KR100715431B1 - A clust drill - Google Patents

Abstract

The present invention relates to a combination hammer. The present invention is provided by a frame which penetrates in the longitudinal direction and has a plurality of sleeve through-holes, and is provided inside the sleeve through-holes and supplied by cooperation of the sleeve through-holes, the valve body and the inner sleeve. A top sub having a lifting and lowering piston, a check valve that is fastened and mounted to an upper end of the frame and supplies air for lifting and lowering of the piston to each of the sleeve through holes, and is fastened to a lower end of the frame. A drive sub which is mounted and is formed through the drive hole in a lengthwise direction corresponding to the sleeve through hole, and is installed to penetrate the drive sub to be rotatable by a predetermined stroke and rotatable once The head of the unit comprises a bit protruding to the lower surface of the drive sub to excavate the ground .

Hammer, bit, drive sub, turn

Description

Combination Hammer {A clust drill}

1 is a cross-sectional view showing the configuration of a hammer unit according to the prior art.

Figure 2 is a perspective view showing the appearance of a preferred embodiment of the combination hammer according to the present invention.

Figure 3 is an exploded perspective view showing the configuration of the combination hammer of the embodiment of the present invention.

Figure 4 is a schematic cross-sectional view showing the internal configuration of an embodiment of the present invention.

5 is a plan view showing the top of the frame constituting the embodiment of the present invention.

Figure 6a is a cross-sectional view of the top sub constituting an embodiment of the present invention.

Figure 6b is a cross-sectional view showing the configuration of the connection portion mounted to the top sub constituting an embodiment of the present invention.

Figure 6c is a bottom view showing the bottom surface of the top sub constituting an embodiment of the present invention.

7 is a plan view showing a top surface of a drive sub which constitutes an embodiment of the present invention.

Explanation of symbols on the main parts of the drawings

100: frame 102: sleeve through

104: insertion guide protrusion 106: fastening hole

108: insertion guide hole 110: fastening hole

120: valve body 122: rod-shaped portion

130: inner sleeve 140: piston

142: air flow path 200: top sub

201: connecting portion 202: air supply passage

204: valve seat 206: check valve

209: communication hole 210: distribution channel

300: drive sub 302: bit through

304: insertion guide protrusion 306: fastening hole

310,310 ': Bit 312: Exhaust flow path

314: penetrating portion 316: hook projection

318: head curd 319: projection

320: foot valve

The present invention relates to a combination hammer, and more particularly, to a combination hammer configured to freely rotate a bit with respect to a drive sub.

Combination hammer is a civil construction equipment having a plurality of hammer units to drill the ground with a bit of each hammer unit. 1 shows a configuration of a hammer unit constituting the combination hammer.

According to the figure, the outer sleeve 3 forms the external appearance of the hammer unit 1 constituting the combined hammer. The outer sleeve 3 is formed to have a long cylindrical shape. Inside the outer sleeve 3, various components constituting the hammer unit 1 are installed.

The outer sleeve 3 corresponding to the upper end of the hammer unit 1 is mounted with a top sub 5 having an air supply passage 5 'formed therethrough. The top sub 5 has a lower end inserted into the upper end of the outer sleeve 3. A valve body 7 is provided inside the outer sleeve 3 corresponding to the lower portion of the top sub 5. An air flow path 7 'is also formed inside the valve body 7.

A check valve 9 is provided between the valve body 7 and the top sub 5. The check valve 9 is installed in close contact with the lower end of the air supply passage 5 'of the top sub 5 by a spring 9', and air flows into the valve body 7 through the top sub 5. To control the supply.

An inner sleeve 11 is provided inside the outer sleeve 3 corresponding to the lower portion of the valve body 7. The piston 13 is installed to penetrate the inner sleeve 11. A portion of the piston 13 is installed to penetrate the inside of the inner sleeve 11, and is lifted by the air supplied through the check valve 9, and the bit 17 to be described below is provided. Will be hit. An air flow passage 13 ′ is formed even through the inside of the piston 13. For reference, a flow path of air for lifting the piston 13 is also formed between the piston 13 and the inner sleeve 11, and these flow paths are communicated or closed by the lifting of the piston 13 and the piston is closed. Air is supplied in the direction of lifting (13) or in the opposite direction.

At the bottom of the outer sleeve 3, a drive sub 15 is installed. The drive sub 15 serves to guide the lift of the bit 17. The bit 17 is a portion which actually digs the ground and performs a puncturing function, and a discharge passage 17 ′ through which the air is discharged is formed.

A bit retaining ring 18 is provided inside the outer sleeve 3 to allow the bit 17 to enter and exit without falling out of the outer sleeve 3 more than a predetermined time. The bit retaining ring 18 is located inside the outer sleeve 3 corresponding to the top of the drive sub 15. The bit retaining ring 18 has a smaller inner diameter than a portion of the upper end of the bit 17 to prevent the bit 17 from being caught. Splines (not shown) surrounding the outer circumferential surface of the bit 17 are formed, and correspondingly splines (not shown) are formed on the inner circumferential surface of the drive sub 15. Thus, the bit 17 does not rotate with respect to the drive sub 15 and can only linear movement by a predetermined stroke.

The foot valve 19 is installed at the upper end of the discharge passage 17 ′ of the bit 17. The foot valve 19 is seated in the air flow path 13 ′ formed in the inner center of the piston 13 when the piston 13 hits the upper end of the bit 17. Together with the sieve 7 and the inner sleeve 11, it serves to form a flow path for raising and lowering the piston 13.

Hammer unit (1) having the configuration as described above is mounted to a separate frame to form a combination hammer. The combination hammer configured as described above is supplied with air to the top sub 5 of each hammer oil knit 1, and each bit 17 is operated to perform a drilling operation.

However, the prior art as described above has the following problems.

The bit 17 does not rotate relative to the drive sub 15 and can only be linearly moved. This is because splines are formed at corresponding positions of the bit 17 and the drive sub 15.

However, since the bit 17 rotates integrally with the rotation of the entire combined hammer in the process of excavating the ground using the combination hammer, the bit 17 collides with the rock, etc. The bit 17 is gradually broken. The spline also breaks due to the impact applied to the bit 17. Therefore, the bit 17 has to be replaced periodically, and in severe cases, there is a problem that the drive sub 15 needs to be replaced.

In addition, forming the spline on the outer circumferential surface of the bit 17 and the corresponding inner circumferential surface of the drive sub 15 to prevent the bit 17 from rotating is a very cumbersome operation, so that the bit 17 and the drive sub 15 are formed. There is a problem that the production cost is high.

It is therefore an object of the present invention to solve the problems of the prior art as described above, and to provide a combination hammer in which the bit is freely rotatable.

Another object of the present invention is to facilitate the manufacture of the components constituting the combination hammer.

According to a feature of the present invention for achieving the object as described above, the present invention is a frame through which the plurality of sleeve through the penetrating in the longitudinal direction is formed, and is installed inside the sleeve through the sleeve And a piston for lifting and lowering by air supplied by cooperation of a valve body and an inner sleeve, and fastened to and mounted on an upper end of the frame and supplying air for lifting and lowering of the piston to the respective sleeve holes. A top sub having a check valve, a drive sub-fastened to a lower end of the frame and having a bit through part corresponding to the sleeve through part to penetrate the inside in a longitudinal direction, and installed through the drive sub It is possible to move up and down by a predetermined stroke with respect to the drive sub and rotate at the same time. It protrudes when a is configured to include a bit for excavation of the ground.

According to another feature of the present invention, the present invention is a combination hammer in which the bit is installed through the drive sub, and the head of the bit tip is excavated and excavated, the bit is freely rotatable with respect to the drive sub and at the same time the drive sub Protruded by a predetermined stroke relative to.

The bit is provided in a cylindrical through portion located in the bit through portion formed through the drive sub and the tip of the through portion exposed to the outside of the drive sub and a plurality of protruding to the head It is configured to include protrusions.

The bit includes a center bit installed through the center of the drive sub, and a side bit installed through the edge of the drive sub, and the center bit protrudes relatively more than the side bit.

The head of the side bit is formed in a disc shape, and a recess is formed to prevent interference with the side bit surrounding the edge of the head of the center bit.

An inner surface of the bit through part further includes a bearing for smoothly rotating the bit.

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

As shown in the figures, the combination hammer of the present embodiment includes a frame 100 having a substantially cylindrical shape. The frame 100 is formed to have a substantially circular cross section, and a plurality of sleeve through-holes 102 are formed through the inside thereof in the longitudinal direction. The sleeve through portion 102 is formed to penetrate from the upper surface of the frame 100 to the lower surface. The sleeve through portion 102 is formed in five places in this embodiment. One is formed through the center of the frame 100, the other four are formed at regular intervals on the circumference of the same distance with respect to the center of the frame 100. The frame 100 is made of a metal material.

On the upper surface of the frame 100, as shown in Figure 5, one end of the sleeve through portion 102 is formed by opening. The insertion guide protrusion 104 also protrudes from the upper surface of the frame 100. At least two insertion guide protrusions 104 are provided symmetrically with respect to the center of the frame 100. A plurality of fastening holes 106 are formed at a predetermined angular interval at the upper edge of the frame 100. In this embodiment, four fastening holes 106 are formed to be opened to the edge of the upper surface of the frame 100 at intervals of 90 °.

Next, as shown in FIG. 3, the lower end of the frame 100 is formed by opening the other end of the sleeve through part 102. In addition, the lower surface of the frame 100 is formed so that the insertion guide hole 108 is recessed. At least two insertion guide holes 108 are provided symmetrically with respect to the center of the frame 100. The fastening hole 110 is formed at the edge of the lower surface of the frame 100 so as to be opened along the edge at predetermined angle intervals. The fastening hole 110 is formed in communication with the bolt groove 112 formed to be recessed in the outer surface of the frame 100. A fastening bolt 114 is positioned in the bolt groove 112 to fasten the frame 100 and the drive sub 300 to be described below.

The valve body 120 is installed at the upper end of the sleeve through-hole 102 of the frame 100. The valve body 120 serves to supply the air supplied through the air supply passage 202 of the top sub 200 to be described below to the piston 140 to be described below. The valve body 120 is provided with a rod-shaped portion 122 which is selectively inserted into the air flow path 142 of the piston 140.

An inner sleeve 130 is installed inside the sleeve through-hole 102 so that a portion of the valve body 120 is inserted into the valve body 120. The inner sleeve 130 is formed in a substantially cylindrical shape, the outer surface is formed with a flow path forming portion 132 long in the longitudinal direction. The flow path forming part 132 is formed by cutting the outer surface of the inner sleeve 130 into a bow shape in the longitudinal direction. The flow path forming part 132 cooperates with an inner surface of the sleeve through part 102 to form a flow path. A plurality of air through holes 134 are provided to communicate the flow path formed by the flow path forming unit 132 with another flow path.

The piston 140 is provided inside the sleeve through part 102. A portion of the piston 140 is movably positioned inside the inner sleeve 130. An air flow path 142 is formed by penetrating the center of the piston 140 in the longitudinal direction up and down. A portion of the piston 140 movable into the inner sleeve 130 may have a relatively small outer diameter, and a lower end of the piston 140 may have a relatively large diameter. A flow path forming part 144 is formed at the lower end of the piston 140 having a relatively large diameter. The flow path forming part 144 is not formed to the lower end of the piston 140.

The top sub 200 of the metal material is mounted on the top of the frame 100. The top sub 200 has a cylindrical shape corresponding to the shape of the frame 100, but has a relatively short length. The connection part 201 is fastened to protrude from the top center of the top sub 200. The connecting portion 201 and the top sub 200 are fastened by the respective screw portions 201 'and 200', as shown in FIG.

An air supply passage 202 is formed by vertically penetrating the center of the top sub 200, more precisely, through the center of the connection part 201. A valve seat 204 is formed inside the lower center of the connecting portion 201, which is a downstream portion of the air supply passage 202.

On the valve seat 204, a check valve 206 is seated, as shown in FIG. The check valve 206 serves to control the air for raising and lowering the piston 140 to be transmitted through the air supply passage 202. The check valve 206 is supported in a direction of shielding the air supply passage 202 by a spring 208 having a predetermined elastic restoring force.

A communication hole 209 communicating with the valve seat 204 is formed to open to the bottom surface of the top sub 200. A plurality of communication holes 209 are formed on the same circumference at regular intervals. In the bottom surface of the top sub 200 in communication with the communication hole 209, as shown in FIG. 6C, a distribution passage 210 is formed. The distribution channel 210 is made to communicate with each sleeve through portion 102 of the frame 100.

An insertion guide groove 212 is formed on the bottom surface of the top sub 200. The insertion guide groove 212 is formed by the number corresponding to the position corresponding to the insertion guide protrusion 104 of the frame 100. The insertion guide groove 212 is inserted into the insertion guide protrusion 104 is coupled to each other so that the coupling of the frame 100 and the top sub-200 more firmly. Thus, by using the insertion guide protrusion 104 and the insertion guide groove 212 in the coupling of the frame 100 and the top sub-200, the assembly work between them becomes easier and the relative movement during the assembly is used It does not occur.

A plurality of fastening holes 214 are formed to be opened to the lower surface of the top sub 200. The fastening hole 214 is formed in communication with the bolt groove 216 formed to be recessed to the outer surface of the top sub-200. The fastening hole 214 is formed at a position corresponding to the fastening hole 106 of the frame 100 to enable the fastening of the frame 100 and the top sub 200 by the fastening bolt 218.

The lower end of the frame 100 is mounted with a metal drive sub (300). The drive sub 300 is configured in a substantially cylindrical shape similar to the frame 100 or the top sub 200. The bit through part 302 is formed by penetrating the drive sub 300 up and down. The bit through part 302 is punched in a position corresponding to the sleeve through part 102 of the frame 100, respectively.

A plurality of bearings 303 are installed on the inner surface of the bit through part 302. An oilless bearing may be used as the bearing 303. The bearing 303 serves to smoothly rotate the bits 310 and 310 ', which will be described below.

An insertion guide protrusion 304 is provided on an upper surface of the drive sub 300. The insertion guide protrusion 304 protrudes from an upper surface of the drive sub 300 and is formed at a position corresponding to the insertion guide hole 108 on the lower surface of the frame 100. The insertion guide protrusion 304 is inserted into the insertion guide hole 108, so that the coupling between the frame 100 and the drive sub 300 is more robust.

An upper surface edge of the drive sub 300 is formed at a position corresponding to the fastening hole 110 of the frame 100. The fastening bolts 114 passing through the fastening holes 110 of the frame 100 are fastened to the fastening holes 110.

Bits 310 and 310 ′ are installed through the bit through part 302 of the drive sub 300. The bits 310 and 310 'are composed of four side bits 310 and one center bit 310'. The discharge passage 312 is formed by penetrating the bits 310 and 310 'up and down. The discharge passage 312 is a portion through which the air that raised and lowered the piston 140 is discharged.

The bits 310 and 310 ′ are provided with a cylindrical through portion 314. The through part 314 is a part located in the bit through part 302 of the drive sub 300 and is formed in an outer diameter and a shape corresponding to the inner diameter surface of the bit through part 302. The outer diameter of the through part 314 has a value corresponding to the inner diameter of the bearing 303.

The hook protrusion 316 surrounding the upper edge of the through part 314 is formed to protrude. The hook protrusion 316 is hooked on a bit ring (not shown) installed in the bit through part 302 to prevent the bits 310 and 310 'from protruding from the drive sub 300 by more than a predetermined time.

A head 318 is formed at the tip of the through part 314 of the bits 310 and 310 ′. The head 318 is formed approximately in the shape of a disk as well shown in the figure. Of course, the shape of the head 318 is not limited to the illustrated figure. The head 318 has a relatively large cross-sectional area compared to the cross-sectional area of the through part 314. The head 318 is different from that of the side bit 310 and the center bit 310 ′. That is, the head 318 of the center bit 310 'is substantially disc-shaped and has a recessed portion for avoiding interference with the head 318 of the side bit 310. The head 318 of the center bit 310 'is relatively thicker.

Accordingly, the head 318 of the center bit 310 ′ is further protruded while the head 318 of each bit 310, 310 ′ is in close contact with the bottom surface of the drive sub 300. As such, the center bit 310 ′ in which the head 318 protrudes relatively serves as the center of rotation of the combination hammer.

Hemispherical protrusions 319 are formed on the lower surface of the head 318 of the bits 310 and 310 ′ and the drive sub 300 without the head 318. The protrusion 319 serves to allow the head of the head 318 to dig into the ground more easily.

A foot valve 320 is provided at the inlet of the discharge passage 312 corresponding to the upper end of the through part 314 of the bits 310 and 310 '. The foot valve 320 is seated in the air passage 142 of the piston 140 when the piston 140 hits the upper end of the through portion 314 of the bit (310, 310 ') to selectively select the flow path of air To form.

 Hereinafter, the operation of the combination hammer according to the present invention as described above will be described in detail.

First, it will be described that the combination hammer of the embodiment of the present invention is assembled. The valve body 120, the inner sleeve 130, and the piston 140 are installed in the sleeve through part 102 of the frame 100. The valve body 120 is seated on an upper end of the sleeve through-hole 102, the inner sleeve 130 is in the inside of the sleeve through 102 corresponding to the lower portion of the valve body (120). Is located.

A portion of the piston 140 is located in the inner sleeve 130, and a relatively large portion of the piston 140 is formed inside the sleeve through hole 102 corresponding to the outside of the inner sleeve 130. Is located. The piston 140 is installed to be elevated in the interior of the sleeve through (102).

The top sub 200 is mounted on the top of the frame 100. At this time, the connection portion 201 is already mounted on the top of the top sub-200. In addition, a check valve 206 is installed in the valve seat 204 of the connection portion 201 to shield the air supply passage 202 by a spring 208.

The top sub 200 is mounted on the lower surface of the upper surface of the frame 100. At this time, the insertion guide protrusion 104 of the upper surface of the frame 100 should be inserted into the insertion guide groove 212 of the bottom surface of the top sub 200. The insertion guide protrusion 104 and the insertion guide groove 212 serves to guide the coupling position between the top sub 200 and the frame 100 and at the same time share the force acting on the fastening bolt 218 Make the bond more firm.

Fastening holes 218 of the fastening bolt 218 of the top sub 200 in a state where the top sub 200 is seated on the upper surface of the frame 100 so that the insertion guide protrusion 104 is inserted into the insertion guide groove 212. 214 passes through the fastening hole 306 of the frame 100.

When the top sub 200 is mounted to the frame 100 as described above, the valve seat 204 of the top sub 200 is connected to each of the sleeves through the communication hole 209 and the communication passage 210. It communicates with the through part 102. In addition, the valve body 120 may selectively communicate with a flow path formed in the sleeve through-hole 102.

The drive sub 300 is mounted on a lower surface of the frame 100. At this time, first, bits 310 and 310 'are seated in the bit through portion 302 of the drive sub 300. That is, the through part 314 of the bit 310, 310 ′ is inserted into the bit through part 302 from the lower surface of the drive sub 300 to protrude upward.

The bit ring is seated inside the bit through part 302 in a state where the through part 314 protrudes to the top surface of the drive sub 300. In this case, the bit ring may not be arbitrarily removed from the bit through part 302 of the bits 310 and 310 '. That is, even if the bits 310 and 310 'are pulled in the direction of exiting the drive sub 300, the hook protrusion 316 cannot be caught by the bit ring.

As such, the drive sub 300 is mounted on the lower surface of the frame 100 in the state where the bits 310 and 310 ′ are installed in the respective bit through parts 302. In this case, the fastening bolt 114 passes through the fastening hole 110 in a state where the insertion guide protrusion 306 of the upper surface of the drive sub 300 is inserted into the insertion guide hole 108 of the lower surface of the frame 100. To be fastened to the fastening hole 306.

The combination hammer assembling is completed as described above is received through a rod (not shown) connected to the connecting portion 201 the rotational force of the electric motor or hydraulic motor providing a rotational force. In the combination hammer of the present invention, the bits 310 and 310 'dig into the ground while tapping the ground as the whole rotates.

At this time, the bit (310, 310 ') is to hit the ground by the piston 140, that is, the air supplied to the air supply passage 202 is the valve seat through the check valve 206 204 is supplied to the distribution flow path 210 through the communication hole 209 from the valve seat 204.

The distribution channel 210 communicates with each of the sleeve through-holes 102 formed in the frame 100. Therefore, the air delivered to the sleeve through portion 102 is between the inner surface of the sleeve through portion 102 and the inner sleeve 130 through the valve body 120 and between the piston 140 and the sleeve. It is alternately supplied to the lower side and the upper side of the piston 140 through a flow path formed between the through parts 102 and the like.

First, when the piston 140 is lowered relatively in the interior of the sleeve through part 102, air is supplied to the lower side of the piston 140 to lift the piston 140. Therefore, the piston 140 is raised in the sleeve through (102).

When the piston 140 is raised, the rod-shaped portion 122 of the valve body 120 is positioned at the upper end of the air passage 142 of the piston 140, and is positioned at the lower end of the air passage 142 of the piston 140. The inserted foot valve 320 is released from the air passage 142 of the piston 140. In this case, the air used to lift the piston 140 is delivered to the discharge passage 312 of the bits 310 and 310 'through the foot valve 320 and is discharged to the outside.

Therefore, the piston 140 starts to fall, and air is rapidly supplied to the upper portion of the piston 140. Accordingly, the piston 140 hits the upper ends of the bits 310 and 310 ', and the bits 310 and 310' are dug into the ground by the impact force. This operation is repeatedly generated while the piston 140 is raised and lowered, and the hole is drilled by the impact force that the piston 140 strikes the bits 310 and 310 'and the rotation force in which the hammer is rotated.

In the process of punching while the combination hammer is operating, the piston 140 for generating an impact force is installed inside the sleeve through-hole 102 formed integrally with the frame 100. Therefore, even when an impact in which the piston 140 strikes the bits 310 and 310 'occurs, the position where the valve body 120, the inner sleeve 130, the piston 140, and the like are installed does not change.

On the other hand, the combined hammer of the present invention excavates the ground while the whole rotates. That is, while the frame 100, the top sub 200 and the drive sub 300 is integrally rotated, the ground is excavated. As the combination hammer rotates as described above, the bits 310 and 310 'rotate freely with respect to the drive sub 300, so that when the bits 310 and 310' collide with a relatively hard part such as a rock, they are relatively shocked. You will receive less. In other words, when the bits 310 and 310 'collide with the rock-like portion, the bits 310 and 310' may be rotated with respect to the drive sub 300 to mitigate the impact.

Meanwhile, in the present invention, when the head 318 is worn and the bits 310 and 310 'are replaced, the drive sub 300 may be separated from the frame 100. That is, instead of separating the drive sub 300 for each bit 310, 310 ′, but separating the integrated drive sub 300 from the frame 100, each bit 310, 310 ′ is a bit through portion. May be separated at 302. In this case, when the bit ring is removed from the bit through part 302, the bits 310 and 310 ′ may be separated from the drive sub 300.

In the present invention, the head 318 of the center bit 310 'is configured to protrude relatively more than the head 318 of the side bit 310, thereby serving as a rotation center axis of the rotating combination hammer. Therefore, since the combination hammer of the present invention maintains straightness during operation, perforation can be made more accurately, and side wear of the side bits 310 is equalized, thereby minimizing total wear.

The rights of the present invention are not limited to the embodiments described above, but are defined by the claims, and those skilled in the art can make various modifications and adaptations within the scope of the claims. It is self-evident.

For example, as long as the bearing 303 is installed on the inner surface of the bit through part 302 as shown in the illustrated embodiment, the bits 310 and 310 'can be freely rotated, and the insertion guide protrusions 104 and 304 are inserted. Positions of the guide grooves 108 and 212 may be reversed from those shown in the drawings. For example, a distribution channel formed on the lower surface of the top sub may be formed on the upper surface of the frame.

In the combined hammer according to the present invention as described in detail above, the following effects can be obtained.

In the present invention, since the bit is freely rotated with respect to the drive sub, damage to the bit by a rock or the like is minimized. Therefore, the combination hammer of the present invention has the effect of digging relatively soft ground more efficiently.

In the present invention, since the bit rotates freely with respect to the drive sub, it is easy to process the inner surface of the drive sub and the outer peripheral surface of the bit corresponding thereto. Therefore, the present invention can be expected to reduce the manufacturing cost while making the bit and the drive sub easy to manufacture.

In addition, in the present invention, the center bit is more protruding than the side bit, and thus serves as a rotation axis when the combination hammer rotates. Therefore, when the combined hammer is excavated, the straightness is increased, so the work is more accurate and easier, and the side wear of the side bit can be minimized, and the straightness of the combined hammer is high, so the length of the combined hammer is increased. Since it can be made relatively short, the combination hammer can be miniaturized.

Claims (6)

A frame having a plurality of sleeve through-holes penetrating in the longitudinal direction, A piston installed inside the sleeve through-hole and lifting and lowering by air supplied by the cooperation of the sleeve through-hole, the valve body, and the inner sleeve, A top sub fastened to the upper end of the frame and having a check valve for supplying air for lifting and lowering of the piston to each of the sleeve through holes; A drive sub-fastened to the lower end of the frame and formed by penetrating a bit through portion corresponding to the sleeve through portion in a longitudinal direction thereof; Combination hammer, characterized in that the penetrates through the drive sub and is capable of lifting up and down by a predetermined stroke with respect to the drive sub and rotating at the same time, and having the head of one end projecting to the lower surface of the drive sub to excavate the ground. In the combination hammer through which the bit is installed through the drive sub, and the head of the bit tip is excavated and excavated, Combination hammer, characterized in that the bit is freely rotatable with respect to the drive sub and at the same time configured to protrude by a predetermined stroke with respect to the drive sub. 3. The head of claim 1 or 2, wherein the bit is provided at a tip portion of the cylindrical portion and a cylindrical through portion positioned at a bit through portion formed through the drive sub portion and exposed to the outside of the drive sub portion. And a combination hammer, comprising a plurality of protrusions protruding from the head of the head. According to claim 3, wherein the bit is composed of a center bit is installed through the center of the drive sub, and the side bit is installed through the edge of the drive sub, the center bit is relatively relative to the side bit Combination hammer characterized by more protruding. 5. The combination hammer according to claim 4, wherein the head of the side bit is formed in a disc shape, and a recess is formed to prevent interference with the side bit surrounding the edge of the head of the center bit. 4. The combination hammer according to claim 3, wherein a bearing for smoothly rotating the bit is further provided on an inner surface of the bit through part.

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