KR102229577B1 - Multicoupled type drilling hammer and method for manufacturing the same - Google Patents

Abstract

The present invention relates to a multiple fastening type drilling hammer and a manufacturing method thereof, the present invention is a hammer-embedded body provided with a plurality of two-stage cylindrical holes on the lower surface; Lower insertion-type hammers respectively inserted into the two-stage cylindrical holes of the hammer-embedded body to generate an impact force by high-pressure compressed air; A connection-type air tank to which the lower end of the hammer-embedded body is fastened by a connection unit; A bit guide member provided with bit guide holes communicating with the two-stage cylindrical holes of the hammer-embedded body, and covering a lower side of the hammer-embedded body; A first fastening unit for fastening the lower end of the hammer-embedded body and the upper end of the bit guide member; A second fastening unit which penetrates in the longitudinal direction of the hammer-embedded body and is fastened to the upper end of the bit guide member; And bits that are respectively inserted to be movable up and down into the bit guide holes of the bit guide member, and excavate by applying an impact to soil or rock by the impact force of the lower insert-type hammer. According to the present invention, the part is not damaged even under eccentric pressure and the ground is excavated, and the configuration is simple.

Description

MULTICOUPLED TYPE DRILLING HAMMER AND METHOD FOR MANUFACTURING THE SAME}

The present invention relates to a multi-lock drilling hammer and a method of manufacturing the same.

There are various methods of drilling the ground to drive piles in the ground. In these methods, a drilling hammer is mounted on the lower end of a rotation shaft installed in a crane, and the drilling hammer excavates the ground by supplying high-pressure compressed air to the drilling hammer while rotating the rotation shaft. At this time, the drilling hammer rotates and simultaneously moves the piston in the drilling hammer up and down by high-pressure compressed air, hitting the drill bit provided at the end of the drilling hammer up and down, and excavating the ground while the drill bit strikes the rock and crushes it.

Drilling hammers include a mono drilling hammer in which a bit is made of a single piece, and a cluster drilling hammer in which a drill bit is divided into several pieces. In the case of a mono drilling hammer, although the excavation speed is high, vibration and noise are generated a lot, and the combined drilling hammer has a rather slow excavation speed, but the noise and vibration are relatively low during excavation.

In the conventional combination drilling hammer, a hammer generating an impact force by high-pressure compressed air is coupled to the through holes of the body in which a plurality of through holes are spaced apart in the circumferential direction, and the number of air passages corresponding to the through holes of the body is combined. The lower flange of the air tank provided with them covers the upper surface of the body. The body and the lower flange of the air tank are fastened by a plurality of stud bolts and bolts and pins respectively fastened to the stud bolts. The air tank pipe through which high-pressure compressed air is introduced is connected to the upper part of the lower flange of the air tank, the upper flange of the air tank is connected to the upper part of the air tank pipe, and the crane side is detachably connected to the upper flange of the air tank. In addition, a bit guide member provided with through holes of the body and a corresponding number of bit guide holes covers the lower surface of the body, and a bit that applies an impact to soil or rock by the impact force of a hammer to each of the bit guide holes of the bit guide member. Is slidably coupled. The body and the bit guide member are fastened by a plurality of stud bolts and nuts and pins fastened to the stud bolt.

In such a conventional combination drilling hammer, when high-pressure compressed air is supplied to the high-pressure supply tube to the air tank pipe while applying a rotational force to the upper end of the rotating shaft of the crane, the high-pressure compressed air supplied through the high-pressure supply tube is transferred to the air tank pipe and the air tank. It is distributed through the air passages of the lower flange and acts on the hammers respectively. As high-pressure compressed air acts on the hammers, the piston of the hammer repeatedly moves up and down, repeatedly applying an impact force to the bit, and the bit moves up and down by the repeated impact force of the piston and impacts the soil and rock of the ground. At the same time, the body rotates by the rotational force of the rotating shaft, and the ground is excavated.

On the other hand, depending on the type of crane, the combined drilling hammer mounted on the lower end of the rotating shaft is rotated by rotating the rotating shaft by applying a rotating force in the middle of the rotating shaft without applying a rotating force at the upper end of the rotating shaft.

However, when the conventional combination drilling hammer is mounted on the bottom of the crane's rotation shaft and excavates the ground while applying rotational force, when the combination drilling hammer excavates only a part of the soil and rock, the combination drilling hammer acts as an eccentric pressure to the combined drilling hammer. There is a problem that it is damaged as a crack is generated in the stud bolts and nuts and pins connecting the body of the air tank and the lower flange of the air tank, or a crack is generated in the stud bolts and pins connecting the body and the bit guide member.

It is an object of the present invention to provide a multi-fastening type drilling hammer for excavating the ground without damaging parts even under eccentric pressure, and a method of manufacturing the same.

In order to achieve the object of the present invention, a hammer-embedded body provided with a plurality of two-stage cylindrical holes on the lower surface; Lower insertion-type hammers respectively inserted into the two-stage cylindrical holes of the hammer-embedded body to generate an impact force by high-pressure compressed air; A connection-type air tank to which the lower end of the hammer-embedded body is fastened by a connection unit; A bit guide member provided with bit guide holes communicating with the two-stage cylindrical holes of the hammer-embedded body, and covering a lower side of the hammer-embedded body; A first fastening unit for fastening the lower end of the hammer-embedded body and the upper end of the bit guide member; A second fastening unit which penetrates in the longitudinal direction of the hammer-embedded body and is fastened to the upper end of the bit guide member; There is provided a multi-lock drilling hammer including; bits that are respectively inserted to be movable vertically into the bit guide holes of the bit guide member and excavate by applying an impact to soil or rock by the impact force of the lower insertion type hammer. .

The first fastening unit includes a plurality of first screw holes formed on the upper surface of the bit guide member, stud bolts each of which one is fastened to the first screw holes, and the outer surface of the lower end of the hammer-embedded body. A plurality of opening grooves formed so as to penetrate through the bottom surface of each of the opening grooves and the bottom surface of the hammer-embedded body, the first through hole through which the other side of the stud bolt is inserted, and through the first through hole It is preferable to include a fastening nut that is fastened to the other side of the stud bolt.

The second fastening unit includes a plurality of second screw holes formed at intervals in the circumferential direction on the upper surface of the bit guide member, and a plurality of holes formed through the hammer-embedded body and penetrating in the longitudinal direction of the hammer-embedded body. It is preferable to include two second through-holes, and a plurality of long bolts respectively inserted through the second through-holes and fastened to the second screw holes.

It is preferable that the second through-holes are respectively located between the two-stage cylindrical holes adjacent to each other.

The connection unit includes a round bar-shaped protrusion formed on the upper end of the hammer-embedded body, a male threaded portion formed on an outer circumferential surface of the round bar-shaped protrusion, and a female threaded portion formed on the lower inner circumferential surface of the connection-type air tank and fastened to the male threaded portion. , A plurality of inner reinforcing plates connected to the lower inner circumferential surface of the connected air tank and the upper surface of the round bar-shaped protrusion, and a plurality of outer reinforcing plates connected to the lower outer circumferential surface of the connected air tank and the upper surface of the hammer-embedded body It is desirable to do it.

The connection unit includes an opening hole formed at the upper end of the hammer-embedded body, a female threaded portion formed on the inner circumferential surface of the upper end of the opening hole, a male threaded portion formed on the lower outer circumferential surface of the connection type air tank and fastened to the female threaded portion, and the connection type It may include a plurality of inner reinforcing plates connected to the lower inner circumferential surface of the air tank and the bottom surface of the opening hole, and a plurality of outer reinforcing plates connected to the lower outer circumferential surface of the connected air tank and the upper surface of the hammer-embedded body.

In addition, inserting a lower insertion type hammer into the two-stage cylindrical holes of the hammer-embedded body provided with a plurality of two-stage cylindrical holes, respectively; Inserting a bit into each of the bit guide holes of the bit guide member provided with the bit guide holes; Temporarily assembling the bit assembly in which bits are inserted into the bit guide member and the hammer-embedded body by a first fastening unit; Fastening the hammer-embedded body and the bit assembly with a second fastening unit; Completely assembling the hammer-embedded body and the bit assembly with the first fastening unit; Assembling an air dispersion cap to the upper end of the hammer-embedded body by welding; Fastening a unit pipe to the upper end of the hammer-embedded body so that the air dispersion cap is located inside; Welding and connecting a plurality of inner reinforcing plates to connect the inner side of the unit pipe and the upper end of the hammer-embedded body; Welding and connecting a plurality of outer reinforcing plates to connect the outer surface of the unit pipe and the upper end of the hammer-embedded body; There is provided a method for manufacturing a multi-lock drilling hammer comprising a step of assembling a connected air tank by connecting a plurality of unit pipes following the unit pipe.

In the present invention, the upper end of the hammer-embedded body and the connecting air tank are coupled to each other by a connecting unit, the lower end of the hammer-embedded body and the upper end of the bit guide member are fastened by the first fastening unit, and the second fastening unit is the hammer-embedded body. Since it penetrates in the longitudinal direction of and is fastened to the upper end of the bit guide member, not only the hammer-embedded body and the connecting air tank are firmly connected, but the hammer-embedded body and the bit guide member are firmly connected. Due to this, not only the ground is excavated while minimizing the damage of parts when excavating the ground, but also the eccentric force acts on the bits (when the bits excavate the soil and rock), the built-in hammer body and the connection type air The eccentric force is transmitted over the entire joint of the tank, minimizing damage to the parts.

In addition, in the present invention, since the second fastening unit penetrates in the longitudinal direction of the hammer-embedded body and is fastened to the upper end of the bit guide member, the components are compactly coupled and the hammer-embedded body and the bit guide member are firmly connected.

In addition, the manufacturing method of the present invention temporarily assembles a hammer-embedded body into which the lower insert-type hammers are inserted and a bit guide member into which the bits are inserted into a first fastening unit, and fasten the hammer-embedded body and the bit guide member by a second fastening unit. By completely assembling the first fastening unit, not only the hammer-embedded body and the bit guide member are firmly fastened, but also the assembly precision of the hammer-embedded body and the bit guide member is increased, and manufacturing is simplified, thereby increasing assembly productivity.

1 is a front cross-sectional view showing an embodiment of a multi-lock drilling hammer according to the present invention,
Figures 2 and 3 are a cross-sectional plan view of a built-in hammer body constituting an embodiment of a multi-lock drilling hammer according to the present invention, respectively,
4 is a cross-sectional plan view of a bit guide member constituting an embodiment of a multi-fastening type drilling hammer according to the present invention,
5 is a bottom view showing an embodiment of a multi-lock drilling hammer according to the present invention,
6 is a front cross-sectional view showing a first embodiment of a connection unit constituting an embodiment of a multi-lock drilling hammer according to the present invention;
7 is a front cross-sectional view showing a second embodiment of a connecting unit constituting an embodiment of a multi-lock drilling hammer according to the present invention;
8 is an exploded perspective view showing an embodiment of a multi-lock drilling hammer according to the present invention,
9 is a flow chart showing an embodiment of a method for manufacturing a multi-lock drilling hammer according to the present invention.

Hereinafter, an embodiment of a multi-lock drilling hammer and a method of manufacturing the same according to the present invention will be described with reference to the accompanying drawings.

1 is a front cross-sectional view showing an embodiment of a multi-lock drilling hammer according to the present invention. 2 and 3 are cross-sectional plan views of a hammer-embedded body, respectively, constituting an embodiment of a multi-lock drilling hammer according to the present invention. 4 is a cross-sectional plan view of a bit guide member constituting an embodiment of a multi-lock drilling hammer according to the present invention. 5 is a bottom view showing an embodiment of a multi-lock drilling hammer according to the present invention.

1, 2, 3, 4, 5, an embodiment of a multi-lock drilling hammer according to the present invention, a hammer-embedded body 110, a lower insertion type hammer 120, a connection-type air tank ( 130), a bit guide member 150, a first fastening unit 160, a second fastening unit 170, and a bit 180.

The hammer-embedded body 110 includes a body part 111 having a set length, a plurality of two-stage cylindrical holes 112 formed through the body part 111 in the longitudinal direction of the body part 111 on the lower surface of the body part 111, and the body It includes a plurality of guide grooves 113 formed at a set interval on the outer surface of the part 111. The body part 111 is preferably formed in a round bar shape having a uniform outer diameter. The plurality of two-stage cylindrical holes 112 are positioned at regular intervals in the circumferential direction with respect to the center line of the body part 111. The two-stage cylindrical hole 112 has an inner diameter smaller than the inner diameter of the large-diameter cylindrical hole 4 and the large-diameter cylindrical hole 4 formed to a depth set in the longitudinal direction from the lower surface of the body part 111 of the hammer-embedded body 110. It is preferable to include a large-diameter cylindrical hole (4) and a small-diameter cylindrical hole (5) for communicating the interior of the connection-type air tank (130). The guide grooves 113 are formed at intervals in the circumferential direction, and each guide groove 113 is formed in the length direction of the body part 111.

The lower insertion type hammer 120 is inserted into the two-stage cylindrical holes 112 of the hammer-embedded body 110 to generate an impact force by high-pressure compressed air. The lower insertion type hammer 120 is inserted into the large-diameter cylindrical hole 4 of the two-stage cylindrical hole 112. As an example of the lower insert-type hammer 120, the lower insert-type hammer 120 has a middle air passage 10 and a top member 121 coupled to the upper end of the two-stage cylindrical hole 112 of the hammer-embedded body 110 , The cylinder 122 coupled to the two-stage cylindrical hole 112 following the tower member 121, the air distribution member 123 coupled to the inside of the cylinder 122 following the tower member 121, and the air distribution A check valve 124 that is inserted in the member 123 so as to be movable up and down to open and close the air passage 10 of the tower member 121, and a coil spring 125 that supports the check valve 124 with an elastic force. , It includes a piston 126 that is slidably inserted into the interior of the cylinder 122 to apply an impact force to the bit 170 while moving up and down by the high-pressure compressed air distributed by the air distribution member 123. The tower member 121 has a set length and is formed in a round bar shape having an outer diameter corresponding to the inner diameter of the large-diameter cylindrical hole 4, and a step surface having a small outer diameter is formed on the lower outer circumferential surface, and a male threaded portion is formed on the step surface. It includes an air passage 10 formed through the center of the tower member 121 in the longitudinal direction. The air passage 10 of the tower member 121 has a first passage 11 formed to a depth set in the center of the lower surface, and a first passage 11 having an inner diameter smaller than that of the first passage 11 following the first passage 11. It includes 2 passages 12. The outer diameter of the cylinder 122 is preferably the same as the inner diameter of the large-diameter cylindrical hole 4 of the two-stage cylindrical hole 112, and a female threaded portion fastened with the male threaded portion of the tower member 121 is provided on the outer circumferential surface of the upper end of the cylinder 122 do. The inner circumferential surface of the cylinder 122 is provided with annular grooves.

The connection type air tank 130 is fastened to the upper end of the hammer-embedded body 110 by the connection unit 140. The connection type air tank 130 is preferably formed of a cylindrical pipe having a set length, and its lower end is connected to the upper end of the hammer-embedded body 110 by the connection unit 180. As an example of the connection-type air tank 130, in the connection-type air tank 130, unit pipes 131 having a set length are connected to each other in the longitudinal direction, and two unit pipes 131 adjacent to each other are connected by welding. , The joint member 40 is coupled to the upper end of the unit pipe among the unit pipes. It is preferable that the air passage 41 is formed through the joint member 40 in the longitudinal direction, and a high pressure supply tube (not shown) through which high-pressure compressed air is supplied to the air passage 41 of the joint member 40 is connected. . A screw 132 wound in a spiral shape is connected to the outer circumferential surface of the connected air tank 130. It is preferable that the screw 132 and the connection type air tank 130 are connected by welding.

In the first embodiment of the connection unit 140, the connection unit 140, as shown in Figure 6, a round bar-shaped protrusion 141 formed on the upper end of the built-in hammer body 110, and the round bar-shaped protrusion A male threaded portion 142 formed on the outer circumferential surface of 141, a female threaded portion 143 formed on the lower inner circumferential surface of the connection type air tank 130 and fastened with the male threaded portion 142 of the round bar-shaped protrusion 141, and a connection type A plurality of inner reinforcing plates 144 connected to the lower inner circumferential surface of the air tank 130 and the upper surface of the round bar-shaped protrusion 141, and the lower outer circumferential surface of the connected air tank 130 and the upper surface of the hammer-embedded body 110 It includes a plurality of external reinforcing plates 145 to be connected. Each small-diameter cylindrical hole 5 of the two-stage cylindrical holes 112 is located in the upper surface area of the round bar-shaped protrusion 141. The air dispersing cap 190 is coupled to the upper surface of the hammer-embedded body 110, that is, the upper surface of the round bar-shaped protrusion 141 so as to be located inside the connected air tank 130. A concave hemispherical surface 191 is provided on the upper surface of the air dispersion cap 190.

In a second embodiment of the connection unit 140, the connection unit 140 includes an opening hole 146 formed at the upper end of the hammer-embedded body 110, and the opening hole 146, as shown in FIG. 7. A female threaded portion 147 formed on the upper inner circumferential surface of ), a male threaded portion 148 formed on the lower outer circumferential surface of the connection type air tank 130 and fastened to the female threaded portion 147 at the top of the opening hole, and the connection type air tank 130 A plurality of inner reinforcing plates 144 connected to the bottom inner circumferential surface of the bottom surface and the bottom surface of the opening hole 145, and a plurality of outer circumferential surfaces connected to the bottom outer circumferential surface of the connection-type air tank 130 and the upper surface of the hammer-embedded body 110 Includes reinforcing plates 145.

The bit guide member 150 is provided with bit guide holes 151 communicating with the two-stage cylindrical holes 112 of the hammer-embedded body 110, respectively, and covers the lower side of the hammer-embedded body 110.

The first fastening unit 160 fastens the lower end of the hammer-embedded body 110 and the upper end of the bit guide member 150. As an example of the first fastening unit 160, the first fastening unit 160, as shown in Figure 8, a plurality of first screw holes 161 formed on the upper surface of the bit guide member 150, Stud bolts 162 each of which one is fastened to the first screw holes 161, a plurality of opening grooves 163 formed on the outer surface of the lower end of the hammer-embedded body 110, and each opening groove 163 The first through hole 164 through which the other portion of the stud bolt 162 is inserted through the bottom surface of the hammer-embedded body 110 and the stud penetrating the first through hole 164 It includes a fastening nut 165 that is fastened to the other side of the bolt 162. The first screw holes 164 are preferably formed on the upper surface of the bit guide member 150 to a set depth, and are formed at intervals in the circumferential direction. The opening grooves 163 are formed at intervals in the circumferential direction of the hammer-embedded body 110 and have a uniform width and depth. It is preferable that there are three opening grooves 163, and it is preferable that two first through holes are located in each of the three opening grooves. It is preferable that there are six stud bolts 162.

The second fastening unit 170 penetrates in the longitudinal direction of the hammer-embedded body 110 and is fastened to the upper end of the bit guide member 150. As an example of the second fastening unit 170, the second fastening unit 170, as shown in Figure 8, a plurality of second screws formed at intervals in the circumferential direction on the upper surface of the bit guide member 150 Holes 171 and a plurality of second through holes 172 which are formed through the hammer-embedded body 110 and penetrate the upper and lower surfaces of the hammer-embedded body 110 in the longitudinal direction of the hammer-embedded body 110 And a plurality of long bolts 173 which are respectively inserted through the second through holes 172 and fastened to the second screw holes 171, respectively. Each of the second through holes 172 is preferably positioned between two two-stage cylindrical holes 112 adjacent to each other. The second screw holes 171 are positioned to correspond to the second through hole 172 one-to-one, and at this time, the second screw holes 171 are also positioned between two bit guide holes 151 adjacent to each other. . The second screw hole 171 is preferably formed to a depth set from the upper surface of the bit guide member 150. It is preferable that the plurality of second through holes 172 are located on the upper surface of the round bar-shaped protrusion 141 of the connection unit 140.

The bits 180 are inserted into the bit guide holes 151 of the bit guide member 150 so as to be movable vertically, and are excavated by applying an impact to soil or rock by the impact force of the lower insertion type hammer 120. The bits 180 are equal to the number of the lower insert type hammers 120.

9 is a flow chart showing an embodiment of a method of manufacturing a multi-lock drilling hammer according to the present invention.

As shown in Figure 9, one embodiment of the method for manufacturing a multi-fastening type drilling hammer according to the present invention, first, a two-stage cylindrical hole 112 of the built-in hammer body 110 provided with a plurality of two-stage cylindrical holes 112 A step (S1) of inserting the lower insert-type hammer 120 into each of the) proceeds. The two-stage cylindrical holes 112 have a large-diameter cylindrical hole 4 formed to a set depth from the lower surface of the hammer-embedded body 110, and the upper surface and a large diameter of the hammer-embedded body 110 with an inner diameter smaller than that of the large-diameter cylindrical hole 4, respectively. It includes a small-diameter cylindrical hole (5) to communicate the cylindrical hole (4). The lower insertion type hammer 120 is inserted into the large-diameter cylindrical hole 4 as the lower surface of the hammer-embedded body 110.

Inserting the lower insertion type hammers 120 into the built-in hammer body 110, and then inserting the bit 180 into the bit guide holes 151 of the bit guide member 150 provided with the bit guide holes 151, respectively. (S2) proceeds. The bit guide holes 151 are the same as the number of two-stage cylindrical holes 112 and the bits 180 are the same as the number of the lower insertion type hammers 120.

The order of inserting the lower insert-type hammers 120 into the hammer-embedded body 110 (S1) and inserting the bits 180 into the bit guide member 150 (S2) may be changed in order.

After inserting the bits 180 into the bit guide member 150, the bit assembly in which the bits 180 are inserted into the bit guide member 150 and the hammer-embedded body 110 are temporarily assembled by the first fastening unit 160. Step S3 proceeds. The first fastening unit 160 includes a plurality of first screw holes 161 formed on the upper surface of the bit guide member 150 and stud bolts 162 that are each fastened to one of the first screw holes 161 And a plurality of opening grooves 163 formed spaced apart from each other on the outer surface of the lower end of the hammer-embedded body 110, and the bottom surface of each opening groove 163 and the lower surface of the hammer-embedded body 110 It includes a formed first through hole 164 and a fastening nut 165 that is fastened to the other side of the stud bolt 162 penetrating the first through hole 164. During temporary assembly, each one of the stud bolts 162 is fastened to the first screw holes 161, and the stud bolts 162 are respectively penetrated through the first through holes 164 of the hammer-embedded body 110, and a fastening nut ( Each of the 165 is fastened to the other side of the stud bolt 162, but the fastening nuts 165 are not completely tightened.

A step (S4) of temporarily assembling the bit assembly and the built-in hammer body 110 by the first fastening unit 160 is performed, and then fastening the built-in hammer body 110 and the bit assembly with the second fastening unit 170 (S4). The second fastening unit 170 includes a plurality of second screw holes 171 formed at intervals in the circumferential direction on the upper surface of the bit guide member 150, and a plurality of pieces passing through the hammer-embedded body 110 in the longitudinal direction. It includes two second through-holes 172, and a plurality of long bolts 173 respectively inserted through the second through-holes 172 and fastened to the second screw holes 171, respectively. The second through-holes 172 are located between the two-stage cylindrical holes 112 adjacent to each other, and the second through-holes 172 are equal to the number of second screw holes 171. When the second fastening unit 170 is fastened, the long bolt 173 is passed through the second through hole 172 of the hammer-embedded body 110, and the male thread of the long bolt 173 is made of the bit guide member 150. 2 Fasten to the screw hole 171.

After fastening the hammer-embedded body 110 and the bit assembly with the second fastening unit 170, a step (S5) of completely assembling the hammer-embedded body 110 and the bit assembly with the first fastening unit 160 proceeds. The complete assembly of the first fastening unit 160 is to completely assemble the fastening nuts 165 respectively fastened to the stud bolts 162.

After assembling the first fastening unit 160 completely, a step (S6) of assembling the air dispersion cap 190 to the upper end of the hammer-embedded body 110 by welding proceeds.

After assembling the air dispersion cap 190 to the hammer-embedded body 110, the step (S7) of fastening the unit pipe 131 to the upper end of the hammer-embedded body 110 so that the air dispersion cap 190 is located inside It goes on. A female threaded portion is formed on the inner peripheral surface of the lower end of the unit pipe 131 and a male threaded portion is formed on the outer surface of the upper end of the hammer-embedded body 110, so that the female threaded portion of the unit pipe 131 is fastened to the male threaded portion of the hammer-embedded body 110 This is desirable. Meanwhile, a male threaded portion is formed on the outer circumferential surface of the lower end of the unit pipe 131 and a female threaded portion is formed on the upper end of the hammer-embedded body 110, and the male threaded portion of the unit pipe 131 is fastened to the female threaded portion of the hammer-embedded body 110. It could be.

After connecting the unit pipe 131 to the hammer-embedded body 110, a plurality of inner reinforcing plates 144 are respectively welded to connect the inner side of the unit pipe 131 and the upper end of the hammer-embedded body 110. Step S8 proceeds. The inner reinforcing plates 144 have a uniform thickness and are connected at intervals in the circumferential direction of the unit pipe 131.

After connecting the inner reinforcing plates 144, a step (S9) of connecting a plurality of outer reinforcing plates 145 by welding each to connect the outer surface of the unit pipe 131 and the upper end of the hammer-embedded body 110 proceeds (S9). do. The outer reinforcing plates 145 have a uniform thickness and are connected at intervals in the circumferential direction of the unit pipe 131.

After connecting the outer reinforcing plates 145, a step (S10) of assembling the connected air tank 130 by connecting a plurality of unit pipes 131 following the unit pipe 131 is performed. It is preferable that the two unit pipes 131 adjacent to each other are connected by welding. A screw 132 wound in a spiral shape is connected to the outer circumferential surface of the connected air tank 130. It is preferable that the screw 132 and the connection type air tank 130 are connected by welding.

Hereinafter, the operation and effect of the multi-lock drilling hammer and the manufacturing method according to the present invention will be described.

First, in a state where the detachable part provided in the joint member 40 of the multi-lock drilling hammer of the present invention is mounted on the lower end of the rotating shaft of the crane, the high-pressure compressed air is supplied to the high-pressure supply tube while applying a rotational force to the rotating shaft of the crane. It is supplied to the air flow path 141 of (40). The high-pressure compressed air supplied through the high-pressure supply tube flows into the connection-type air tank 130 and is dispersed by the air dispersion cap 190, and the dispersed high-pressure compressed air is a two-stage cylindrical hole ( 112) are supplied respectively. By supplying high-pressure compressed air to the two-stage cylindrical holes 112 of the built-in hammer body 110, the check valve 124 and the coil spring 125 of the lower insertion type hammer 120 are operated, and the air distribution member 123 ) Due to the air distribution, the piston 126 is repeatedly moved up and down by the high-pressure compressed air, and an impact force is repeatedly applied to the bit 170. As the bit 170 moves up and down by the repeated impact force of the piston 126 of the lower insertion type hammer 120, it gives an impact to the soil and rock of the ground, and at the same time, the hammer-embedded body 110 is formed by the rotational force of the rotary shaft. As it rotates, the ground is excavated. The excavated soil and rock debris are discharged onto the ground through the guide grooves 113 formed on the outer surface of the hammer-embedded body 110 and the screw 132 of the connection-type air tank 130.

As described above, in the present invention, the upper end of the hammer-embedded body 110 and the connection-type air tank 130 are coupled to each other by the connection unit 140, and the lower end of the hammer-embedded body 110 and the upper end of the bit guide member 150 Is fastened by the first fastening unit 160, and the second fastening unit 170 penetrates in the longitudinal direction of the hammer built-in body 110 and is fastened to the upper end of the bit guide member 150, so that the hammer built-in body 110 As well as the connection type air tank 130 is rigidly connected, the hammer-embedded body 110 and the bit guide member 150 are rigidly connected. Due to this, when excavating the ground, not only the ground is excavated while minimizing the damage of the parts, but also the eccentric force acts on the bits 170 (when the bits excavate soil and rock), the built-in hammer body The eccentric force is transmitted over the entire coupling portion of the connecting portion 110 and the connection type air tank 130 and the coupling portion of the hammer-embedded body 110 and the bit guide member 150 to minimize damage to the parts.

In addition, in the present invention, since the second fastening unit 170 penetrates in the longitudinal direction of the hammer-embedded body 110 and is fastened to the upper end of the bit guide member 150, the hammer-embedded body 110 and the bit are compactly coupled to the components. The guide member 150 is firmly connected.

In addition, the manufacturing method of the present invention temporarily assembles the hammer-embedded body 110 into which the lower insert-type hammer 120 is inserted and the bit guide member 150 into which the bits 180 are inserted into the first fastening unit 160, and The hammer-embedded body 110 and the bit guide member 150 are fastened with the second fastening unit 170 and the first fastening unit 160 is completely assembled to secure the hammer-embedded body 110 and the bit guide member 150. In addition to fastening, the assembly precision of the hammer-embedded body 110 and the bit guide member 150 is increased, and manufacturing is simplified, thereby increasing assembly productivity.

110; A built-in hammer body 120; Bottom insertion hammer
130; Connected air tank 140; Connection unit
150; Bit guide member 160; 1st fastening unit
170; A second fastening unit 180; beat

Claims (7)

A hammer-embedded body provided with a plurality of two-stage cylindrical holes on the lower surface;
Lower insertion-type hammers respectively inserted into the two-stage cylindrical holes of the hammer-embedded body to generate an impact force by high-pressure compressed air;
A connection-type air tank to which the lower end of the hammer-embedded body is fastened by a connection unit;
A bit guide member provided with bit guide holes communicating with the two-stage cylindrical holes of the hammer-embedded body, and covering a lower side of the hammer-embedded body;
A first fastening unit for fastening the lower end of the hammer-embedded body and the upper end of the bit guide member;
A second fastening unit which penetrates in the longitudinal direction of the hammer-embedded body and is fastened to the upper end of the bit guide member;
And bits that are respectively inserted to be movable vertically into the bit guide holes of the bit guide member and excavate by applying an impact to the soil or rock by the impact force of the lower insert-type hammer, and
The first fastening unit includes a plurality of first screw holes formed on the upper surface of the bit guide member, stud bolts each of which one is fastened to the first screw holes, and the outer surface of the lower end of the hammer-embedded body. A plurality of opening grooves formed so as to penetrate through the bottom surface of each of the opening grooves and the bottom surface of the hammer-embedded body, a first through hole through which the other side of the stud bolt is inserted, and through the first through hole It includes a fastening nut that is fastened to the other side of the stud bolt,
The second fastening unit is formed through a plurality of second screw holes formed at an interval in the circumferential direction on the upper surface of the bit guide member and the hammer-embedded body, the hammer-embedded body in the longitudinal direction of the hammer-embedded body And a plurality of second through holes penetrating the upper and lower surfaces of and a plurality of long bolts respectively inserted through the second through holes and fastened to the second screw holes,
The connection unit includes a round bar-type protrusion formed on the upper end of the hammer-embedded body, a male threaded portion formed on an outer circumferential surface of the round bar-type protrusion, and a female threaded portion formed on the lower inner circumferential surface of the connection-type air tank and fastened to the male threaded portion. , A plurality of inner reinforcing plates connected to the lower inner circumferential surface of the connected air tank and the upper surface of the round bar-shaped protrusion, and a plurality of outer reinforcing plates connected to the lower outer circumferential surface of the connected air tank and the upper surface of the hammer-embedded body And
The second through holes of the second fastening unit are located on the upper surface of the round bar-shaped protrusion,
In the connected air tank, a plurality of unit pipes having a set length are connected to each other in the longitudinal direction, and two unit pipes adjacent to each other are connected by welding, and a joint member is covered at the upper end of the upper unit pipe among the unit pipes. Multi-lock drilling hammer, characterized in that combined. delete delete delete delete delete delete

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