KR20150014276A - Down hole bit assembly - Google Patents

Abstract

The present invention relates to a boring bit assembly which facilitates the combining and separating of components and easily discharges crushed earth and sand. For the above-mentioned objective, the boring bit assembly comprises a first ring-shaped boring bit unit which has a first cutting protrusion unit protruding in an lower area in order to make a hole in the ground; a second ring-shaped boring bit unit which is inserted into and settled in the inner space of the first boring bit unit in one end and is arranged to protrude toward the upper part of the first boring bit unit in the other end; and a third boring bit unit which has a second cutting protrusion unit to make a hole in the ground, a bit head installed by being penetrated into the first boring bit unit and the second boring bit unit, and a power transmission member extended toward the upper part of the bit head in order to receive power from the outside.

Description

Down hole bit assembly < RTI ID = 0.0 >

The present invention relates to a perforated bit assembly, and more particularly, to a perforated bit assembly that facilitates fastening and disassembling of components and facilitates the discharge of crushed soil.

Generally, perforated bit is used as a striking means to be used for drilling of the ground such as for mining, earth anchor, geological use, groundwater development by fastening to a hammer. Hamming and rotation Drilling by exercise is performed at the same time to drill ground or rock

Conventionally, since the bit head in which the striking pin is protruded is formed integrally with the bit body, it is impossible to replace only the striking pin where the striking defect easily occurs. As a result, the whole drilling bit needs to be replaced, Even before the lifetime of the device, the device is disadvantageous in terms of economical loss.

In order to solve such a problem of the integral type perforated bit, a technique of separating a bit head and a bit body so that only a bit head can be replaced without replacing all the components when the severity of the impact pin is severe .

1, a conventional drilling bit (Patent No. 10-0858865) has a cutting tip 11 formed on a lower end surface thereof, a space portion formed therein, and a cheek bump 12 formed on an upper inner circumference A first frame 1 on which a clamping jaw 13 is formed on the inside of the clamping jaw 12 and a second frame 1 which is coupled to the inside of the first frame 1 and has a cutting tip 21 and a nozzle hole A second frame 2 on which a coupling groove 23 is formed to be slidably engaged with the coupling jaw 13 of the first frame 1 and a discharge groove 24 is formed on a side surface thereof, The first frame 1 is engaged with the hook 12 of the first frame 1 and is coupled to the outside of the second frame 2 to support the second frame 2 And a third frame (3).

The side surface 15 of the fastening protrusion 13 is smoothly inserted along the fastening groove 23, and the side surface 15 of the fastening protrusion 13 is smoothly inserted along the fastening groove 23, As shown in Fig. Therefore, the fastening protrusion 13 can be smoothly inserted into the fastening groove 23.

However, the conventional puncturing bit has an advantage that the fastening jaw 13 is smoothly inserted into the fastening groove 23, but the fastening jaw 13 can be easily inserted into the fastening groove 23 23). ≪ / RTI >

Specifically, when the second frame 2 moves up and down with respect to a conventional drilling bit, or when the drilling bit bites the rock, the coupling jaw 13 is separated from the coupling groove 23 It is easily separated.

As a result, the drilling operation is interrupted and the efficiency of the operation is deteriorated.

It is an object of the present invention to provide a perforated bit assembly in which a perforating operation can be performed while component parts are stably coupled, and a fastening operation and a disassembling operation of the component parts are facilitated.

Another problem to be solved by the present invention is to provide a perforated bit assembly capable of efficiently discharging crushed gravel.

According to an aspect of the present invention, there is provided a drill bit unit comprising: a ring-shaped first drilling bit unit having a first cutting protrusion protruded in a lower region; A second puncturing bit unit of a ring shape, one end of which is inserted and seated in the inner space of the first puncturing bit unit and the other end of which is arranged to protrude to the top of the first puncturing bit unit; The bit head is provided with a second cutting protrusion protruding in a lower region for penetrating the ground and penetrating the first and second perforation bit units. In order to transmit power from the outside, And a third punch bit unit having a power transmitting member extending in an upper direction of the punch bit assembly.

Wherein the first drilling bit unit comprises: a first coupling unit having a coupling protrusion protruded in a radial direction for coupling with the bit head; and a coupling unit coupled to the second coupling unit, And a second fastening portion having a fastening protrusion for the fastening portion.

The bit head includes a discharge groove formed in the longitudinal direction of the bit head so as to allow the first and second cutting protrusions and the bitumen crushed by the second cutting protrusion to be discharged, A coupling groove may be formed along the circumferential direction of the bit head so as to have a depth equal to that of the discharge groove and to be coupled with the coupling protrusion.

The coupling groove may include an inclined region groove formed at a predetermined height of the discharge groove and a horizontal region groove extending in the circumferential direction of the bit head in the inclined region groove.

Wherein the discharge groove includes a lower discharge groove located in a region where the coupling groove extends and an upper discharge groove extending from the lower discharge groove to an upper portion of the lower discharge groove, And the lower groove wall surface may be formed to be inclined in the radial direction of the bit head so that the width of the lower discharge groove becomes larger.

The fastening protrusions are stably coupled to the fastening grooves by being inserted into the horizontal region grooves, and the fastening protrusions and the horizontal region grooves may correspond to each other with a rectangular cross section.

The upper end of the fastening protrusion and the upper end of the fastening groove wall forming the fastening groove may be chamfered to maintain a distance between the fastening protrusion and the fastening groove.

A fluid injection hole through which fluid is injected is formed on a bottom surface of the bit head and the fluid injection hole is formed to be inclined in a direction of the discharge groove while communicating with a through hole penetrating the inside of the third perforation bit unit .

The through hole may include a first through hole formed in the bit head and a second through hole formed in the power transmitting member in communication with the first through hole.

The outer circumferential surface of the power transmitting member may be recessed along the longitudinal direction of the power transmitting member for coupling with an external power unit.

Wherein the discharge groove includes a first discharge groove, a second discharge groove and a third discharge groove formed at regular intervals along the circumferential direction of the bit head, A second engagement groove extending from the second discharge groove, and a third engagement groove extending from the third discharge groove, wherein the engagement protrusion is protruded from the inner side of the first engagement portion at regular intervals along the circumferential direction Wherein the first fastening protrusion is rotated in the circumferential direction after the first fastening protrusion is moved a predetermined distance along the first discharge groove, and the first fastening protrusion, the second fastening protrusion, Can be inserted.

The perforated bit assembly according to the present invention has the following effects.

First, the bit head of the third drilling bit unit is provided with a coupling groove for coupling with a coupling projection of the first drilling bit unit. The coupling groove is divided into an inclined region groove and a horizontal region groove, So that the fastening protrusion can be stably engaged with the fastening groove.

In particular, the fastening protrusion is formed to extend to the side surface of the discharge groove at a predetermined height from a starting point of the discharge groove in which the fastening protrusion starts to be inserted, and the fastening protrusion and the horizontal area groove each have a rectangular cross- The first puncturing bit unit and the third puncturing bit unit can be stably engaged while the puncturing bit assembly is rotated.

Second, an exhaust groove extending from the coupling groove is formed on an outer circumferential surface of the bit head. By making the depth of recess of the coupling groove equal to the depth of the drain groove, the resistance received in the process of discharging the ground- And a part of the wall surface forming the discharge groove is formed to be inclined in the radial direction of the bit head so that the sectional area of the discharge groove is widened so that the ground gravel can be easily discharged through the discharge groove.

Third, the upper end of the fastening protrusion and the upper end of the fastening groove wall forming the fastening groove are chamfered to maintain a predetermined gap between the fastening protrusion and the fastening groove, so that even if fine adhered material flows between the fastening protrusion and the fastening groove There is an advantage that the fastening protrusion can be easily separated from the fastening groove.

Fourthly, the fluid ejection holes formed on the bottom surface of the bit head are inclined in the direction of the ejection grooves, so that the gravel can be easily ejected through the ejection grooves.

Figure 1 is an exploded perspective view of a conventional perforated bit assembly.
2 is a perspective view of an embodiment of a perforated bit assembly in accordance with the present invention.
Figure 3 is an exploded perspective view of the perforated bit assembly of Figure 2;
4 is a perspective view illustrating a third perforated bit unit included in the perforated bit assembly of FIG.
FIG. 5 is a perspective view showing a bit head provided in the third perforation bit unit of FIG. 4. FIG.
6 is a perspective view illustrating a first perforated bit unit included in the perforated bit assembly of FIG.

Embodiments of a perforated bit assembly according to the present invention will be described with reference to the accompanying drawings.

Referring to FIGS. 2 to 6, the perforated bit assembly according to this embodiment includes a first perforation bit unit 100, a second perforation bit unit 200, and a third perforation bit unit 3000.

Hereinafter, the upper and lower directions referred to in the description of the detailed configurations of the first puncturing bit unit 100, the second puncturing bit unit 200, and the third puncturing bit unit 3000 will be referred to as a ' Is set perpendicular to the paper.

The first drilling bit unit 100 has a ring shape, and a first cutting protrusion 130 for protruding the ground surface is protruded from a lower area, that is, a portion contacting the ground.

The first puncturing bit unit 100 includes a first coupling part 110 for coupling with the third puncturing bit unit 3000 and a second coupling part 110 for coupling with the second puncturing bit unit 200. [ 2 fastening portion 120, as shown in Fig.

The second fastening part 120 extends from the upper surface of the first fastening part 110 and the first fastening part 110 and the second fastening part 120 are connected to the first puncturing bit unit 100, As shown in Fig.

As a result, the lower end of the second perforation bit unit 200 is positioned in a region where the first fastening part 110 and the second fastening part 120 are stepped, that is, the upper end of the first fastening part 110 Respectively.

The second fastening part 120 is formed with a latching protrusion 121 for fastening to one end of the second puncturing bit unit 200. The locking protrusion 121 protrudes from the inner surface of the second coupling part 120 in the form of a ring.

In addition, the first fastening part 110 has a fastening protrusion protruding radially from the bit head 3100 of the third perforation bit unit.

Specifically, the fastening protrusion includes a first fastening protrusion 111, a second fastening protrusion 112, and a third fastening protrusion 113 protruding from the inside of the first fastening part 110 at regular intervals along the circumferential direction ). That is, the first fastening protrusions 111, the second fastening protrusions 112, and the third fastening protrusions 113 are protruded at intervals of 120 degrees along the inner circumferential direction of the first fastening portions 110 have.

The first fastening protrusions 111, the second fastening protrusions 112 and the third fastening protrusions 113 protrude at intervals of 120 degrees along the circumferential direction. The first fastening protrusions 111, the second fastening protrusions 112, The third puncturing bit unit 3000 and the first puncturing bit unit 100 can be stably coupled by being coupled to the groove 3140, the second fastening groove (not shown) and the third fastening groove (not shown) And the rotational force of the third puncturing bit unit 3000 is efficiently transmitted to the first puncturing bit unit 100.

The second puncturing bit unit 200 has a ring shape and its lower end is inserted and seated in the inner space of the first perforation bit unit 100, that is, the inner space of the second fastening part 120, The upper end protrudes to the upper portion of the first perforation bit unit 100.

Specifically, a packing insertion groove 210 into which a packing member (not shown) is inserted is formed on the outer surface of the lower region of the second puncturing bit unit 200. The lower end of the second perforation bit unit 200 is inserted into the second fastening part 120 so that the packing member is in close contact with the inner surface of the second fastening part 120.

The upper end of the second puncturing bit unit 200 is fitted to the outer surface of the bit head 3100 of the third puncturing bit unit 3000.

Meanwhile, the third puncturing bit unit 3000 is installed while passing through the first puncturing bit unit 100 and the second puncturing bit unit 200.

Specifically, the third drilling bit unit 3000 includes a bit head 3100 having a second cutting protrusion 3110 protruded in a lower region for drilling the ground, 3100. The power transmitting member 3200 is formed to extend in the upward direction of the vehicle.

The outer surface of the bit head 3100 is formed with a recess formed in the longitudinal direction of the bit head 3100 so as to discharge the gravel broken by the first cutting protrusion 130 and the second cutting protrusion 3110. [ And a coupling groove extending from one side of the discharge groove and being recessed along the circumferential direction of the bit head 3100 to have the same depth as the discharge groove and to be coupled with the coupling protrusion.

By making the depth of recesses of the coupling groove and the drain groove the same, the resistance to be received in the process of discharging the crushed gravel through the drain groove is reduced.

The discharge groove includes a first discharge groove 3130, a second discharge groove (not shown) and a third discharge groove (not shown) formed at regular intervals along the circumferential direction of the bit head 3100.

The fastening groove includes a first fastening groove 3140 extending from the first discharge groove 3130, a second fastening groove (not shown) extending from the second discharge groove, a third fastening groove And a fastening groove (not shown).

The first discharge groove 3130, the second discharge groove, and the third discharge groove have substantially the same shape, and the first coupling groove 3140, the second coupling groove, and the third coupling groove are also substantially The description will be made only of the shapes of the first discharge groove 3130 and the first fastening groove 3140 in the following description.

The first discharge groove 3130 includes a lower discharge groove 3131 located in a region where the first fastening groove 3140 extends and a lower discharge groove 3131 extending from the lower discharge groove 3131, And an upper discharge groove 3133 located at an upper portion of the upper discharge groove 3133.

The lower discharge groove 3131 is formed by a lower groove wall surface 3132 formed along the longitudinal direction of the bit head 3100 and a lower groove bottom surface forming the bottom of the lower discharge groove 3131.

The upper discharge groove 3133 is formed by an upper groove wall 3134 extending from the first lower groove wall 3132 and an upper groove bottom forming the bottom of the upper discharge groove 3133 do.

Here, the lower groove wall 3132 is formed to be inclined in the radial direction of the bit head 3100 so that the width of the lower discharge groove 3131 becomes larger. As a result, the cross-sectional area of the first discharge grooves 3130 is widened, so that the crushed gravel can be easily discharged through the first discharge grooves 3130.

The first coupling groove 3140 includes an inclined region groove 3141 formed at a predetermined height of the first discharge groove 3130 and a second inclined region groove 3141 extending from the inclined region groove 3141 in the circumferential direction of the bit head 3100 As shown in FIG.

The inclined region groove 3141 includes an inclined groove wall surface 3142 extending obliquely from an end of the first lower groove wall surface 3132a of the lower groove wall surface, Is formed by the bottom surface.

The horizontal region groove 3143 is formed by a horizontal groove wall surface 3144 extending from the inclined groove wall surface 3142 and a horizontal groove bottom surface forming the bottom of the horizontal region groove 3143.

The upper end of the first fastening groove wall surface forming the first fastening groove 3140, that is, the upper end portion 3142a of the slanted groove wall surface and the upper end portion 3144a of the horizontal groove wall surface are chamfered.

Similarly, since the upper end portion 111a of the first fastening protrusion is also chamfered, when the first fastening protrusion 111 and the first fastening recess 3140 are fastened, the first fastening protrusion 111 and A predetermined gap is maintained between the first engagement grooves 3140.

Even if fine gravel adheres between the first fastening protrusion 111 and the first fastening groove 3140 by keeping a predetermined distance between the first fastening protrusion 111 and the first fastening groove 3140, The first fastening protrusion 111 can be easily separated from the first fastening groove 3140.

In addition, at least a portion of the first fastening protrusion 111 and the horizontal region groove 3143 correspond to each other with a rectangular cross section. Therefore, the first puncturing bit unit 100 and the third puncturing bit unit 3000 can be stably coupled while the puncturing bit assembly is rotating.

When the first fastening protrusion 111 and the first fastening recess 3140 are fastened together, the first fastening protrusion 111 is moved in the circumferential direction after being moved a certain distance along the first discharge groove 3130 And is stably inserted into the first engagement groove 3140, that is, the horizontal region groove 3143 while being rotated.

As a result, when the third perforation bit unit 3000 rotates in a direction opposite to the circumferential direction in which the horizontal region groove 3143 is formed, the first fastening protrusion 111 is stably positioned in the horizontal region groove 3143 As shown in Fig.

On the other hand, a fluid ejection hole through which fluid is ejected is formed on the bottom surface of the bit head 3100. The fluid ejection hole includes a first fluid ejection hole 3121 formed to be inclined in the direction of the first ejection groove 3130, a second fluid ejection hole 3122 formed to be inclined in the direction of the second ejection groove, And a third fluid injection hole 3123 formed to be inclined in the direction of the discharge groove.

The fluid discharge hole is formed to be inclined in the direction of the discharge groove, so that the gravel can be easily discharged through the discharge groove.

The fluid injection hole communicates with a through hole passing through the inside of the third perforation bit unit 3000. Specifically, the through hole includes a first through hole 3151 formed in the bit head 3100 and a second through hole 3151 formed in the power transmitting member 3200 in communication with the first through hole 3151. [ And includes a through hole 3251.

The bit head 3100 is formed at an upper end thereof with a separation preventing jaw 3160 for preventing the second puncturing bit unit 200 from being separated upward.

An outer engaging groove 3210 for engaging with an external power unit is formed on the outer circumferential surface of the power transmitting member 3200 along the longitudinal direction of the power transmitting member 3200.

A process of fastening and separating the components of the perforated bit assembly will be described as follows.

First, the lower end of the second perforation bit unit 200 is coupled to the upper portion of the first perforation bit unit 100.

Next, the third puncturing bit unit 3000 is inserted into the first puncturing bit unit 100 and the second puncturing bit unit 200 so that the first puncturing bit unit 100 and the first puncturing bit unit 200 correspond to each other. Through.

Next, the third puncturing bit unit 3000 is rotated in a direction opposite to the circumferential direction in which the first fastening recess 3140 is formed, so that the first fastening protrusion 111 is rotated in the horizontal direction of the first fastening recess 3140 So as to be seated in the groove of the region.

At this time, the second fastening protrusion and the third fastening protrusion are also seated in the second fastening groove and the third fastening groove, respectively.

Then, the coupling of the first puncturing bit unit 100, the second puncturing bit unit 200, and the third puncturing bit unit 3000 is completed.

Of course, the present invention is not limited to this, and the first puncturing bit unit 100 may be fastened while the second puncturing bit unit 200 is inserted into the third puncturing bit unit 3000 first.

Next, the third perforation bit unit 3000, which is connected to an external power device, pierces the ground through vertical movement and rotation. At this time, the first puncturing bit unit 100 coupled to the third puncturing bit unit 3000 is also rotated to puncture the ground.

The second puncturing bit unit 200 secures the linearity of the first puncturing bit unit 100 while puncturing the ground.

The worker inserts the third puncturing bit unit 3000 into the first puncturing bit unit 100 and the second puncturing bit unit 200 in a case where the cutting protrusions of the third puncturing bit unit 3000 are worn out and have reached the end of their life, ).

In order to separate the third puncturing bit unit 3000, the operator rotates the third puncturing bit unit in a direction opposite to the direction in which the third puncturing bit unit 3000 was rotated while puncturing the ground.

The first fastening protrusion 111 is separated from the first fastening recess 3140 and when the operator pulls the third puncturing bit unit 3000 in the upward direction, Is separated from the first puncturing bit unit 100 and the second puncturing bit unit 200.

As described above, the present invention is not limited to the above-described specific preferred embodiments, and various changes and modifications may be made by those skilled in the art without departing from the scope of the present invention as claimed in the claims. And such variations are within the scope of the present invention.

100: first puncturing bit unit 110: first fastening unit
120: second fastening part 130: first cutting projection
200: second puncturing bit unit 3000: third puncturing bit unit
3100: bit head 3110: second cutting projection
3121: first fluid discharge hole 3130: first discharge groove
3131: Lower discharge groove 3132: Lower groove wall surface
3133: upper discharge groove 3134: upper groove wall
3140: first fastening groove 3141: inclined region groove
3142: Sloped groove wall surface 3143: Horizontal area groove
3144: Horizontal groove wall surface 3160:
3200: Power transmission member 3210: Outer coupling groove

Claims (6)

A first puncturing bit unit having a ring shape and having a first cutting protrusion protruded in a lower region for puncturing the ground;
A second puncturing bit unit of a ring shape, one end of which is inserted and seated in the inner space of the first puncturing bit unit and the other end of which is arranged to protrude to the top of the first puncturing bit unit; And,
A bit head which protrudes in a lower region and penetrates the first drilling bit unit and the second drilling bit unit, and a second cutting protrusion protruding from the upper portion of the bit head for receiving power from the outside, And a third punch bit unit having a power transmitting member extending in a direction of the first punch bit unit,
Wherein the first drilling bit unit comprises: a first coupling unit having a coupling protrusion protruded in a radial direction for coupling with the bit head; and a coupling unit coupled to the second coupling unit, And a second fastening portion having a fastening protrusion for the fastening portion,
The bit head includes a discharge groove formed in the longitudinal direction of the bit head so as to allow the first and second cutting protrusions and the bitumen crushed by the second cutting protrusion to be discharged, A coupling groove is formed along the circumferential direction of the bit head so as to have a depth equal to that of the discharge groove and to be coupled with the coupling protrusion,
Wherein the coupling groove includes an inclined region groove formed at a predetermined height of the discharge groove and a horizontal region groove extending in a circumferential direction of the bit head in the inclined region groove,
Wherein the discharge groove includes a lower discharge groove located in a region where the coupling groove extends and an upper discharge groove extending from the lower discharge groove to an upper portion of the lower discharge groove, And the lower groove wall surface is formed to be inclined in the radial direction of the bit head so that the width of the lower discharge groove becomes larger. The method according to claim 1,
Wherein the fastening protrusion is stably coupled to the fastening groove by being inserted in the horizontal region groove, wherein the fastening protrusion and the horizontal region groove each correspond to each other with a rectangular cross section. 3. The method of claim 2,
Wherein an upper end of the fastening protrusion and an upper end of a fastening groove wall forming the fastening groove are chamfered to maintain a distance between the fastening protrusion and the fastening groove. The method according to claim 1,
A fluid injection hole through which fluid is injected is formed in a bottom surface of the bit head and the fluid injection hole is formed to be inclined in a direction of the ejection groove while communicating with a through hole penetrating the inside of the third perforation bit unit Characterized by a perforated bit assembly. 5. The method of claim 4,
Wherein the through hole includes a first through hole formed in the bit head and a second through hole formed in the power transmitting member in communication with the first through hole,
Wherein an outer engaging groove for engaging with an external power generator is formed on an outer circumferential surface of the power transmitting member along a longitudinal direction of the power transmitting member. 6. The method according to any one of claims 1 to 5,
Wherein the discharge groove includes a first discharge groove, a second discharge groove and a third discharge groove formed at regular intervals along the circumferential direction of the bit head, A second engagement groove extending from the second discharge groove, and a third engagement groove extending from the third discharge groove, wherein the engagement protrusion is protruded from the inner side of the first engagement portion at regular intervals along the circumferential direction A first fastening protrusion, a second fastening protrusion, and a third fastening protrusion,
Wherein the first fastening protrusion is inserted into the first fastening groove while being rotated in the circumferential direction after being moved a predetermined distance along the first discharge groove.

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