KR101472783B1 - Injection tip equipment for excavating ground - Google Patents

Abstract

The present invention relates to an excavation tip device capable of effectively opening or closing a connection passage connected to an air hammer. An excavation tip device according to the present invention includes a valve seat (37) formed on a middle portion of a connection passage (33) to face upward; and a valve member (38) provided on the valve seat (37) to be able to lift. Since the pressure of air and water supplied to the connection passage (33) is adjusted, the valve member (38) is lifted to open or close the middle portion of the connection passage (33). Since the water is supplied in a state in which the connection passage (33) is sealed by the valve member (38), it is possible to prevent the water from flowing to an air hammer (40) via the connection passage (33). Also, it is possible to prevent the connection passage (33) from being sealed due to the variation in the pressure of the air supplied to the connection passage (33).

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to an excavation-

BACKGROUND OF THE INVENTION Field of the Invention [0001] The present invention relates to a new apparatus for ground excavation, which can effectively open and close a connection passage connected to an air hammer.

Generally, when improving the soft ground, a method is used in which a ground is excavated by using a ground excavation apparatus to form a excavation hole, and then the mortar is filled in the excavation hole to reinforce the ground.

As shown in FIGS. 1 to 5, the ground excavation apparatus used for improving the soft ground includes an excavator body 10 provided with a excavation head 11, A distal end device 30 coupled to the lower end of the extension pipe 20 and an air hammer 40 coupled to a lower end of the distal end device 30. The air-

The extension pipe 20 is formed in the form of a triple pipe 22 composed of an inner pipe 21, a middle pipe 22 and an outer pipe 23 and is provided with a mortar supply passage 21a through which mortar is supplied into the inner pipe 21, And first and second auxiliary passages 22a and 23a are formed between the inner pipe 21 and the middle pipe 22 and between the middle pipe 22 and the outer pipe 23, respectively.

At this time, the upper and lower ends of the extension pipe 20 are formed so as to correspond to each other so that the upper and lower ends of the extension pipes 20 can be connected to each other.

The upper end of the distal end device 30 is configured to be screwed to the lower end of the extension pipe 20 and the lower end thereof is formed with a coupling portion 31 to which the air hammer 40 can be screwed, A mortar discharge passage 32 connected to the mortar supply passage 21a and connected at its lower end with a discharge hole 32a opened to the outside of the peripheral surface of the end device 30, A connecting passage 33 opened to the coupling portion 31 and an outer passage 34 connected to the second auxiliary passage 23a at an upper end thereof, A plurality of spray nozzles 35 are provided.

The upper end of the air hammer 40 is screwed to the coupling part 31 of the distal end device 30 and the lower end of the air hammer 40 is provided with a hammer bit 41, Pressure air supplied through the connection passage 33 in a state in which it is in a state of being opened.

The excavator main body 10 includes an air compressor for supplying high pressure air to the first auxiliary passage 22a provided in the extension pipe 20 and an air compressor for supplying high pressure water to the first auxiliary passage 22a, A pump is provided.

Therefore, when the excavation head 11 is operated in a state where the extension pipe 20 is connected to the excavating head 11 of the excavator main body 10 and the end device 30 and the air hammer 40, The excavating head 11 and the excavating head 20 are excavated while the front end device 30 and the air hammer 40 are rotated and the depth of the excavating head 11 is adjusted in accordance with the depth at which the air hammer 40 excavates the ground. The extension pipe 20 can be additionally provided between the pipe and the pipe, so that the ground can be drilled deeply.

At this time, when high-pressure air is supplied to the first auxiliary passage 22a using the air compressor, the air is supplied to the air hammer 40 through the connection passage 33 to vibrate the air hammer 40 The air hammer 40 can pierce the gravel layer, the zebric stone layer, the slag layer, and the rock layer.

When excavation of the ground is completed, the excavator main body 10 operates the high-pressure pump to supply high-pressure water to the connection passage 33 through the first auxiliary passage 22a, Water supplied to the connection passage 33 is injected at a high speed into the periphery of the end device 30 through the injection nozzle 35 to expand the excavation hole and supply mortar to the mortar supply passage 21a So that the mortar is discharged to the periphery of the distal end device 30 through the mortar discharge passage 32 and the discharge hole 32a of the distal end device 30. [

Then, the extension pipe 20, the end device 30 and the air hammer 40 are pulled out upwardly in accordance with the filling of the mortar inside the excavation hole, thereby filling the whole excavation hole with the mortar, The soft ground can be reinforced by allowing the filled mortar to cure.

The connection passage 33 of the distal end device 30 functions to supply high-pressure air to the air hammer 40. When the high-pressure water is supplied to the connection passage 33, the connection passage 33 To prevent the high pressure water from flowing into the air hammer 40. [

To this end, a check valve 36, which is urged upward by a spring 36a, is provided in the middle portion of the connection passage 33. When air is supplied to the connection passage 33, as shown in FIG. 4 The check valve 36 is opened so that air is supplied to the air hammer 40 through the connection passage 33. When water is supplied to the connection passage 33, The check valve 36 is closed so that water is injected only through the injection nozzle 35 without flowing into the air hammer 40 through the connection passage 33.

The construction and operation of such a ground excavator are described in detail in a number of prior documents including the registered patent 10-0787612 and the registered patent 10-0484906, and a detailed description thereof will be omitted.

When the water is supplied to the connection passage 33, the midpoint of the connection passage 33 is sealed by using the check valve 36, and water is supplied to the air hammer 40 The air hammer 40 is pressurized to be raised by the spring 36a so that it can not close the connection passage 33 immediately when water is supplied, 33 into the air hammer 40 through the air suction holes 33,

When the air is supplied through the connection passage 33, the check valve 36 must be kept open at all times. When the pressure of the air supplied through the connection passage 33 rises above the set pressure, There is a problem that the check valve 36 is closed by the air to seal the connection passage 33.

Therefore, there is a need for a new method to solve such a problem.

SUMMARY OF THE INVENTION The present invention has been made to solve the above-mentioned problems, and it is an object of the present invention to provide a new apparatus for ground excavation tip apparatus capable of effectively opening and closing a connection passage connected to an air hammer.

In order to attain the above object, the present invention is characterized in that a connecting passage (33) is connected to an intermediate portion between an extension pipe (20) and an air hammer, and a connecting passage (33) for connecting an air hammer to a first auxiliary passage (22a) A valve seat 37 is disposed at an intermediate portion of the connection passage 33 so as to face upward and is vertically movable up and down on the valve seat 37, Further comprising a valve body (38) for closing the connecting passage (33) and closing the intermediate portion of the connecting passage (33) in close contact with the valve seat (37) when the connecting passage (33) Is provided.

According to another aspect of the present invention, the valve body 38 is formed in a spherical shape, and the inner diameter of the upper end of the valve seat 37 is formed larger than the outer diameter of the valve body 38, And a gap G is formed between the outer circumferential surface of the valve seat 37 and the upper circumferential portion of the valve seat 37.

According to another aspect of the present invention, the valve seat 37 is formed on the inner bottom surface of the enlarged diameter portion 33c formed in the middle portion of the connecting passage 33, Further comprising a cover block (39) having a large recess (39a) formed on the lower side and the recess (39a) being engaged and fixed so as to cover the upper portion of the valve body (38) And a through hole 39b is formed in the circumferential surface of the through hole 39b so as to open to the interior of the recess 39a. The through hole 39b has an inner end portion formed with a gap G And the high pressure air supplied through the connection passage 33 flows into the gap G between the valve seat 37 and the valve body 38 through the through hole 39b, And the valve body (38) is pushed upward to open the connection passage (33).

A valve seat 37 is disposed on the intermediate portion of the connecting passage 33 so as to face upward and a valve body 38 is provided on the valve seat 37 The valve body 38 can be moved up and down by adjusting the pressure of air and water supplied to the connection passage 33 so that the middle portion of the connection passage 33 can be opened and closed.

Therefore, water can be prevented from flowing into the air hammer 40 through the connection passage 33 by supplying water in a state in which the connection passage 33 is closed by the valve element 38, It is possible to prevent the connection passage 33 from being sealed due to the pressure change of the air supplied to the connection passage 33.

1 is a reference view showing a conventional ground excavation apparatus,
2 and 3 are side cross-sectional views showing a prior art ground drilling rig,
FIG. 4 and FIG. 5 are reference views showing an operating state of a prior art ground drilling apparatus,
FIGS. 6 and 7 are side cross-sectional views showing a girder for ground excavation according to the present invention,
8 and 9 are reference views showing an operating state of the ground excavating apparatus according to the present invention.

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

6 to 9 show a front end apparatus for ground excavation according to the present invention, which is connected to an intermediate portion between an extension pipe 20 and an air hammer, and is provided therein with a first auxiliary passage 22a of the extension pipe 20, And the connecting passage 33 connecting the hammer 40 is formed.

That is, the extension pipe 20 is formed in the form of a triple pipe 22 composed of an inner pipe 21, a middle pipe 22 and an outer pipe 23, and is connected to a mortar supply passage And first and second auxiliary passages 22a and 23a are formed between the inner pipe 21 and the middle pipe 22 and between the middle pipe 22 and the outer pipe 23 respectively .

At this time, the upper and lower ends of the extension pipe 20 are formed so as to correspond to each other so that the upper and lower ends of the extension pipes 20 can be connected to each other.

The upper end of the distal end device 30 is configured to be screwed to the lower end of the extension pipe 20 and the lower end thereof is formed with a coupling portion 31 to which the air hammer 40 can be screwed, A mortar discharge passage 32 connected to the mortar supply passage 21a and connected at its lower end with a discharge hole 32a opened to the outer side of the peripheral surface of the end device 30 and an upper end connected to the first auxiliary passage 22a, And a lower end of which is open to the coupling portion 31 and an outer passage 34 whose upper end is connected to the second auxiliary passage 23a. A plurality of spray nozzles 35 connected to the spray nozzle 33 are provided.

The upper end of the air hammer 40 is screwed to the coupling part 31 of the distal end device 30 and the lower end of the air hammer 40 is provided with a hammer bit 41, Pressure air supplied through the connection passage 33 in a state in which it is in a state of being opened.

According to the present invention, a valve seat 37 is disposed at the middle portion of the connection passage 33 so as to face upward, and the valve seat 37 is provided above the valve seat 37, And a valve body 38 which is in close contact with the connecting passage 33 to open and close the intermediate portion of the connecting passage 33.

The connecting passage 33 is formed with a diameter enlarged portion 33c for partitioning the connecting passage 33 into an upper passage 33a and a lower passage 33b and the valve seat 37 Is recessed downward at the center of the bottom surface of the enlarged diameter portion 33c.

The valve body 38 is formed in a spherical shape having a high strength.

At this time, the valve seat 37 is recessed downward so as to form a dome shape having an upper inner diameter larger than the outer diameter of the valve body 38, and the outer peripheral surface of the valve body 38 and the valve seat 37 The gap G is formed between the upper circumferential portion of the upper end portion of the upper end portion and the lower end portion of the upper end portion.

A cover block 39 for covering an upper portion of the valve body 38 is provided on the bottom surface of the enlarged diameter portion 33c.

A recess 39a having a larger inner diameter than that of the valve seat 37 is formed on the lower side of the valve block 39 and a thread is formed on the outer peripheral surface of the lower end of the valve block 39, And is fixed to the bottom surface of the enlarged diameter portion 33c so as to cover the upper portion of the body 38. A through hole 39b opened to the inside of the recess 39a is formed on the circumferential surface.

The through hole 39b is formed so that its inner end is inclined so as to face a gap G formed between the valve body 38 and the valve seat 37. [

The operation of the end device thus constructed will be described as follows.

8, the valve element 38 is lowered due to its own weight, so that the valve seat 38 (see FIG. 8) 37 so as to seal the middle portion of the connecting passage 33. [

When the intermediate portion of the connecting passage 33 is sealed as described above, the first auxiliary passage 22a of the extension pipe 20 is instantaneously pressurized by using the air compressor provided in the excavator main body 10. [ When air is supplied, the air flows into the through hole 39b of the cover block 39 provided inside the enlarged diameter portion 33c through the upper passage 33a.

At this time, the through hole 39b is formed so that its inner end portion is inclined so as to face a gap G formed between the valve body 38 and the valve seat 37, so that high pressure air passing through the through hole 39b The intermediate portion of the connection passage 33 is opened by pushing the valve element 38 upward as shown by the dotted line in FIG.

When the high-pressure air is continuously supplied using the air compressor, the air passes through the through hole 39b to push the lower side of the valve body 38 upward so that the valve body 38 is not lowered , The air hammer 40 is supplied to the air hammer 40 through the lower passage 33b as shown by the dotted arrow, so that the air hammer 40 is operated.

When the operation of the air compressor is stopped, the flow of the air supplied to the connection passage 33 is stopped. At this time, the valve body 38 is lowered by its own weight and brought into close contact with the valve seat 37.

9, when the water is slowly supplied to the first auxiliary passage 22a using the high-pressure pump provided in the excavator main body 10, The upper surface of the valve body 38 is pressed by the water pressure generated at this time so that the valve body 38 is pressed against the valve seat 37 And is completely adhered.

That is, as described above, when high-pressure air is supplied to the first sub-passage 22a, the supplied high-pressure air passes between the valve element 38 and the valve seat 37 while passing through the through hole 39b, When water is slowly supplied to the first auxiliary passage 22a, water is injected into the cover block 39 through the through hole 39b, The valve body 38 is prevented from being pushed upwards.

When high pressure water is supplied to the inside of the first auxiliary passage 22a using the high pressure pump in a state in which the valve body 38 is pressed against the valve seat 37 by the water pressure as described above, The valve body 38 is kept in a state of being in close contact with the valve seat 37 without being pushed upwards so that the intermediate portion of the connection passage 33 is maintained in a closed state, Is injected into the periphery of the distal end device (30) through the injection nozzle (35) connected to the connection passage (33).

In the apparatus for ground excavation thus constructed, a valve seat 37 arranged upward is formed at the middle portion of the connecting passage 33, and a valve body 38 is provided on the valve seat 37 The valve body 38 can be moved up and down by adjusting the pressure of air and water supplied to the connection passage 33 so that the middle portion of the connection passage 33 can be opened and closed.

Therefore, water can be prevented from flowing into the air hammer 40 through the connection passage 33 by supplying water in a state in which the connection passage 33 is closed by the valve element 38, It is possible to prevent the connection passage 33 from being sealed due to a change in the pressure of the air supplied to the connection passage 33.

Particularly, since the valve body 38 is simple in structure and has a high durability as compared with a general check valve 36, there is an advantage that maintenance of the distal end device 30 is not required frequently.

The inner diameter of the upper end of the valve seat 37 is larger than the outer diameter of the valve body 38 so that the gap G between the outer circumferential surface of the valve body 38 and the upper end of the valve seat 37 So that the valve element 38 can be effectively pushed upward by the high-pressure air supplied to the connection passage 33.

Particularly, the valve seat 37 is formed on the inner bottom surface of the enlarged diameter portion 33c formed at the middle portion of the connecting passage 33, and the valve seat 38 is formed at the upper portion of the valve seat 38 And a cover block 39 having a concave portion 39a with a large inner diameter formed on a lower side thereof is provided on the circumferential surface of the cover block 39. An inner end portion of the cover block 39 is provided between the valve element 38 and the valve seat 37 A through hole 39b is formed so as to face the formed gap G so that the air supplied to the connection passage 33 passes through the gap G between the valve element 38 and the valve seat 37 through the through hole 39b, As shown in FIG.

Therefore, there is an advantage that the valve element 38 can be raised more effectively by the high-pressure air supplied to the connection passage 33. [

In the present embodiment, the valve seat 37 is recessed downward so as to form a dome having an inner diameter larger than the outer diameter of the valve body 38. However, It can be composed of various shapes such as a cone shape with a wider inner diameter.

10. Excavator main body 20. extension pipe
30. End cap 40. Air hammer

Claims (3)

And a connection passage (33) connecting the first auxiliary passage (22a) of the extension pipe (20) and the air hammer is formed in the middle of the extension pipe (20) and the air hammer,
A valve seat 37 disposed on the intermediate portion of the connection passage 33 so as to face upward,
The valve seat 37 is provided on the upper side of the valve seat 37 so as to be movable up and down. The valve seat 37 is closed when the valve seat 37 is lifted. The valve body 38,
And a cover block (39) which is coupled to cover the upper portion of the valve body (38) and has a concave portion (39a) and a through hole (39b)
The inner diameter of the upper end of the valve seat 37 is larger than the outer diameter of the valve body 38 so that a gap G is formed between the outer circumferential surface of the valve body 38 and the upper end of the valve seat 37 Formed,
The concave portion 39a of the cover block 39 is relatively larger in inner diameter than the valve seat 37 and the through hole 39b is inclined so as to face the gap G,
When the high-pressure air supplied through the connection passage 33 flows into the gap G through the through hole 39b, the valve body 38 is pushed upward to selectively open the connection passage 33 Wherein said apparatus further comprises: delete delete

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