rear oil chamber 103 are sequentially arranged in a middle cylinder body 1 from left to right, a reversing valve assembly comprises a valve body 2 fixed on the top surface of the middle cylinder body 1, a valve core 3 arranged in the valve body 2, and a reversing valve 4 arranged between the valve core 3 and the valve body 2, one end of the valve body 2 is connected with a valve cover 5, the inner circumferential surface of the valve body 2 is provided with a reversing chamber 200, a high pressure chamber 201 and a low pressure chamber 102 along the circumferential direction of the valve body 2, the reversing chamber 200, the high pressure chamber 201 and the low pressure chamber 102 are sequentially arranged at intervals from left to right, the valve core 3 is internally provided with a high-low pressure switching chamber 300, the middle part of the valve core 3 is provided with an oil hole one 301 communicated with the high-low pressure switching chamber 300, the reversing valve 4 is provided with an oil hole two 400 communicated with the high pressure chamber 201, the rear oil cavity 103 is communicated with a high-pressure cavity 201, the high-low pressure conversion cavity 101 is communicated with a reversing cavity 200, and the front oil cavity 100 is communicated with an oil hole four 203. The working principle of the hydraulic breaking hammer is as follows:

and a return acceleration stage: when the return stroke of the piston 6 is started, the last impact of the piston 6 is finished, and the piston 6 is in an instant pause state, at the moment, the pressure of hydraulic oil in the low-pressure cavity 102 is far greater than that of hydraulic oil in the reversing cavity 200, the left end of the reversing valve 4 abuts against the left end of the valve body 2, the front oil cavity 100 is communicated with the high-pressure cavity 201, the rear oil cavity 103 is always communicated with the high-low pressure switching cavity 300 through an oil hole four 203, the rear oil cavity 103 is low-pressure, the piston 6 does return stroke accelerated motion under the action of the high-pressure oil in the front oil cavity 100, and meanwhile, the piston 6;

and (3) return braking movement: the piston 6 continues to move back under the action of high-pressure oil in the front oil cavity 100, when the lower side surface of the middle section of the piston 6 crosses the left side wall of the high-low pressure conversion cavity 101, the high-pressure oil in the front oil cavity 100 enters the reversing cavity 200, the pressure of the hydraulic oil in the reversing cavity 200 is greater than that of the hydraulic oil in the low-pressure cavity 102, the hydraulic oil in the reversing cavity 200 pushes the reversing valve 4 to move towards the right, the high-pressure oil entering the front oil cavity 100 is gradually reduced in the process that the reversing valve 4 moves towards the right, the return thrust acting on the piston 6 is also gradually reduced, the return resistance exerted by relatively compressed nitrogen is increasingly large, the piston 6 is switched to a return braking stage, the reversing valve 4 finally cuts off the hydraulic oil entering the front oil cavity 100, and the piston 6 stops return movement quickly;

a stroke acceleration stage: when the piston 6 stops the return stroke movement, the piston immediately shifts to a stroke movement stage, at the moment, the front oil cavity 100 is communicated with the high-low pressure switching cavity 300 through the high pressure cavity 201, the oil hole II 400 and the oil hole I301, hydraulic oil in the front oil cavity 100 can enter the high-low pressure switching cavity 300 through the high pressure cavity 201, the oil hole II 400 and the oil hole I301, the piston 6 starts the rapid stroke movement under the action of nitrogen, and the reversing valve 4 stays at the rightmost position when the piston 6 makes the stroke movement;

the special state is as follows: the piston 6 strikes the pause state, under the effect of nitrogen gas adiabatic expansion in nitrogen chamber, the piston 6 makes equal accelerated motion, when the side passes the right side wall of high low pressure conversion chamber 101 on the piston 6 middle section, high pressure chamber 201 is linked together with the oil return passageway of quartering hammer, the oil pressure in high pressure chamber 201 diminishes, the oil pressure in low pressure chamber 102 is greater than the oil pressure in high pressure chamber 201, switching-over valve 4 moves left, piston 6 has obtained enough energy at this moment and strikes the drill rod, accomplish the impact action, when switching-over valve 4 moved to extreme position left, piston 6 is in the pause state in the twinkling of an eye, piston 6 finishes a duty cycle, rebound after piston 6 strikes afterwards, begin next duty cycle.

In the return braking movement stage of the piston 6, the hydraulic oil in the rear oil chamber 103 flows back to the high-low pressure switching chamber 300, and supplies oil to the front oil chamber 100 through the oil hole two 400, the oil hole one 301 and the high pressure chamber 201, or the hydraulic oil in the high-low pressure switching chamber 300 flows to the low pressure chamber 102 through the oil hole one 301 and the oil hole three 401, the reversing valve 4 is located at the extreme position on the left side and moves to the right from the extreme position, the distance between the oil hole two 400 and the oil hole three 401 in the conventional reversing valve 4 is greater than the axial length of the oil hole one 301 along the reversing valve 4, therefore, at a certain moment, the oil hole one 301 is completely blocked by the position between the oil hole two 400 and the oil hole three 401 in the reversing valve 4, so that the high-low pressure switching chamber 300 is completely isolated from the high pressure chamber 201 and the low pressure chamber 102, and the hydraulic oil in the rear oil chamber 103 flows back to the, so that the screw of the valve cap 5 is easily broken and the screw rod of the accumulator communicated with the high-low pressure switching chamber 300 is also easily broken.

In a special state stage of the piston 6, hydraulic oil in the front oil cavity 100 flows back to the high-low pressure switching cavity 300 through the high-pressure cavity 201, the oil hole two 400 and the oil hole one 301, oil is supplemented to the rear oil cavity 103, the distance between the oil hole two 400 and the oil hole three 401 in the reversing valve 4 is larger than the axial length of the oil hole one 301 along the reversing valve 4 in the process that the reversing valve 4 is located at the extreme position on the right side and moves leftwards from the extreme position, therefore, at a certain moment, the oil hole one 301 is completely blocked at the position between the oil hole two 400 and the oil hole three 401 in the reversing valve 4, so that the hydraulic oil in the front oil cavity 100 and the hydraulic oil in the low-pressure cavity 102 cannot enter the high-low pressure switching cavity 300, the oil in the rear oil cavity 103 cannot be supplemented timely, the oil pressure in the rear oil cavity 103 is insufficient, the piston 6 continues to stroke movement, the hydraulic oil between the middle part of the outer peripheral surface of the piston 6, and cavitation is generated in the middle of the outer peripheral surface of the piston 6, although the time for completely closing the oil hole I301 is very short, the piston 6 moves for a certain stroke in the time period due to the high moving speed of the piston 6, cavitation is generated on the inner wall of the middle cylinder body, the area of the cavitation distributed on the inner wall of the middle cylinder body is the moving distance of the piston 6 in the time period, and the middle cylinder body is easy to be scratched and damaged.

Disclosure of Invention

The invention aims to solve the problems in the prior art, and provides a reversing valve structure of a hydraulic breaking hammer, which aims to solve the technical problems that: how to solve the problem of cylinder body cavitation.

The purpose of the invention can be realized by the following technical scheme:

a reversing valve structure of a hydraulic breaking hammer comprises a valve body, a valve core and a reversing valve, wherein the valve core is arranged in the valve body, the reversing valve is arranged between the valve body and the valve core in a sliding mode, a reversing cavity, a high-pressure cavity and a low-pressure cavity are formed in the inner peripheral surface of the valve body along the circumferential direction of the valve body, a high-pressure switching cavity and a low-pressure switching cavity are formed in the valve core, a first oil hole communicated with the high-pressure switching cavity is formed in the middle of the valve core, the reversing valve is provided with a second oil hole communicated with the first oil hole and a third oil hole communicated with the low-pressure cavity and the first oil hole, and a blocking portion is arranged at a position, between the second oil hole and the third oil hole, of the inner peripheral surface of the reversing valve.

In the return braking movement stage of the piston, hydraulic oil in an oil cavity behind the breaking hammer flows back to a high-low pressure switching cavity, oil is supplemented to an oil cavity in front of the breaking hammer through an oil hole II, an oil hole I and a high-pressure cavity, or hydraulic oil in the high-low pressure switching cavity flows to a low-pressure cavity through the oil hole I and the oil hole I, a reversing valve is located at the limit position on the left side and moves rightwards from the limit position, at a certain moment, a blocking part moves to be opposite to the oil hole I, at the moment, the high-low pressure switching cavity is communicated with the high-pressure cavity or/and the low-pressure cavity through an oil passing structure, the high-low pressure switching cavity is communicated with the high-pressure cavity or/and the low-pressure cavity, the hydraulic oil in the high-low pressure switching cavity flows into the high-pressure cavity or/and the high-low pressure switching cavity through the oil hole I, the oil hole III and the oil passing structure, and the situation that the hydraulic, the problem of hydraulic pressure impact force lead to the fact the screw of valve gap and the screw of energy storage ware to cause the breaking is solved.

In the return stage of the piston, hydraulic oil in the front oil cavity of the breaking hammer flows back to the high-low pressure switching cavity through the high-pressure cavity, the oil hole II and the oil hole I and supplies oil to the rear oil cavity, the reversing valve is located at the limit position on the right side and moves leftwards from the limit position, at a certain moment, the blocking part moves to be opposite to the oil hole I, at the moment, the high-pressure cavity is communicated with the oil hole I or/and the low-pressure cavity is communicated with the high-pressure cavity or/and the low-pressure cavity through the oil passing structure, so that the high-low pressure switching cavity is communicated with the high-pressure cavity or/and the low-pressure cavity, the hydraulic oil in the front oil cavity of the breaking hammer enters the high-low pressure switching cavity or/and the low-pressure switching cavity through the high-pressure cavity, the oil passing structure, the oil hole I and the high-low pressure switching cavity, the hydraulic oil in the high-low pressure switching cavity flows, the cavitation erosion of the inner wall of the middle cylinder body caused by insufficient oil pressure in the oil cavity behind the breaking hammer is avoided, and the service life of the middle cylinder body is prolonged.

In the above reversing valve structure of the hydraulic breaking hammer, when the blocking portion moves to be opposite to the first oil hole, the oil passing structure includes that the front side of the blocking portion is provided with a first oil passing gap for communicating the high-pressure chamber with the first oil hole or/and the rear side of the blocking portion is provided with a second oil passing gap for communicating the low-pressure chamber with the first oil hole. Through the arrangement of the structure, when the blocking part moves to the position opposite to the oil hole I, the high-pressure cavity is communicated with the oil hole I through the oil passing gap I, and the low-pressure cavity is communicated with the oil hole I through the oil passing gap II.

In the reversing valve structure of the hydraulic breaking hammer, the outer peripheral surface of the valve core is provided with an annular groove, the first oil hole is formed in the bottom surface of the groove, and when the blocking part moves to be opposite to the first oil hole, the first oil passing gap is communicated with the high-pressure cavity and the groove or/and the second oil passing gap is communicated with the low-pressure cavity and the groove.

In the above reversing valve structure of the hydraulic breaking hammer, the width of the groove along the axial direction of the valve core is greater than the width of the blocking part along the axial direction of the valve core.

In the reversing valve structure of the hydraulic breaking hammer, the inner edges of the front side and the rear side of the blocking part are provided with the notches to form the first oil passing gap and the second oil passing gap.

In the reversing valve structure of the hydraulic breaking hammer, the reversing valve structure further comprises a valve cover fixed on the valve body, the valve cover is provided with a positioning sleeve located in the valve body, one end of the valve core abuts against the inner wall of the valve body, one end of the positioning sleeve abuts against the other end of the valve core, the outer peripheral surface of the positioning sleeve is provided with a fourth oil hole, and the side wall of the valve body is provided with a fifth oil hole communicated with the fourth oil hole.

Compared with the prior art, the reversing valve structure of the hydraulic breaking hammer has the following advantages:

1. the reversing valve is located at the left limit position and moves rightwards from the left limit position, at a certain moment, the blocking part moves to be arranged opposite to the oil hole I, the front side of the blocking part is provided with an oil passing gap I communicated with the high-pressure cavity and the oil hole I, the rear side of the blocking part is provided with an oil passing gap II communicated with the low-pressure cavity and the oil hole I, so that the high-pressure and low-pressure switching cavity is communicated with the high-pressure cavity and the low-pressure cavity, hydraulic oil in the high-pressure and low-pressure switching cavity flows into the high-pressure cavity through the oil hole I, the oil hole II and the oil passing gap I, hydraulic oil in the high-pressure and low-pressure switching cavity flows into the low-pressure cavity through the oil hole I, the oil hole III and the oil passing gap II, the situation that the hydraulic oil in the oil cavity behind the breaking hammer flows back to the high;

2. the reversing valve is positioned at the limit position on the right side, and in the process of moving leftwards from the limit position, at a certain moment, the blocking part moves to be arranged opposite to the oil hole I, the front side of the blocking part is provided with an oil passing gap I communicated with the high-pressure cavity and the oil hole I, the rear side of the blocking part is provided with an oil passing gap II communicated with the low-pressure cavity and the oil hole I, so that the high-pressure and low-pressure switching cavity is communicated with the high-pressure cavity and the low-pressure cavity, hydraulic oil in the front oil cavity of the breaking hammer enters the high-pressure and low-pressure switching cavity through the high-pressure cavity, the oil passing gap I, the oil hole II and the oil hole I, hydraulic oil in the low-pressure cavity enters the high-pressure and low-pressure switching cavity through the oil hole III, the oil passing gap II and the oil hole I, hydraulic oil in the high-pressure and low-pressure switching cavity flows into the rear, the risk of piston galling is reduced, the life of piston has been improved.

Drawings

Fig. 1 is a schematic sectional view of a conventional breaking hammer.

Fig. 2 is a schematic cross-sectional view of a diverter valve structure according to the present invention.

Fig. 3 is an enlarged schematic view of a portion a in fig. 2.

In the figure, 1, a valve body; 10. a commutation cavity; 11. a high pressure chamber; 12. a low pressure chamber; 13. an oil hole five; 2. a valve core; 20. a high-low pressure switching cavity; 21. a first oil hole; 22. a groove; 3. a diverter valve; 30. An oil hole II; 31. an oil hole III; 32. a plugging section; 4. a first oil passing gap; 5. a second oil passing gap; 6. a valve cover; 60. a positioning sleeve; 60a and an oil hole IV; 7. and (4) a notch.

Detailed Description

The following are specific embodiments of the present invention and are further described with reference to the drawings, but the present invention is not limited to these embodiments.

Example 1

As shown in fig. 2 and 3, the reversing valve structure of the hydraulic hammer comprises a valve body 1, a valve core 2 arranged in the valve body 1, and a reversing valve 3 arranged between the valve body 1 and the valve core 2 in a sliding manner, wherein a reversing cavity 10, a high-pressure cavity 11 and a low-pressure cavity 12 are arranged on the inner peripheral surface of the valve body 1 along the upper direction, a high-pressure and low-pressure switching cavity 20 is arranged in the valve core 2, an oil hole I21 communicated with the high-pressure and low-pressure switching cavity 20 is arranged in the middle of the valve core 2, the reversing valve 3 is provided with an oil hole II 30 capable of communicating the high-pressure cavity 11 with the oil hole I21, and an oil hole III 31 capable of communicating the low-pressure cavity 12 with the oil hole I21, a blocking part 32 is arranged at a position between the oil hole II 30 and the, when the blocking part 32 moves to be aligned with the first oil hole 21, the reversing valve structure further comprises an oil passing structure for communicating the high pressure cavity 11 with the first oil hole 21 or/and communicating the low pressure cavity 12 with the first oil hole 21. In this embodiment, the oil passing structure includes that the front side of the blocking portion 32 has an oil passing gap one 4 communicating the high pressure chamber 11 and the oil hole one 21, the rear side of the blocking portion 32 has an oil passing gap two 5 communicating the low pressure chamber 12 and the oil hole one 21, and the inner edges of the front side and the rear side of the blocking portion 32 are both provided with notches 7 to form the oil passing gap one 4 and the oil passing gap two 5.

As shown in fig. 2 and fig. 3, the reversing valve 3 further includes a valve cover 6 fixed on the valve body 1, the valve cover 6 has a positioning sleeve 60 located in the valve body 1, one end of the valve core 2 abuts against the inner wall of the valve body 1, one end of the positioning sleeve 60 abuts against the other end of the valve core 2, an oil hole four 60a is formed in the outer peripheral surface of the positioning sleeve 60, and an oil hole five 13 communicated with the oil hole four 60a is formed in the side wall of the valve body 1.

The reversing valve structure is arranged on a hydraulic breaking hammer for use, in the return braking motion stage of a piston, hydraulic oil in an oil cavity behind the breaking hammer flows back to a high-low pressure switching cavity 20 through an oil hole five 13 and an oil hole four 60a, the hydraulic oil in the oil cavity in front of the breaking hammer is supplemented or the hydraulic oil in the high-low pressure switching cavity 20 flows to a low pressure cavity 12 through an oil hole one 21 and an oil hole three 31 through an oil hole two 30, an oil hole one 21 and a high pressure cavity 11, the reversing valve 3 is located at the limit position on the left side and moves rightwards from the limit position, at a certain moment, a blocking part 32 moves to be opposite to the oil hole one 21, an oil passing gap one 4 communicating the high pressure cavity 11 with the oil hole one 21 is arranged on the front side of the blocking part 32, an oil passing gap two 5 communicating the low pressure cavity 12 with the oil hole one 21 is arranged on the rear side of the blocking part 32, so that the high, hydraulic oil in the high-low pressure switching cavity 20 flows into the high-pressure cavity 11 through the first oil hole 21, the second oil hole 30 and the first oil passing gap 4, hydraulic oil in the high-low pressure switching cavity 20 also flows into the low-pressure cavity 12 through the first oil hole 21, the third oil hole 31 and the second oil passing gap 5, the situation that the hydraulic oil in the oil cavity behind the breaking hammer flows back to the high-low pressure switching cavity 20 and can go anywhere is avoided, and the problem that hydraulic impact force causes the breakage of screws of the valve cover 6 and screws of the energy accumulator is solved.

In the stroke stage of the piston, hydraulic oil in the front oil cavity of the breaking hammer flows back into the high-low pressure switching cavity 20 through the high-pressure cavity 11, the oil hole II 30 and the oil hole I21 and supplies oil to the rear oil cavity of the breaking hammer, the reversing valve 3 is located at the limit position on the right side and moves leftwards from the limit position, at a certain moment, the blocking part 32 moves to be opposite to the oil hole I21, the oil passing gap I4 communicated with the high-pressure cavity 11 and the oil hole I21 is formed in the front side of the blocking part 32, the oil passing gap II 5 communicated with the low-pressure cavity 12 and the oil hole I21 is formed in the rear side of the blocking part 32, the high-low pressure switching cavity 20 is communicated with the high-pressure cavity 11 and the low-pressure cavity 12, the hydraulic oil in the front oil cavity of the breaking hammer enters the high-low pressure switching cavity 20 through the high-pressure cavity 11, the oil passing gap I4, the oil hole II 30 and the oil hole I21, the oil passing gap II 5 and the oil hole I21 enter the high-low pressure switching cavity 20, hydraulic oil in the high-low pressure switching cavity 20 flows into the rear oil cavity of the breaking hammer, sufficient oil supply for the rear oil cavity of the breaking hammer is guaranteed, cavitation erosion of the inner wall of the middle cylinder body caused by insufficient oil pressure in the rear oil cavity of the breaking hammer is avoided, and the service life of the middle cylinder body is prolonged.

Example 2

This embodiment is substantially the same as embodiment 1 described above, except that: in this embodiment, an annular groove 22 is formed in the outer peripheral surface of the valve element 2, the first oil hole 21 is formed in the bottom surface of the groove 22, when the blocking portion 32 moves to be opposite to the first oil hole 21, the first oil passing gap 4 communicates the high pressure chamber 11 with the groove 22, the second oil passing gap 5 communicates the low pressure chamber 12 with the groove 22, and the width of the groove 22 in the axial direction of the valve element 2 is greater than the width of the blocking portion 32 in the axial direction of the valve element 2.

Example 3

This embodiment is substantially the same as embodiment 1 described above, except that: in this embodiment, the outer side wall of the valve core 2 is radially provided with a first through hole and a second through hole, when the blocking portion 32 moves to be aligned with the first oil hole 21, the first through hole communicates the high pressure chamber 11 with the first oil hole 21, and the second through hole communicates the low pressure chamber 12 with the first oil hole 21.

Example 4

This embodiment is substantially the same as embodiment 1 described above, except that: in this embodiment, the outer side wall of the valve core 2 is radially provided with a first through hole, and when the blocking portion 32 moves to be aligned with the first oil hole 21, the first through hole communicates with the high pressure chamber 11 and the first oil hole 21.

Example 5

This embodiment is substantially the same as embodiment 1 described above, except that: in this embodiment, a first through hole is radially formed in the outer side wall of the valve core 2, and the first through hole communicates the low pressure chamber 12 and the first oil hole 21.

The specific embodiments described herein are merely illustrative of the spirit of the invention. Various modifications or additions may be made to the described embodiments or alternatives may be employed by those skilled in the art without departing from the spirit or ambit of the invention as defined in the appended claims.

Claims (6)

1. A reversing valve structure of a hydraulic breaking hammer comprises a valve body (1), a valve core (2) arranged in the valve body (1) and a reversing valve (3) arranged between the valve body (1) and the valve core (2) in a sliding mode, wherein a reversing cavity (10), a high-pressure cavity (11) and a low-pressure cavity (12) are formed in the upper edge of the inner circumferential surface of the valve body (1), a high-pressure and low-pressure switching cavity (20) is formed in the valve core (2), an oil hole I (21) communicated with the high-pressure and low-pressure switching cavity (20) is formed in the middle of the valve core (2), the reversing valve (3) is provided with an oil hole II (30) capable of communicating the high-pressure cavity (11) with the oil hole I (21) and an oil hole III (31) capable of communicating the low-pressure cavity (12) with the oil hole I (21), and a blocking portion (32) is arranged at a position, between the oil hole II (, the reversing valve structure is characterized by further comprising an oil passing structure for communicating the high-pressure cavity (11) with the first oil hole (21) or/and communicating the low-pressure cavity (12) with the first oil hole (21) when the blocking part (32) moves to be aligned with the first oil hole (21).

2. The structure of a change valve (3) of a hydraulic breaker according to claim 1, wherein when the block portion (32) is moved to be opposed to the first oil hole (21), the oil passing structure includes that the front side of the block portion (32) has an oil passing clearance one (4) for communicating the high pressure chamber (11) with the first oil hole (21) or/and the rear side of the block portion (32) has an oil passing clearance two (5) for communicating the low pressure chamber (12) with the first oil hole (21).

3. The structure of the reversing valve (3) of the hydraulic breaking hammer as claimed in claim 2, wherein the valve core (2) is provided with an annular groove (22) on the outer peripheral surface, the first oil hole (21) is formed on the bottom surface of the groove (22), and when the blocking portion (32) moves to be opposite to the first oil hole (21), the first oil passing gap (4) is communicated with the high pressure cavity (11) and the groove (22) or/and the second oil passing gap (5) is communicated with the low pressure cavity (12) and the groove (22).

4. A structure of a direction valve (3) of a hydraulic breaker according to claim 3 wherein the width of the groove (22) in the axial direction of the spool (2) is larger than the width of the blocking portion (32) in the axial direction of the spool (2).

5. The structure of the reversing valve (3) of the hydraulic breaking hammer as claimed in claim 2 or 3, characterized in that the inner edges of the front and rear sides of the blocking part (32) are provided with notches (7) to form the first oil passing gap (4) and the second oil passing gap (5).

6. The structure of the reversing valve (3) of the hydraulic breaking hammer as claimed in claim 1, wherein the structure of the reversing valve (3) further comprises a valve cover (6) fixed on the valve body (1), the valve cover (6) is provided with a positioning sleeve (60) positioned in the valve body (1), one end of the valve core (2) abuts against the inner wall of the valve body (1), one end of the positioning sleeve (60) abuts against the other end of the valve core (2), the outer peripheral surface of the positioning sleeve (60) is provided with a fourth oil hole (60a), and the side wall of the valve body (1) is provided with a fifth oil hole (13) communicated with the fourth oil hole (60 a).

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