KR19990037739A - Bit of Excavator - Google Patents

Abstract

The present invention relates to an excavator bit, the object of which is to quickly discharge the compressed air interposed between the bit and the piston to the outside to improve the crushing force of the bit, to quickly discharge the compressed air to increase the number of strokes of the bit, compression The outer circumferential surface of the bit, the chuck and the housing are not cut by the crushed rock blown out by the air.

The present invention is a bit of an excavator for crushing a rock by using the striking force of the piston reciprocating by the high-pressure compressed air supplied from the outside, the hood valve having an inner diameter extended in a predetermined section from the rear end of the through hole of the piston An insertion hole, a hood valve having an inner diameter and an outer diameter extended to be inserted into the hood valve insertion hole, a through hole of a bit connected to the hood valve, the inner diameter of which is extended to a predetermined size, and a predetermined portion at the center of the outer peripheral surface of the bit And a pneumatic discharge groove further extending in length forward, and a path conversion jaw formed at a rear end of the rock discharge groove formed on the outer peripheral surface of the tip of the bit with a predetermined radius of curvature.

According to the present invention, the bit of the excavator is formed with a sufficiently long pneumatic discharge groove formed on the outer peripheral surface of the excavator, since the compressed air interposed between the piston and the bit is quickly discharged to the front of the chuck, the drilling efficiency is increased Since the diameter of the bit through hole is sufficiently large, the supplied compressed air is quickly discharged to the outside to increase the number of blows of the bit, and a path conversion jaw having a predetermined radius of curvature is provided at the rear end of the rock discharge groove to be crushed. The rock is blown out by the compressed air so that the outer circumferential surfaces of the bit and chuck housings are not cut off.

Description

Excavator Bits {Bit of Excavator}

TECHNICAL FIELD The present invention relates to an excavator bit, and more particularly, to an excavator bit for breaking a rock by using high pressure compressed air.

In general, an excavator is a heavy equipment used to construct a railway or road, or to form a cavity by crushing a rock or the like when underground storage tanks and other construction.

In the underground construction site, the internal combustion engine is not used to prevent ventilation problems and the risk of explosion due to sparks, and the required power is mainly obtained by using high pressure compressed air supplied from a compressor located outside the construction site.

Such an excavator is provided with a track frame positioned toward a rock to be crushed, a bit which transmits an impact force to a target rock by a compressed air provided to slide on the track frame, and a hydraulic cylinder for manipulating the position of the track frame. And a compression device for supplying compressed air of high pressure to the bit.

1 is an exploded perspective view of a conventional excavator bit, Figure 2 is a cross-sectional view showing a coupling state of a conventional excavator bit.

Referring to this, the bit part of the excavator is largely provided with a back head 20 which receives high pressure compressed air from the outside, and a check valve installed inside the back head 20 to control the inflow of compressed air from the outside ( 30), a piston 40 reciprocating by the compressed air supplied inside the cylindrical housing 10, and a bit 50 which transmits the impact force to the target rock by the impact force of the piston 40. Is done.

The housing 10 is provided with predetermined spiral grooves 11 and 17 on both inner circumferential surfaces of the cylindrical member, and a plurality of pneumatic bypass grooves 12 and 13 and 14 having an inner diameter extended therein. do.

The back head 20 has a connection portion 23 protrudingly formed at one side thereof and connected to an external pneumatic line, and a screw portion 21 spirally coupled to the inside of the housing 10 at the other side thereof, and the connection portion 20 A predetermined through hole 22 is formed on the center axis line. At this time, the valve mounting portion 25 is formed on the central axis of the screw portion 21 toward the expanded hole in communication with the through-hole 22.

A predetermined check valve 30 is installed on the valve installation unit 25 to control the inflow of compressed air supplied from the outside.

The check valve 30 is provided with a valve 34 protruding rearward by a predetermined length by a predetermined spring 33, a plurality of inclined grooves 32 are provided on the outer peripheral surface of the check valve 30, the tip The insertion rod 36 protruding a predetermined length is provided. At this time, the inclined groove 32 of the check valve 30 is installed to be connected to the pneumatic bypass groove 12 of the housing.

A cylindrical inner sleeve 70 is provided inside the housing 10 to be in contact when the check valve 30 is advanced toward the bit 50. A rear end portion of the piston 40 slides inside the inner sleeve 70. Is inserted as possible.

The piston 40 has a predetermined head portion 41 is provided at the rear end thereof so as to slide by compressed air supplied in the state inserted into the inner circumferential surface of the inner sleeve 70, so that the front end portion has an expanded outer diameter. The expansion part 43 is formed to be inserted to slide in the housing 10 is provided, a plurality of pneumatic passages 44 which are dug to a predetermined depth from the rear end to a predetermined length on the outer peripheral surface of the expansion part 40 Is prepared.

A predetermined through hole 46 is provided on the central axis of the piston 40, and the through hole 46 has an inner diameter into which the insertion rod 36 of the check valve is inserted.

The bit 50 is provided with a hood valve 57 protruding a predetermined length at a rear end thereof, and a plurality of guide protrusions 55 are provided on an outer circumferential surface of the rear end thereof so as to slide into the guide groove 65 of the chuck to be described later. .

At this time, the tip portion of the bit 50 is formed with a predetermined radius of curvature, a plurality of projections (59a) is provided on the surface is made to transmit the impact force concentrated on the rock. In addition, a plurality of pneumatic discharge grooves 56 are provided on the outer peripheral surface of the central portion of the bit 50, a plurality of rock discharge grooves 58 having a predetermined depth are provided on the outer peripheral surface of the tip portion, and on the central axis of the bit 50. The through-hole 53 is divided into two at the tip side is formed.

A chuck 60 for guiding the conveying direction of the bit 50 is spirally coupled to the front end spiral groove 17 of the housing 10, and the chuck 60 is inserted with a guide protrusion 55 of the bit. A plurality of guide grooves 65 for guiding the conveying direction are provided, and an insertion hole 67 is inserted into the front end portion so that the outer peripheral surface of the central portion of the bit 50 slides.

Therefore, the bit 50 is supplied to the outer circumferential surface of the inner sleeve 70 through the inclined groove 32 of the check valve, the external compressed air supplied through the through hole 22 of the back head, and then The piston 40 is supplied toward the distal end portion of the piston 40 through a pneumatic passage 44 on the outer circumferential surface of the piston 40 and a pneumatic bypass groove 14 of the housing.

As a result, the piston 40 is slid backward by a predetermined length by the supplied compressed air, and pushes the check valve 30 of the rear end toward the rear end.

Therefore, a gap is generated between the check valve 30 and the inner sleeve 70 to push the rear end of the piston 40 toward the front end through the gap.

In this case, the hood valve 57 is inserted into the through hole 46 of the piston as the piston 40 and the hood hood 57 of the bit are slid toward the front end with a predetermined distance from each other. While hitting the bit 50 toward the tip to deliver the impact force to the rock.

Therefore, the compressed air that is filled between the piston 40 and the bit 50 before the hood valve 57 of the bit and the through hole 47 of the piston are engaged with the pneumatic discharge groove of the bit 50. It is made to be discharged to the front of the chuck 60 through 56.

In addition, the compressed air supplied through the hood valve 57 inserted into the through hole 47 of the piston 40 is discharged to the front of the bit 50, wherein the crushed rock is combined with the compressed air to the bit ( 50 is discharged to the outside through the rock discharge groove (58).

In this process, the pneumatic discharge groove 56 has a short length, so that even if the bit 50 is moved forward, the pneumatic discharge groove 56 is inserted into the inner circumferential surface of the chuck 60, and thus, between the bit 50 and the piston 40. The compressed air interposed therebetween cannot be discharged to the outside, and the impact force of the piston 40 is buffered, so that the excavation efficiency of the rock is lowered.

In addition, since the through hole 53 of the bit has a small diameter, the compressed air cannot be discharged quickly, so that the number of hits of the bit 50 is reduced, which causes a reduction in the excavation speed by the excavator.

Since the rock discharge groove 58 is located in a straight line from the tip of the bit 50, the crushed rock is ejected to the outside by compressed air, and the outer peripheral surfaces of the bit 50 and the chuck 60 housing 10 are shaved. There is a problem that the life of the component is shortened due to the bet.

The main object of the present invention is to form the length of the pneumatic discharge groove sufficiently long, to quickly discharge the compressed air interposed between the bit and the piston to the outside so that the impact force of the piston is transmitted to the bit as it is, the rock drilling efficiency It is to provide a bit of excavator that can be increased.

It is another object of the present invention to provide a bit of an excavator which is capable of significantly increasing the speed of rock rocking by an excavator by rapidly discharging compressed air by increasing the inner diameter of the bit through hole sufficiently to increase the number of strokes of the bit. It is.

It is still another object of the present invention to provide an excavator bit in which the outer circumferential surface of the bit and the chuck housing are not cut off by the crushed rock ejected by the compressed air by forming a predetermined path change jaw at the rear end of the rock discharge groove. .

1 is an exploded perspective view of a conventional excavator bit,

2 is a cross-sectional view showing a coupling state of a conventional excavator bit,

3 is an exploded perspective view of an excavator bit according to the present invention;

4 is a cross-sectional view of the excavator bit according to the present invention,

5 is a cross-sectional view showing a state when the piston constituting the present invention is retracted,

6 is a cross-sectional view showing a state when the piston constituting the present invention is advanced to break the rock.

*** Explanation of symbols for the main parts of the drawing ***

10: housing 12, 13, 14: pneumatic bypass groove

20: back head 30: check valve

32: inclined groove 40: piston

44: pneumatic passage 50: bit

56: pneumatic discharge groove 58: rock discharge groove

58a: Path Conversion Jaw 60: Chuck

70: inner sleeve

The present invention is a bit of an excavator for crushing a rock by using the striking force of the piston reciprocating by the high-pressure compressed air supplied from the outside, the inner diameter is extended to a predetermined size from the rear end of the through hole of the piston to a predetermined section inside A hood valve inserting hole formed therein, a hood valve formed by extending an inner diameter and an outer diameter so as to be inserted into the hood valve inserting hole, a through hole of a bit connected to the hood valve, and having an inner diameter extended to a predetermined size; The pneumatic discharge groove further extends forward by a predetermined length in the central portion of the outer peripheral surface of the bit, and the path conversion jaw formed in the rear end of the rock discharge groove formed on the outer peripheral surface of the tip of the bit with a predetermined radius of curvature.

In the present invention, the hood valve has an outer diameter of 28 mm to 40 mm, an inner diameter of 20 mm to 35 mm, and an inner diameter of a hood valve insertion hole corresponding to the hood valve is formed of 28 mm to 40 mm, and has a through hole of a bit. Has the characteristic formed from 20 mm-35 mm.

Hereinafter, with reference to the accompanying drawings for a preferred embodiment of the present invention in detail as follows.

Figure 3 is an exploded perspective view of the excavator bit according to the present invention, Figure 4 is a cross-sectional view of the excavator bit according to the present invention.

Referring to this, the bit part of the excavator is largely provided with a back head 20 which receives high pressure compressed air from the outside, and a check valve installed inside the back head 20 to control the inflow of compressed air from the outside ( 30), a piston 40 reciprocating by the compressed air supplied and supplied inside the cylindrical housing 10, and a bit 50 for transmitting the impact force to the target rock by the impact force of the piston 40. Is done.

The housing 10 is provided with predetermined spiral grooves 11 and 17 on both inner circumferential surfaces of the cylindrical member, and a plurality of pneumatic bypass grooves 12 and 13 and 14 having an inner diameter extended therein. do.

The back head 20 has a connection portion 23 protrudingly formed at one side thereof and connected to an external pneumatic line, and a screw portion 21 spirally coupled to the inside of the housing 10 at the other side thereof, and the connection portion 20 A predetermined through hole 22 is formed on the center axis line. At this time, the valve mounting portion 25 is formed on the central axis of the screw portion 21 toward the expanded hole in communication with the through-hole 22.

A predetermined check valve 30 is installed on the valve installation unit 25 to control the inflow of compressed air supplied from the outside.

The check valve 30 is provided with a valve 34 protruding rearward by a predetermined length by a predetermined spring 33, a plurality of inclined grooves 32 are provided on the outer peripheral surface of the check valve 30, the tip The insertion rod 36 protruding a predetermined length is provided. At this time, the inclined groove 32 of the check valve 30 is installed to be connected to the pneumatic bypass groove 12 of the housing.

A cylindrical inner sleeve 70 is provided inside the housing 10 to be in contact when the check valve 30 is advanced toward the bit 50. A rear end portion of the piston 40 slides inside the inner sleeve 70. Is inserted as possible.

The piston 40 has a predetermined head portion 41 is provided at the rear end thereof so as to slide by compressed air supplied in the state inserted into the inner circumferential surface of the inner sleeve 70, so that the front end portion has an expanded outer diameter. The expansion part 43 is formed to be inserted to slide in the housing 10 is provided, a plurality of pneumatic passages 44 which are dug to a predetermined depth from the rear end to a predetermined length on the outer peripheral surface of the expansion part 40 Is prepared.

A predetermined through hole 46 is provided on the central axis of the piston 40, and the through hole 46 has an inner diameter into which the insertion rod 36 of the check valve is inserted.

In addition, the front end of the through-hole 46 is provided with a hood valve insertion hole 47 having an inner diameter enlarged to a size of 28mm ~ 40mm to insert the hood valve 57 of the bit to be described later.

The bit 50 is provided with a hood valve 57 protruding a predetermined length at a rear end thereof, and a plurality of guide protrusions 55 are provided on an outer circumferential surface of the rear end thereof so as to slide into the guide groove 65 of the chuck to be described later. .

At this time, the tip portion of the bit 50 is formed with a predetermined radius of curvature, a plurality of protrusions (59a) is provided on the surface is made to deliver a concentrated force to the rock bed, the size of the hood valve 57 is It is 28mm ~ 40mm, the inner diameter is formed to have a diameter enlarged to about 20mm ~ 35mm is made to increase the discharge rate of the compressed air.

In addition, a plurality of pneumatic discharge grooves 56 are provided on the outer peripheral surface of the central portion of the bit 50, a plurality of rock discharge grooves 58 having a predetermined depth are provided on the outer peripheral surface of the tip portion, and on the central axis of the bit 50. The through-hole 53 is divided into two at the tip side is formed.

The pneumatic discharge groove 56 is formed to extend further toward the tip portion so that the compressed air filled between the piston 40 and the bit 50 is easily discharged, the through hole 53 has an inner diameter of 20 mm ~ It is expanded to 35mm so that the compressed air can be easily escaped.

In addition, a path conversion jaw 58a having a predetermined radius of curvature is provided at a rear end of the rock discharge groove 58 of the bit 50 so that the bit 50 and the chuck 60 are formed by the rock ejected by the compressed air. ), So that the outer peripheral surface of the housing 10 is not cut off.

A chuck 60 for guiding the conveying direction of the bit 50 is spirally coupled to the front end spiral groove 17 of the housing 10, and the chuck 60 is inserted with a guide protrusion 55 of the bit. A plurality of guide grooves 65 for guiding the conveying direction are provided, and an insertion hole 67 is inserted into the front end portion so that the outer peripheral surface of the central portion of the bit 50 slides.

In this case, a rounding part 68 having a considerable radius of curvature is provided at the tip end of the insertion hole 67 so that the compressed air discharged to the outside through the pneumatic discharge groove 56 can be more easily escaped.

When described in detail with reference to the accompanying drawings for the working example of the present invention by the above configuration as follows.

5 is a cross-sectional view showing a state when the piston constituting the present invention is retracted, Figure 6 is a cross-sectional view showing a state when the rock crushing the piston constituting the present invention is advanced.

Referring to this, the portion of the bit 50 is supplied to the outer circumferential surface of the inner sleeve 70 through the inclined groove 32 of the check valve, the external compressed air supplied through the through hole 20 of the back head is Subsequently, the pneumatic passage 44 on the outer circumferential surface of the piston 40 and the pneumatic bypass bypass 14 of the housing are supplied toward the distal end of the piston 40.

As a result, the piston 40 slides backward by a predetermined length by the supplied compressed air, and pushes the check valve 30 of the rear end toward the rear end.

Therefore, a gap is generated between the check valve 30 and the inner sleeve 70 to push the rear end of the piston 40 toward the front end through the gap.

At this time, as the piston 40 and the hood valve 57 of the bit are spaced apart from each other by a predetermined distance, the hood valve 57 is inserted into the through hole 47 of the piston. While hitting the bit 50 toward the tip will give impact to the rock.

Therefore, the compressed air that has been filled between the piston 40 and the bit 50 before the hood valve 57 of the bit and the hood valve inserting hole 47 of the piston is engaged with the pneumatic pressure of the bit 50. The discharge groove 56 is formed sufficiently long, and a rounding portion having a substantial radius of curvature is provided at the tip of the insertion hole of the chuck, and is quickly discharged to the front of the chuck 60, thereby increasing the impact force of the excavator.

In addition, since the through hole 53 of the bit is sufficiently large in diameter, the supplied compressed air is quickly discharged to increase the number of hits of the bit 50, and thus the excavation speed by the excavator is significantly improved.

Experiments have shown that as described above, the striking force is improved, and the excavation speed is increased by about 40% as the number of strikes is increased.

In addition, the rear end portion of the rock discharge groove 58 is provided with a path conversion jaw 59 having a predetermined radius of curvature so that the crushed rock is ejected to the outside by compressed air, and thus the bit 50 and the chuck 60 and the housing. The outer peripheral surface of (10) is not cut off.

According to the present invention, since the pneumatic discharge groove formed on the outer peripheral surface of the bit of the excavator is sufficiently long, the compressed air interposed between the piston and the bit is quickly discharged to the front of the chuck, thereby increasing the drilling efficiency. .

In addition, since the through hole of the bit is sufficiently large in diameter, the supplied compressed air is quickly discharged to the outside, so that the number of hits of the bit increases, and thus, the drilling speed by the excavator is significantly improved.

The rear end of the rock discharge groove is provided with a path conversion jaw having a predetermined radius of curvature so that the crushed rock is ejected to the outside by compressed air so that the outer peripheral surfaces of the bit and chuck housings are not cut off.

Claims (2)

In the bit of the excavator crushing the rock using the striking force of the piston 40 reciprocating by the high pressure compressed air supplied from the outside, A hood valve insertion hole 47 having an inner diameter extended to a predetermined size from a rear end of the through hole 46 of the piston 40 by a predetermined size; A hood valve 57 formed by expanding an inner diameter and an outer diameter so as to be inserted into the hood valve insertion hole 47; A through hole (53) connected to the hood valve (57), the inner diameter of which is extended to a predetermined size; A pneumatic discharge groove (56) further extended forward a predetermined length in the center of the outer peripheral surface of the bit (50); Bit of the excavator, characterized in that it comprises a path conversion jaw (59) formed with a predetermined radius of curvature at the rear end of the rock discharge groove (58) formed on the outer peripheral surface of the tip portion (50). The method of claim 1, The hood valve 57 has an outer diameter of 28 mm to 40 mm, an inner diameter of 20 mm to 35 mm, and an inner diameter of the hood valve insertion hole 47 corresponding to the hood valve 57 is 28 mm to 40 mm. Is formed, the through hole 53 of the bit is a bit of the excavator, characterized in that formed in 20 ~ 35mm.