KR200331848Y1 - hammer bit hitting apparatus for digging - Google Patents

Abstract

The present invention relates to a hammer bit striking device for drilling, the air distributor has a check valve coupled to the top of the center by a spring and has a plurality of inlet pipes in the upper periphery and close contact with the inner surface of the sleeve pipe at the top It has a bottom portion is in close contact with the upper surface of the upper part of the upper part of the sleeve has a spring seating portion and the lower part is in close contact with the inner cylinder of the cylinder, and the upper part of the heme bit of the sleeve tube inner side has a locking projection protruding inward to the outside of the lower projection Ascending hole is formed, the outer circumferential surface of six directions in a cylindrical shape has a plurality of hollow parts long cut inwardly up and down direction, has a plurality of descending overheads in the upper part, has a plurality of descending hollows in the center, Inner side of the sleeve tube inside the sleeve tube is fixed in close contact with the lower protrusion of the air distributor and the body The stage forms a cylinder which is fixed to the upper side of the locking projection, and the piston has a through hole at the center side, and when the cylinder descends from the upper portion of the cylinder, the lower induction seal guides the external pneumatic pressure introduced through the lower hollow to the upper end of the piston and the air distributor. It is configured by forming a rising induction guide that guides the external air pressure introduced through the rising and lowering hole in the cylinder lower portion between the piston bottom and the upper end of the hammer bit through the rising hole of the sleeve.

Description

Hammer bit hitting apparatus for digging}

The present invention relates to a hammer hammer hitting device for drilling, and more particularly, it is not necessary to guide the piston guides when the blow hitting the hammer bit on the entire surface of the lower end of the piston, the impact force is very good and the air distributor needs to be formed long The present invention relates to a drilling hammer bit hitting device which is structurally solid and strong and has a long service life.

In general, boring is the drilling of small diameter holes in the earth's crust to understand the structure and properties of the strata, to gain knowledge of the interior of the earth's crust, or to oil, natural gas, hot springs, and groundwater. It is made to collect the back. According to the excavation method, there is a shock type that impacts the bit and breaks the rock and drills it, and a rotary type that drills by rotating the bit inserted with diamond and cemented carbide at the end of the steel pipe (pipe) with respect to the rock surface.

Excavation hammer bits used for such drilling are to use hammer bits of different specifications and structures according to the purpose or the conditions of the geological (geological) bar, the type of hammer bits for direct digging and indirect digging It is roughly divided into bits. The hammer bit for the direct excavation method is used in a manner in which the state of the ground layer is good or does not drill deeply, and the ground layer is excavated while the bit housing mounted on the hammer drill rotates without using a steel tube. The hammer bit for indirect digging method is used in the method of drilling while embedding the steel pipe in the drilling hole, and after the bit housing and the bit mounted on the hammer drill drill a hole wider than the diameter of the steel pipe, It is taken out.

The indirect digging hammer drill increases the pressure as it goes deep into the ground, and the load caused by a lot of energy interferes with the hammer bit, making the digging work difficult. In addition, the hammer bit that needs to excavate a hole wider than the diameter of the steel tube being buried is that the steel tube is embedded at the same time as the amount of excavation, and if the hole is not widely excavated to easily enter the steel tube, Not only becomes difficult to bury, but also takes a lot of load during excavation, which causes breakage of the hammer bit, and it becomes very difficult to remove the hammer bit after excavation.

Therefore, in the art, many products have been developed in order to supply a product capable of performing rapid excavation work as well as supplying a stronger hammer bit, and thus, eccentric rotation type and open type products have been known. The open type product is a structure in which two or three multi-drive hammer bits are open on the bottom of the bit housing, which is structurally so apart from the bits that the support part supporting the bits is excluded. There is a problem that the expensive excavation work because the problem occurs, such as broken even in small shocks do not fulfill the function of.

The price of these hammer bits varies greatly depending on the type and specification of the product, but indirect drilling hammer bits are expensive products that cost at least 5 million won to 30 million won for each bit, so every time you drill one borehole Core supervision will be carried out carefully excavation work. If a bit breakage problem occurs during work, the impact is directly related to the cost of construction.

7a to 7c have been proposed to improve the structure of the hammer bit and to improve the hammer bit striking to solve this problem, the configuration is a bag formed with the inlet hole 192 through which a pneumatic pressure of a constant pressure is introduced into the center The head 190 and the check valve 180 which is located at the lower end of the inlet hole 192 to prevent the inlet air pressure flows back to the inlet hole 192 of the back head 190, and the back head inside the upper end The lower end of the 190 is coupled to the lower end of the sleeve tube 120 is a long tube body is coupled to the lower end of the hammer bit 150 fixed by the chuck 174 slidably, and the hammer inside the sleeve tube 120 The lifting hole 111 is positioned at the upper side of the bit 150 and fitted into the air distributor 130 to be reciprocated in the sleeve tube 120 and described later. ) And the outside air supplied to the air distributor 130 to the upper side of the body To lower down the induction hole 112 is formed and the other side of the lower body through the operating hole 131 and the rising induction hole 114 is formed to flow the external air to the lower side of the body is formed in the sleeve tube 120 A piston 110 is formed at the bottom of the body protruding downward and strikes the hammer bit 150 downward, and is located between the hammer bit 150 and the piston 110 above the hammer bit 150. Guide pipe 160 for guiding the lowering of the striking rod 116 within the sleeve tube 120 when the hammer 110 hits the upper end of the hammer rod 116 of the piston 110, the upper sleeve tube 120 It is located between the piston 110 and the back head 190 in a sealed state in the upper side and the center side is protruded to the lower side of the operation that the air pressure introduced into the inlet hole 192 of the back head 190 is ejected A hole 151 is formed to properly distribute the external air pressure to the induction hole 112 and the induction hole 114 by the piston 11 An operating hole 131 hitting the hammer bit 150 by reciprocating up and down 0) was formed of an “T” shaped air distributor 130 formed below.

However, such a conventional drilling hammer bit striking device requires a guide tube 16 protruding the striking rod 116 in the lower portion to guide the striking rod 116 in the sleeve tube 120, hammer bit 150 ), The impact force of the piston 110 is weak, and the operating hole 131 of the air distributor 130 which distributes the external air pressure when the piston 110 descends, is raised and lowered when the piston 110 descends. Since it should be formed to protrude in the lower portion long to the guide hole 114 and the position penetrated, the structural strength is weak and there is a structural problem that the service life is not long.

The present invention is to solve the conventional problems as described above, do not need a guide tube for guiding the piston at the time of hitting the hammer bit on the entire surface of the lower end of the piston, the impact force is very excellent, there is no need to lengthen the air distributor The object of the present invention is to provide a drilling hammer bit hitting device that is structurally robust and strong, thus extending its service life.

In order to achieve the above object, the present invention has a back head formed with an inlet hole through which a constant pressure of pneumatic pressure flows in the center, and a check valve which is located at the lower end of the inlet hole to prevent the inlet air pressure from leaking back into the inlet hole of the back head. And, inside the upper end, the lower end portion of the back head is hermetically coupled, and the lower inner side is fixed by the chuck, the sleeve tube is a long tube with a hammer bit located inside, and the upper and lower reciprocating movements are located above the hammer bit inside the sleeve tube. Excavation hammer having a piston hitting the hammer bit, and an air distributor located between the piston inside the sleeve tube and the back head to distribute the pneumatic flow into the inlet hole of the back head to move the piston up and down to strike the hammer bit In a bit striking device;

The air distributor has a check valve coupled to the top of the center by a spring and has a plurality of inlet pipes at the upper periphery, a close upper protrusion that is in close contact with the inner side of the sleeve tube, and a spring seat at the upper face of the close upper protrusion. And the lower portion is formed in close contact with the bottom in close contact with the inner cylinder;

An upper portion of the hemmer bit of the inner side of the sleeve tube has a locking protrusion protruding inwardly and an upwardly elongated hole is formed outwardly of the lower locking protrusion;

The outer circumferential surface of six directions in a cylindrical shape has a plurality of hollow parts long cut in the inner up and down direction, has a plurality of descending overheads at the top, has a plurality of descending hollows at the center, and has a plurality of ascents at the bottom, The inner top of the body is tightly fixed to the close bottom protrusion of the air distributor and the bottom of the body forms a cylinder which is fixed to the upper side of the locking protrusion;

The piston has a through hole at the center side and has a downward induction hole that guides the external air pressure introduced through the descending hollow when descending from the upper cylinder between the upper end of the piston and the bottom of the air distributor, and has an external flow introduced through the rising hollow when rising from the lower cylinder. And a rise induction portion for inducing pneumatic pressure between the lower end of the piston and the upper end of the hammer bit through the rising hole of the sleeve tube.

The cylinder has a plurality of hollows formed in a cylindrical shape in the up and down direction, having a plurality of descending holes at the top and a plurality of descending holes at the center and a plurality of rising holes at the bottom, and are formed only from the inner side of the body to the hollow part, the sleeve Inside the tube, the upper end of the body is fixed in close contact with the lower protrusion of the air distributor and the lower end of the body may be formed to be fixed to the upper locking projection.

1 is an exploded perspective view showing a separation state of the present invention embodiment,

Figure 2a is a front view showing a state of the cylinder of the present invention,

2B is a side view of FIG. 2A,

2C is a cross-sectional view taken along the line S-S 'of FIG. 2A;

Figure 2d is a side cross-sectional view of a cylinder of the present invention,

Figure 3a is a front view showing a state of the piston which is an embodiment of the present invention,

3B is a left side view of FIG. 3A;

3C is a side cross-sectional view of FIG. 3A,

Figure 4a is a sectional side view of the operating state showing the pneumatic flow when the piston descends in the embodiment of the present invention,

Figure 4b is a sectional side view of the operating state showing the pneumatic flow when the piston rises in the embodiment of the present invention,

Figure 4c is a side view of the operating state showing the pneumatic flow of the piston no-load state of the present invention embodiment,

Figure 5a is a side cross-sectional view showing a state in which another embodiment of the subject innovation cylinder coupled to the inside of the sleeve tube,

5B is a side cross-sectional view of FIG. 5A;

Figure 6a is a sectional side view of the operating state showing the pneumatic flow when the piston descends in another embodiment of the present invention,

Figure 6b is a sectional side view of the operating state showing the pneumatic flow when the piston rises in another embodiment of the present invention,

Figure 6c is a side view of the operating state showing the pneumatic flow of the piston no-load state of another embodiment of the present invention,

Figure 7a is a sectional side view of the operating state showing the pneumatic flow when the piston descends of the conventional design,

Figure 7b is a sectional side view of the operating state showing the pneumatic flow when the piston rises of the conventional design,

Figure 7c is a side view of the operating state showing the pneumatic flow of the piston unloaded state of the prior art.

* Description of the symbols for the main parts of the drawings *

10: piston 11; Through

12: descent induction paint 14: ascending induction

20,20a: cylinder 21,21a: hollow part

22,22a: Downhill 23,23a: Downhill

24,24a: Ascending and descending 30: Air distributor

31: inlet hole 32; Close contact

33: spring mounting portion 34: close bottom protrusion

50: hammer bit 60: sleeve tube

61: jamming projection 62: climb

74: Chuck 80: Check Valve

81: spring 90: backhead

91: inflow hole

Hereinafter, the present invention in more detail by the accompanying drawings as follows.

Figure 1 is an exploded perspective view showing a separation state of the present invention embodiment, Figure 2a is a front view showing a state of the embodiment of the present invention, Figure 2b is a side view of Figure 2a, Figure 2c is a line S-S 'of Figure 2a. 2D is a side cross-sectional view of a cylinder according to an embodiment of the present invention, FIG. 3A is a front view showing a state of a piston according to the present invention, FIG. 3B is a left side view of FIG. 3A, and FIG. 3C is a side cross-sectional view of FIG. 3A. Figure 4a is a side cross-sectional view of the operating state showing the pneumatic flow when the piston descends in the embodiment of the present invention, Figure 4b is a side view of the operating state showing the pneumatic flow when the piston rises in the embodiment of the present invention, Figure 4c is a piston of the present invention embodiment Side view of the operating state showing no-load pneumatic flow.

Excavation hammer bit striking device of the present invention has a back head 90 is formed in the inlet hole 92 is a pneumatic pressure of a constant pressure in the center, and the pneumatic pressure introduced by being located at the lower end of the inlet hole 92 Check valve 80 to prevent the flow back to the inlet 92 of the 90, the upper end of the back head 90 is coupled to the lower end is sealed and fixed to the inner side by the chuck 74 inside The sleeve tube 60 is a long tube having a hammer bit 50 is positioned and has a locking projection 61 and a rising hole 62 in the lower portion, and the air distributor 30 and the sleeve tube inside the sleeve tube 60 ( 60) the cylindrical cylinder 20 fixed between the locking projections 61 in the lower portion, and the upper and lower reciprocating motion of the hammer bit (50) located inside the cylinder 20 inside the sleeve tube 60 inside the sleeve; Piston (10) striking 50, and the lower end is fixed to the inner periphery of the upper end of the cylinder 20 and the upper end is formed in the bottom of the back head (90) Distributes the air pressure flowing into the inlet hole 92 of the head 90 is composed of an air distributor (30) which vertically reciprocate the piston (10).

The sleeve tube 60 is an elongated tube body in which a hammer bit 50 is positioned. The sleeve tube 60 has a locking protrusion 61 protruding inward from an upper portion of the hammer bit 50 on an inner side thereof, and a lower portion of the locking protrusion 61. It has a rising field hole 62 formed to the outside, the lower end portion of the back head 90 is hermetically coupled to the upper inner side, it is fixed by the chuck 74 on the lower inner side.

The piston 10 has a through hole 11 at the center side, and the external air pressure introduced through the lowering hollow 23 when descending from the upper portion of the cylinder 20 is between the upper end of the piston 10 and the lower end of the air distributor 30. It has a downward induction coating hole 12, the external air pressure introduced through the rising hole 24 when rising from the lower cylinder 20, the lower end of the piston (10) through the rising hole 62 of the sleeve pipe (60) And has a rising induction portion 14 to guide between the upper end of the hammer bit 50, the upper and lower reciprocating motion in the cylinder 20 inside the sleeve tube 60, and strikes the hammer bit 50 strongly downward.

The air distributor 30 is located between the piston 10 inside the sleeve tube 60 and the back head 90 so that the check valve 80 is elastically coupled to the top center by the spring 81 and the upper periphery. It has a plurality of inlet pipe 31 in the upper portion has a close upper protrusion 32 is in close contact with the inner surface of the sleeve tube 60, the upper face has a spring seating portion 33 on the upper end 32 And, the lower portion is in close contact with the lower end of the cylinder (34) is in close contact with the inlet hole 34 is formed, and the pneumatic flow into the inlet hole 92 of the back head 90 by distributing the piston 10 up and down Hit the hammer bit (50).

The cylinder 20 has a plurality of hollow portions 21 having a plurality of hollow portions 21 whose outer circumferential surfaces in six directions are cut in an up-down direction in a cylindrical shape, and having a plurality of descending upper holes 22 therein, and a plurality of descending hollows 23 in the center thereof. ) And has a plurality of raised holes 24 at the bottom, and inside the sleeve tube 60 inside the upper end of the body is fixed in close contact with the lower protrusion 34 of the air distributor 30 and the lower end of the body is a locking projection 61 ) It is fixed on the upper side.

Referring to the use state of the present invention as follows.

As shown in FIG. 4A, when the external air pressure having a constant pressure is supplied through the inlet hole 92 of the back head 90, the external air pressure passes through the space between the back head 90 and the check valve 80. It passes through the hollow portion 21 formed between the outer periphery of the cylinder 20 and the inner periphery of the sleeve tube 60 through the inlet down hole 22 of the cylinder 20 through the inlet pipe hole 31 of the 30. .

The external air pressure passing through the hollow portion 21 passes through the downward induction hole 12 of the piston 10 located inside the cylinder 20 through the lowering hollow 23 of the cylinder 20 and the upper end of the piston 10 and air. Filled into the space between the bottom of the distributor 30 is filled.

The external air pressure filled in the space between the upper end of the piston 10 and the air distributor 30 pushes the piston 10 downward in the cylinder 20, and the piston 10 in the cylinder 20. Descends.

At this time, the residual air located between the lower end of the piston 10 and the sleeve tube 60, the upper end of the piston 10 and the lower end of the air distributor 30 inside the cylinder 20 through the through-hole 11 of the piston 10 It is discharged into the space between them.

As shown in FIG. 4B, the piston 10 lowered from the upper side to the lower side in the cylinder 20 passes through the inlet pipe 31 of the air distributor 30 and the descending upper hole 22 inside the cylinder 20. 20) Passes the hollow portion 21 between the outer circumference and the inner circumference of the sleeve tube 60.

The external air pressure passing through the hollow portion 21 is introduced into the cylinder 20 through the rising and lowering holes 24 in the lower portion of the cylinder 20, and the introduced external air pressure causes the rising induction portion 14 of the piston 10 to flow. After passing through the ascending hole 62 between the lower portion of the piston 10 and the sleeve tube 60 is introduced into the space between the lower end of the piston 10 and the upper end of the hammer bit 50 is filled.

External air pressure, which is filled between the hammer bit 50 and the piston 10 and has a constant pressure, raises the piston 10 upwardly in the sleeve tube 60 and inside the cylinder 20 to hammer the lower end of the piston 10. The upper surface of the bit 50 is separated from the upper end of the piston 10 and the air distributor 30 is contacted.

At this time, the residual air existing between the upper end of the piston 10 and the lower end of the air distributor 30 is a space between the lower end of the piston 10 and the upper end of the hammer bit 50 through the through-hole 11 of the center of the piston 10. Discharged to negative.

In this state, as shown in FIG. 4C, when the worker lifts up the sleeve tube 60 while working, the hammer bit 50 that is not hit by the lower hammer bit 50 protrudes downward, and the air distributor 30 Through the downflow hole 22 and the hollow portion 21 of the cylinder 20 through the inlet pipe 31 of the outside, and again introduced into the cylinder 20 through the hollow hole 21 through the falling hollow (23) Air pressure is filled in the space between the top of the piston 10 and the bottom of the air distributor 30 is discharged to the outside through the hammer bit 50 through the through-hole of the center of the piston 10 to maintain a no-load state.

Excavator equipped with the hammer hammer striking device for the present invention, as the external air pressure flows into the air distributor 30, the piston 10 is continuously raised and lowered repeatedly in the up and down direction inside the cylinder 20. The hammer bit 50, which is hit by the piston 10 from the lower part of the piston 10, continues the excavation work by continuously hitting the ground surface with the excavation strike surface of the lower part with the striking force received from the upper part.

Figure 5a is a side cross-sectional view showing another embodiment of the cylinder of the present invention is coupled to the inside of the sleeve tube, Figure 5b is a side cross-sectional view of Figure 5a, Figure 6a is an operating state showing the pneumatic flow when the piston descends of another embodiment of the present invention Figure 6b is a side cross-sectional view showing a pneumatic flow when the piston rises in another embodiment of the present invention, Figure 6c is a side cross-sectional view showing a pneumatic flow in the piston no-load state of another embodiment of the present invention.

Instead of the cylinder 20, it has a plurality of hollow portion (21a) formed in the inner longitudinal direction in the cylindrical shape, a plurality of descending upper holes (22a) at the top and a plurality of descending hollow (23a) at the center and a plurality at the bottom It has two rising holes (24a), only the hollow portion (21a) is formed in the inner surface of the body, the inner sleeve upper end inside the sleeve 60 is in close contact fixed to the lower protrusion 34 of the air distributor 30 The lower end of the body may be formed of a cylinder 20a that is caught and fixed to the upper side of the locking protrusion 61.

As such, the present invention does not require a guide tube for guiding the piston at the time of the blow, and strikes the hammer bit on the entire surface of the lower end of the piston so that the blow force is very excellent and the air distributor does not need to be formed long. It has a prolonged effect.

The present invention is not limited to the above-described specific preferred embodiment, and any person having ordinary skill in the art to which the present invention pertains may make various modifications without departing from the gist of the present invention claimed in the claims. Of course, such changes will fall within the scope of the claims.

Claims (2)

The back head 90 is formed with an inlet hole 92 through which a predetermined pressure of pneumatic pressure flows, and the pneumatic pressure introduced at the lower end of the inlet hole 92 flows back into the inlet hole 92 of the back head 90. Check valve 80 to prevent leakage, and the upper end of the inner end of the back head 90 is sealed in a long pipe is fixed by the chuck 74 in the lower inner side and the hammer bit 50 is located inside A chain sleeve tube 60, a piston 10 positioned above the hammer bit 50 inside the sleeve tube 60 and reciprocating up and down and hitting the hammer bit 50, and a piston inside the sleeve tube 60; Air distribution that is located between the 10 and the back head 90 and distributes the pneumatic pressure introduced into the inlet hole 92 of the back head 90 to reciprocate the piston 10 up and down to hit the hammer bit 50 In the drilling hammer bit striking device having a ruler (30); The air distributor 30 has a check valve 80 is elastically coupled to the top center by a spring 81 and has a plurality of inlet pipes 31 at the upper periphery and close to the inner surface of the sleeve pipe 60 at the top. A close bottom protrusion 34 having a close contact top protrusion 32 and having a spring seat 33 on the top face of the close top protrusion 32 and having a close contact with the inner surface of the cylinder 20 at the bottom thereof; An upper portion of the hemmer bit of the inner side of the sleeve tube 60 has a locking protrusion 61 protruding inward, and a rising hole 62 is formed outwardly below the locking protrusion; The outer circumferential surface of six directions in a cylindrical shape has a plurality of hollow portions 21 long cut in the inner vertical direction, has a plurality of descending upper holes 22 at the top, and has a plurality of descending hollows 23 at the center and It has a plurality of up and down holes 24 and the inside of the upper body of the sleeve tube 60 is fixed in close contact with the lower lower protrusion 34 of the air distributor 30 and the lower end of the body is fixed to the upper locking projection 61 To form a cylinder 20; The piston 10 has a through hole 11 at the center side and guides the external air pressure introduced through the lowering hollow 23 when descending from the upper portion of the cylinder 20 between the upper end of the piston 10 and the lower end of the air distributor 30. External air pressure introduced through the rising and lowering hole 24 when rising from the lower portion of the cylinder 20 has a downward induction hole (12) to the lower end of the piston 10 and the hammer bit through the elevating hole 62 of the sleeve tube 60 (50) Excavation hammer bit striking device, characterized in that the rising induction portion 14 is guided between the upper end. The method of claim 1; Instead of the cylinder 20, it has a plurality of hollow portion (21a) formed in the inner longitudinal direction in the cylindrical shape, a plurality of descending upper holes (22a) at the top and a plurality of descending hollow (23a) at the center and a plurality at the bottom It has two rising holes (24a), only the hollow portion (21a) is formed in the inner surface of the body, the inner sleeve upper end inside the sleeve 60 is in close contact fixed to the lower protrusion 34 of the air distributor 30 The lower end of the body has a hammer bit striking device, characterized in that it comprises a cylinder (20a) is fixed to the upper locking projection (61).