KR20060119338A - Perforator means for excavator - Google Patents

Abstract

A drilling apparatus for an excavator is provided to form a hole on the ground without causing much pollution of the soil, and effectively reduce the cost. A drilling apparatus for an excavator is connected to a leader of a crane, to be movable upward and downward to form a hole on the ground. The perforator device comprises a hollow main body(100), a main cutter(200), and a driving unit. The main body is opened at the lower side and connected to the leader to be movable upward and downward. The main cutter is mounted integrally and rotatably to the lower end of the main body. A plurality of cutter blades are formed at the lower end of the main body, to perforate the ground in a cylinder form. The driving unit is installed in the main body to rotate the main cutter. The main body is connected to a driving shaft of a motor, which is mounted to the leader to be movable upward and downward. Air-jet holes and water-jet holes are arranged at intervals along the circumference of the main cutter.

Description

Perforator means for excavator

1 is a state diagram used in the drilling means according to the invention

Figure 2 is a perspective view of the drilling means according to the invention

Figure 3 is an exploded perspective view of a portion of the drilling means according to the invention

Figure 4 is a front cross-sectional view of the drilling means according to the invention

5 is an enlarged view illustrating main parts of FIG. 4;

Figure 6 is a side cross-sectional view of the drilling means according to the present invention.

7 is an enlarged view illustrating main parts of FIG. 6;

8 is a cross-sectional view taken along line AA of FIG.

9 is a process chart showing the process of drilling holes in the ground using the drilling means of the present invention

<Description of the symbols for the main parts of the drawings>

  2. Soil 3. Cylinder

  6. Crane 7. Leader

100.Body 200.Main Cutter

210. Cutting edge 230. Air sprayer

250. Water sprayer 400. Cutting means

410. Cutting Cutter 430. Rotating Cylinder

500. Lifting Cylinder

The present invention relates to a drilling means for excavators, and more particularly, to a drilling means for drilling holes in the ground to put a pile or the like in the ground, it is possible to reduce the occurrence of noise, vibration and dust, and to lower the cost The present invention relates to a drilling head for an excavator having a new structure.

In general, in order to pour concrete or pile piles in the ground in civil engineering work, piles are drilled by drilling holes in the ground to a predetermined depth. As described above, in order to drill a hole in the ground, a drilling means is connected to a rotary driver (hereinafter referred to as a motor) provided to be lifted up and down by a leader of a crane, and the drilling means is rotated by the driving force of the motor. The hole will be drilled. At this time, the drilling means is to use auger (aka, screw rod) or air hammer largely, since the auger is difficult to puncture the rock layer, it will be mainly used for drilling holes in the ground using an air hammer.

The air hammer is provided with a hammer bit that is operated by a pneumatic cylinder at the lower end of the air hammer, and imparts an impact force to the ground by the hammer bit while drilling the hole while rotating the air hammer by the motor. At this time, the hammer bit is formed with an air spraying hole and a water spraying hole so that dust generated at the time of drilling can be easily discharged to the outside and dust can be suppressed.

However, the method of drilling holes in the ground using an air hammer as described above has a problem that the hammer bit is drilled while applying impact force to the ground, so that vibration and noise are severely generated. In addition, in order to smoothly lift and operate the hammer bit, the lubricating oil is continuously supplied to the piston of the cylinder. In this case, there is a problem that soil is contacted with the lubricating oil during soil drilling. In addition, when the rock layer meets the ground during drilling, the air hammer is frequently biased to one side due to its impact force, and thus there is a problem in that the hole cannot be drilled in the exact vertical direction.

In addition, the method of drilling the ground with the air hammer, it is necessary to puncture the area as large as the diameter to be punched, it is not easy to suppress the dust generation even when spraying water through the water spray hole. In addition, since a plurality of air compressors must be driven in order to operate a heavy hammer bit, the air hammer has a problem in that the cost of energy is increased.

Therefore, the present invention has been proposed to solve the fundamental problems of the prior art as described above, the object of the present invention is to cut only the periphery of the hole diameter to be drilled without drilling the hole in the ground by the impact force It is possible to reduce vibration and noise by cutting the lower end, to prevent soil contamination, to reduce dust generation, and to provide a drilling means for the excavator of a new structure that can significantly reduce the cost.

In order to achieve the above object, the present invention is a drilling means connected to the leader of the crane lifting and drilling holes in the ground, the drilling means is hollow of the lower side is openly connected to the leader lifting The main body and the lower end of the body rotatably integrally provided with a plurality of cutting edges are formed at the lower end of the circular ring-shaped main cutter to form a cylinder on the ground, and the inside of the main body is installed It provides a drilling means characterized in that the drive means for rotating the cutter.

<Example>

Hereinafter, preferred embodiments of the present invention will be described in more detail with reference to the accompanying drawings. 1 is a view showing a state of use of the drilling means according to the invention, Figure 2 is a perspective view of the drilling means according to the invention, Figure 3 is a partially exploded perspective view of the drilling means according to the invention, Figure 4 is a drilling according to the invention Front section view of the means. And, Figure 5 is an enlarged view of the main portion of Figure 4, Figure 6 is a side cross-sectional view of the drilling means according to the invention, Figure 7 is an enlarged view of the main portion of Figure 6, Figure 8 is a cross-sectional view A-A of FIG. 9 is a process chart showing the process of drilling holes in the ground using the drilling means of the present invention.

As shown, the drilling means 10 is provided so as to be capable of lifting in a vertical direction to the leader 7 which is erected vertically from the ground by the crane 6, the motor 8 suspended by the wire 9 Is connected to the drive shaft of the rotation in one direction, connected to the drive shaft of the motor 8 and the body 100 is rotated in one direction, rotatably coupled to the lower end of the body 100, the body ( The main cutter 200 is rotated in the direction opposite to the rotation direction of the 100, and the drive means is installed in the body 100 to rotate the main cutter 200.

At this time, the motor 8 is installed vertically so that the drive shaft is located on the lower side, the drive shaft is installed so as to be exposed to the upper side of the motor 8, consisting of a hollow shaft, the drive shaft through the body 100 Into the inside of the oil hose, water hose, air hose can be inserted, the hollow screw rod (8a) for connecting the body 100 is fixed to the lower end of the drive shaft of the motor (8).

The body 100 is vertically fixed to the lower end of the screw rod (8a) to support the main cutter 200 to be described later, the lower side is made of a circular hollow tube shape, the desired ground 2 A hole of depth is formed long so that it can be drilled and rotated in one direction by the motor 8. At this time, the body 100 is made of a double tube shape. That is, the inner cylinder body 110 and the outer cylinder body 120 is wrapped around the circumference of the inner cylinder body 110 so as to form a space 115 therebetween, the drive chamber 130 is formed on the upper end Thus, the upper end of the drive chamber 130 is fixed to the lower end of the screw rod (8a). In this case, an insertion hole for inserting a power line and a hydraulic line into the center of the upper surface of the drive chamber 130 to supply power and hydraulic pressure to the driving means and cylinders 430 and 500 which will be described later into the drive chamber 130. 132 is formed through.

In this case, a pair of shaft couplings are formed on the upper surface and the bottom circumference of the body 100, that is, on the circumference of the space 115 position so as to communicate with the space 115 at regular intervals along the circumferential direction. Balls 111 and 112 are formed through, and the shaft coupling hole 111 and the shaft coupling hole 112 of the bottom surface are formed so as to face each other, the rotating shaft 320 of the driving means to be described later in the shaft coupling hole (111, 112). ) Can be coupled through.

In addition, a pair of through-holes 113 and 114 are formed on the upper and lower circumferences of the body 100, that is, on the same circumference between the axial coupling holes 111 and 112 so as to communicate with the space 115. Like the axial coupling holes 111 and 112, the through hole 113 and the through hole 114 on the bottom surface are formed to face each other. Therefore, the hydraulic line, the water line, and the air line introduced through the insertion hole 132 of the driving chamber 130 are configured to be connected to the connection ring body 150 to be described later through the through holes 113 and 114.

At this time, the lower end of the body 100 is fixedly coupled to the connection ring body 150 having the same diameter as the outer diameter of the body 100. The connection ring body 150 supports the main cutter 200, and has a ring-shaped concave groove concave inward along the circumferential direction so as to communicate with the axial coupling hole 112 and the through hole 114 in the central portion of the upper surface. 152 is formed, so that the lower end of the rotating shaft 320 to be described later on the bottom surface of the concave groove 152 is rotatably installed. At this time, the inner circumferential surface of the connecting ring body 150 is formed to be expanded in multiple stages so as to expand the diameter toward the lower side, one side of the second driven gear 340 connected to the lower end of the rotary shaft 320 to be described later on the upper inner circumferential surface The slot hole 154 is formed to penetrate in the circumferential direction so that the circumferential portion protrudes inward, and one side circumference of the second driven gear 340 protrudes into the connection ring body 150 through the slot hole 154. It is configured to be engaged with the ring gear 205 fixed to the main cutter 200 to be described later.

At this time, the center of the concave groove 152 of the connection ring body 150, that is, the bottom surface of the concave groove 152 of the position facing the respective through holes 114, the high pressure to the main cutter 200 to be described later An air flow path 155a, a water flow path 155b, and a pair of oil flow paths 155c are formed to communicate with the oil pressure, the lower side of the connection ring body 150 to supply water and air, respectively.

The main cutter 200 is rotatably coupled to an inner circumferential surface of the connection ring body 150 so that the lower side thereof protrudes toward the lower side of the connection ring body 150, and is rotated in a direction opposite to the rotational direction of the body 100. Cutting by drilling to form a cylinder (3) on the ground (2), it is made of a circular ring shape, the inner and outer diameter is formed with the same diameter as the inner and outer diameter of the body 100, while cutting the ground (2) on the bottom A plurality of cutting edges 210 are formed at regular intervals along the circumferential direction so as to perforate.

At this time, the upper end of the main cutter 200 is fixed to the ring gear 205, the gear teeth formed on the outer circumferential surface thereof so as to receive a driving force to the driving means to be described later is fixed by bolts. Meanwhile, in the illustrated embodiment, the ring gear 205 is separately formed and coupled to the upper end of the main cutter 200 with bolts, but in some cases, gear teeth may be formed on two upper surfaces of the main cutter 200. At this time, the inner circumferential surface of the lower end of the main cutter 200 has a predetermined interval along the circumferential direction, that is, a pair of receiving grooves 290 concave inward to accommodate the cutting means 400 to be described later in a position facing each other ) Is formed.

The air flow passage 155a and the water flow passage are formed at the center of the outer circumferential surface of the main cutter 200, that is, the surfaces corresponding to the air flow passage 155a and the water flow passage 155b and the pair of oil flow passages 155c. A ring-shaped air inlet groove 220a, a water inlet groove 220b, and a pair of oil inlet grooves 220c are formed to concave inwardly so as to communicate with each of the 155b and the pair of oil passages 155c. The air inlet groove 220a is formed with a plurality of air injection holes 230 which are inclined downwardly inwardly of the main cutter 200 at predetermined intervals along the circumferential direction, thereby providing air through the air injection holes 230. Supply to the inside of the main cutter 200 to blow out the dust generated during the drilling of the ground (2) to the outside.

In addition, the water inlet groove 220b is formed with a plurality of water injection holes 250 penetrating the cutting edge 210 at a predetermined interval along the circumferential direction, and sprays water through the water injection holes 250. By reducing the dust generated during the drilling of the ground (2) to prevent the cutting edge 210 is worn by the heat. In addition, an oil supply hole 292 penetrates into each of the receiving grooves 290 in the oil inflow groove 220c, and through a hose in the oil supply hole 292 penetrating into the receiving groove 290. Hydraulic pressure may be supplied to the cylinders 430 and 500 to be described later.

The driving means is to rotate the main cutter 200 at a high speed in the direction opposite to the rotation direction of the body 100, the drive motor 310 is fixedly installed perpendicular to the drive chamber 130 of the body 100 And a pair of rotary shafts 320 installed vertically in the shaft coupling holes 111 and 112 and rotatably installed, and drive gears 350 fixed to the drive shafts of the drive motor 310, respectively. A first driven gear 330 fixedly installed at an upper end of the rotating shaft 320 and engaged with the driving gear 350, and fixed to a lower end of each of the rotating shafts 320, and a ring gear of the maker 200. And a second driven gear 340 meshed with 205. In this case, the drive motor 310 is to use an electrically operated or hydraulically operated motor.

Therefore, the body 100 is rotated at a low speed in one direction to the motor 8 installed in the crane 6, the main cutter 200 is a high speed in the opposite direction to the rotation direction of the body 100 by the drive means It is rotated to cut the perforated to form a cylinder (3) on the ground (2).

At this time, each of the receiving grooves 290 of the main cutter 200, cutting means 400 for cutting the lower end of the cylinder (3) formed when the hole in the ground (2) by the main cutter (200) Is provided. The cutting means 400 is a cylinder formed by the main cutter 200 by the other end is hinged so that one end is roaming in the horizontal direction to the center of the main cutter 200 in each of the receiving grooves 290 ( 3) a cutting cutter 410 which cuts and cuts a lower end of the cutting unit to form a weak portion 4 having a predetermined thickness, and is connected between the cutting cutter 410 and the main cutter 200 to cut the cutting cutter 410. Rotating) is composed of a rotating cylinder 430 to allow the cutting cutter 410 to be accommodated in the receiving groove 290 or to rotate in and out. Therefore, when the main cylinder 200 is drilled so that the cylinder 3 is formed on the ground 2, the lower end of the cylinder 3 is cut by the cutting cutter 410, but the weak portion 4 is cut. Done.

At this time, the lifting cylinder 500 is provided in the front end of the cutting cutter 410 is fixedly installed so that the lower end is projected downward. Therefore, after cutting so that the weakened portion 4 of the cylinder 3 is formed by the cutting cutter 410, by operating the lifting cylinder 500 to elevate the drilling means 10, the weakened portion 4 is It will break.

Reference numeral 70 is an oil chamber that prevents oil, air, and water from leaking into the main cutter 200 individually, and number 158 is an inner circumferential surface of the connection ring body 150 to support the main cutter 200. The support ring is bolted to the, 280 is a locking ring bolted to the outer circumferential surface of the main cutter 200 to support the main cutter 200 is caught on the upper surface of the support ring 158, the number 285 The bearing is provided between the support ring 158 and the locking ring 280 to allow the main cutter 200 to be easily rotated.

According to such a configuration, the drilling means 10 drives the motor 8 in a state in which the upper end of the body 100 is connected to and fixed to the motor 8 that is installed to be lifted on the crane 6. And rotate the ring-shaped main cutter 200 at the same time to cut and drill a predetermined depth in the ground 2, as shown in Figure 9a, by the cutting edge 210 of the main cutter 200 When the cylinder 3 is formed in the ground 2, and then the cutting cutter 410 is slowly rotated to the center of the main cutter 200, as shown in Figure 9b, the lower end of the cylinder (3) Is cut to cut, but cut to cut so that the weak portion 4 of a predetermined thickness is formed, and then, when the lifting means 500 is extended to elevate the drilling means 10, the weak portion 4 is cut. Subsequently, when the cutting cutter 410 is accommodated in the receiving groove 290 of the main cutter 200 in the state in which the drilling means 10 is elevated above the ground 2, the cylinder 3 is provided with the drilling means 10. Are separated from).

As described above, according to the present invention, the drilling means is cut and punched to form a cylinder on the ground by a ring-shaped main cutter, and then cut the cylinder by cutting with a cutting cutter, and then extend the lifting cylinder After cutting the lower end of the cylinder, and then by lifting the drilling means to the upper side of the ground to remove the cut cylinder, as in the prior art, vibration and noise can be significantly reduced compared to using an air hammer. In addition, since only the periphery of the diameter to be drilled is required, as compared with drilling the entire diameter to be drilled as in the prior art, there is an advantage that the generation of dust can be significantly reduced, and only the main cutter needs to be rotated. Likewise, since the energy consumption is reduced compared to driving a large number of air compressors, the cost can be significantly reduced, and the soil is not contaminated.

Although the features of the present invention have been shown and described with reference to preferred embodiments, the present invention is not limited to the above-described embodiments, and the technical field to which the present invention pertains does not depart from the objects, configurations, and effects of the present invention. Various changes may be made by those skilled in the art.

Claims (6)

In the drilling means which is connected to the leader of the crane so as to drill a hole in the ground, The drilling means A hollow body having a lower side connected to the leader so as to be lifted and lowered; A main ring-shaped main cutter which is rotatably integrated at the lower end of the body and has a plurality of cutting edges formed at the lower end thereof to perforate to form a cylinder in the ground; Drilling means characterized in that the drive means is installed inside the body consisting of a drive means for rotating the main cutter. The method of claim 1, The body is boring means, characterized in that connected to the drive shaft of the motor provided to be elevated on the leader. The method of claim 1, Drilling means, characterized in that the inner wall surface and the cutting edge portion of the main cutter is formed with a plurality of air spray holes and water spray holes at regular intervals along the circumferential direction, respectively. The method of claim 1, Drilling means, characterized in that the cutting means for cutting the lower end of the cylinder is installed so as to be protruded into the center of the main cutter. The method of claim 4, wherein the cutting means A cutting cutter for cutting the lower end of the cylinder and the other end is hinged so that one end is rotated to the center of the main cutter inside the main cutter, and is connected between the cutting cutter and the main cutter to rotate the cutting cutter Perforation means, characterized in that consisting of a cylinder. The method of claim 5, The cutting cutter is cut to form a weak portion of a predetermined thickness at the lower end of the cylinder, One of the inner one side of the main cutter or one end of the cutting cutter, the lifting means is provided with a lifting cylinder which is fixed to raise the drilling means so that one end of the downward shed so that the weak part of the cylinder is broken. .

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