KR100705355B1 - Injection nozzle device of water jet system - Google Patents

Abstract

The present invention relates to an injector of a waterjet system for crushing a repair surface using ultra high pressure water, and more specifically, as the surface is irregularly formed during the crushing operation, repair is performed without any additional work to refine the crushing surface. The present invention relates to an injector of a waterjet system in which a surface crushing operation and a smoothing operation can be performed at the same time. The shaft 1 which rotates at a low speed by the power of the motor 111 and has a first water supply passage 11 perpendicular to the center portion 1 )Wow; An outer injection part 2 rotating with the shaft 1 to inject the ultra-high pressure water transmitted through the shaft 1 to the water-retaining surface; The inner injector 4 is rotatably provided inside the outer injector 2 and rotates at a high speed by the reaction force of the ultra high pressure water on the repair surface; In addition, there is an effect that can be economical as well as simple and efficient operation.

Outer injection part, inner injection part, upper and lower manifolds, connection part, swivel

Description

Injection nozzle device of water jet system

1 is a perspective view showing a transport robot of a general waterjet system.

Figure 2 is a side view showing the injector of FIG.

Figure 3 is a side view showing the injector of the waterjet system to which the present invention is applied.

Figure 4 is a perspective view showing the overall structure of the present invention.

5a and 5b show the internal structure of the present invention,

5A is a longitudinal sectional view,

5B is an enlarged view of a portion “A” of FIG. 5A.

6 is a front view showing an operating state of the present invention.

* Explanation of symbols for main parts of the drawings

1: shaft 2: outer sprayer

3: Connection part 4: Inner injection part

5: Nozzle putting on and taking off part 11: The first water supply

21: Outer injection nozzle 22: Upper manifold

22a: 2nd water supply 22b, 42b: water supply hole

23: Outer nozzle inclined portion 31: Spiral coupling portion

32: rotating support shaft 33: insertion hole

34: bearing 41: inner spray nozzle

42: lower manifold 42a: third feed passage

43: inner nozzle inclined portion 51: adapter

52: tightening nut

The present invention relates to an injector of a waterjet system for crushing a repair surface using ultra high pressure water, and more specifically, as the surface is irregularly formed during the crushing operation, repair is performed without any additional work to refine the crushing surface. The present invention relates to an injector of a waterjet system, which allows a surface crushing operation and a polishing operation to be performed simultaneously.

As is well known, a water jet system is a system that removes and repairs a wall surface of a road or structure that requires repair with ultra high pressure water, and includes a power pack for applying high pressure to water, and an ultra high pressure from the power pack. It is composed of an attachment (100) of Figure 1 performing a direct chipping (chipping), that is, a crushing operation for the repair surface receiving a number, and a transport robot (R) to attach and move the attachment .

In addition, the attachment 100 is a lower injection nozzle 115 while linearly reciprocating along the guide 110 by the drive unit 130 and the roller 117 of the carriage 116 integrally formed on the rear side. Injecting the ultra-high pressure water to the surface repaired through the injection device 120, the injection nozzle 115 is vertically penetrating the reduction device 112 associated with the motor 111 and the motor 111 It is attached to the lower side of the shaft 113 which rotates by the power of and is comprised so that it may rotate together.

On the other hand, when the chipping operation for the repair surface using the ultra-high pressure, the repair surface is formed in an irregular shape deeply dug by the ultra-high pressure, so the next concrete laying work requires a separate trimming work.

Therefore, in the related art, not only the promptness of the maintenance work can be provided, but also the work is cumbersome and inconvenient, and there is a problem of causing economic deterioration due to additional manpower and equipment input.

Accordingly, the present invention has been made to solve the conventional problems as described above, the purpose of which is to separate the surface of the irregular shape deeply dug by the ultra high pressure during the operation of the repair surface using the ultra high pressure It is to be able to carry out the shredding work and the smoothing work of the repair surface without the smoothing work.

In addition, an object of the present invention is to enable the drive to the low speed crushing unit and the high speed crushing unit necessary to achieve the above object with only one drive device.

In order to achieve the object of the present invention, the shaft rotates at a low speed by the power of the motor and a vertical water supply path is formed in the center; An outer injecting unit rotating the coaxially with the shaft and injecting the ultra-high pressure water transmitted through the shaft to the maintenance surface; The inner jetting unit is rotatably provided inside the outer spraying unit, and the inner spraying unit rotates at a high speed by the reaction force of the ultra high pressure water on the maintenance surface.

In addition, the motor is characterized by consisting of a hydraulic motor.

In addition, the outer injection portion is characterized in that the ultra-high pressure water is configured to be sprayed in the same rotational direction as the shaft.

In addition, the outer injection portion and the inner injection portion is characterized in that the ultra-high pressure water is configured to be injected in the same rotational direction as the shaft.

In addition, the outer injection unit is configured to be sprayed with ultra-high pressure water in the same rotational direction as the shaft, the inner sprayer is characterized in that the ultra-high pressure water is configured to be injected in the opposite direction to the rotational direction of the shaft.

In addition, the outer injection portion is configured by the upper side manifold having a plurality of outer injection nozzles in communication with the water supply passage of the shaft on the lower side of the shaft, the inner injection portion is rotated in the lower portion of the upper manifold by the connecting portion The lower side manifold having a plurality of inner injection nozzles freely coupled and in communication with the upper side manifold is characterized in that it is configured.

In addition, an outer nozzle inclined portion and an inner nozzle inclined portion forming an inclined angle in the same direction as the shaft rotation direction are formed on the end sides of the outer injection nozzle and the inner injection nozzle.

In addition, the outer nozzle inclined portion forming the same inclination angle as the rotational direction of the shaft on the end side of the outer injection nozzle, and the inner nozzle inclined portion in the opposite direction to the outer nozzle inclined portion formed on the end side of the inner injection nozzle It is done.

In addition, the connecting portion is configured to be coupled to the lower side of the upper side manifold by the helical coupling portion of the upper side, the lower portion is formed with an insertion hole into which the rotation support shaft formed is formed in the upper side central portion of the lower manifold It is characterized in that the bearing is provided in the insertion hole is configured to support the rotation support shaft freely rotated by the bearing.

The outer injection nozzle and the inner injection nozzle may be detachably mounted to upper and lower manifolds by a nozzle detachable part.

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

Figure 3 is a side view showing the injection device of the waterjet system to which the present invention is applied Figure 4 is a perspective view showing the overall structure of the present invention.

As shown therein, the present invention is mounted to the lower side of the shaft (1) of the injector 120 is configured to inject the ultra high pressure water transmitted through the swivel (114) and the shaft (1) to the maintenance surface, the injection The device 120 is configured to linearly reciprocate along the guide 110 by the drive device 130 and the roller 117 of the carriage 116 integrally formed on the rear side.

In addition, the present invention mounted on the lower side of the shaft 1 is configured to rotate by allowing the power of the upper motor 111 of the plate 118 to be transmitted to the shaft 1 through the reduction device 112.

In addition, the present invention rotates with the shaft (1) while the outer injection portion (2) for injecting the ultra-high pressure water transmitted through the shaft (1) to the maintenance surface, and the rotation inside the outer injection portion (2) It is possible to be comprised, it consists of an inner injection part 4 which rotates at high speed by the reaction force of the ultra high pressure water with respect to a maintenance surface, The said inner injection part 4 is the outer injection part 2 by the connection part 3; The lower side of the rotation is provided freely, the motor 111 is composed of a hydraulic motor (111).

The outer injection unit 2 is composed of an upper manifold having a plurality of outer injection nozzles 21 and is coupled to the lower side of the shaft 1, and the inner injection unit 4 has a plurality of inner injection nozzles. It consists of the lower side madfold 42 which has 41, and rotation is freely attached to the upper side manifold 22 by the connection part 3. As shown in FIG.

On the other hand, the inner injection unit 4 is configured to rotate by the reaction force generated when the ultra-high pressure water injected through the inner injection nozzle 41 hits the water surface as described above, for this purpose the inner injection An inner nozzle inclined portion 43 is formed on the end side of the nozzle 41.

That is, only when the injection direction of the ultra high pressure water through the inner injection nozzle 41 is formed to be inclined to one side, the ultra high pressure water that is injected obliquely can rotate at a high speed due to the reaction force generated by the impact surface. The same inclination direction and inclination angle are applied to all the inner injection nozzles 41 mounted on the side manifold 42 in large numbers.

In addition, since the outer injection nozzle 21 is rotated at a low speed by receiving the power of the upper motor 111 through the reduction device 112 and the shaft 1, the injection direction of the ultra high pressure water through the outer injection nozzle 21 is determined. It is not necessary to form it inclined, but in terms of crushing efficiency, it is more preferable to form the outer nozzle inclined portion 23 on the end side of the outer injection nozzle 21 like the inner injection portion, and the inclined direction of the outer portion on the lower side. The sand 2 is formed in the same direction as the shaft 1 on which it is mounted.

At this time, when the outer nozzle inclined portion 23 of the outer spray nozzle 21 and the inner nozzle inclined portion 43 of the inner spray nozzle 41 are formed in the same inclined direction as shown in FIG. The nozzle 21 is rotated clockwise with the shaft 1 in response to the power of the motor 111, and the inner spray nozzle 41 is counterclockwise due to the reaction force generated when the sprayed ultra high pressure water strikes the water surface. In high speed.

However, the inner inclined portion (41) of the inner spray nozzle (41) is formed to be inclined in the opposite direction to the outer nozzle inclined portion (23) of the outer spray nozzle (21) by the reaction force generated when the injected ultra high pressure water strikes the water surface. Although it may be configured to rotate in the same clockwise direction as the outer injection nozzle 21, it is more preferable that the inner injection nozzle 41 and the outer injection nozzle 21 are configured to rotate in opposite directions with respect to efficiency.

5a and 5b show the internal structure of the present invention, Figure 5a is a longitudinal cross-sectional view.

As shown in the present invention, the first water supply passage 11 vertically penetrates the central portion of the shaft 1, and is connected to the first water supply passage 11 to the upper side manifold of the outer injection portion 2. A second water supply passage 22a perpendicular to the fold 22 is formed, and the third water supply passage 42a is connected to the lower manifold 42 of the inner sprayer 4 subsequent to the second water supply passage 22a. Is formed.

In addition, between the second water supply passage 22a of the upper manifold 22 and the outer injection nozzle 21 and of the third water supply passage 42a and the inner injection nozzle 41 of the lower manifold 42. The space is configured to communicate with each other by the water supply hole 22b ().

The outer spray nozzle 21 and the inner spray nozzle 41 are detachably mounted to the upper manifold 22 and the lower manifold 42 by the nozzle detachable portion 5, respectively. As usual, the nozzle detachable part 5 is helically coupled and fixed to the upper and lower manifolds 22 and 42, and the other side is the outer injection nozzle 21 or the inner injection nozzle by the tightening nut 52. It is composed of an adapter 51 coupled with 41.

Together, the connecting portion 3 is coupled to the lower side of the upper manifold 22 by the spiral coupling portion 31 on the upper side as shown in FIG. 5B, and the lower portion is the upper portion of the lower manifold 42. An insertion hole 33 into which the rotational support shaft 32 formed at the side center portion is inserted and formed is formed, and a bearing 34 is provided inside the insertion hole 33 so that the insertion hole is formed by the bearing 34. 33) The rotating support shaft 32 is configured to freely support the rotation.

6 is a front view showing an operating state of the present invention.

The present invention configured as described above, first, the shaft (1) penetrating vertically through the reduction device 112 is coupled to the lower side of the shaft (1) by receiving the power of the hydraulic motor 111 and rotates in a clockwise direction. The outer injection part 2 rotates at a low speed in the same direction with the shaft 1, and the inner injection part 4 freely mounted on the lower side of the outer injection part 2 by the connecting part 3 It rotates at a high speed in the opposite direction to the outer injection part 2, that is, counterclockwise.

As described above, the inner ejection portion 4 rotates at a high speed in the opposite direction to the rotation direction of the outer ejection portion 2. As described above, the inner ejection nozzle 41 is formed by the inner nozzle inclination portion 43 by the shaft 1 and the outer portion. By forming the same inclination angle as the direction of rotation of the sand (2) is the opposite of the inclination angle by the reaction force generated when the ultra-high pressure water transmitted through the swivel 114 and the shaft 1 and injected from the inner injection nozzle 41 hits the water surface This is due to the high speed rotation in the direction.

Therefore, since the outer injection nozzle 21 rotates at a low speed, the ultra high pressure water injected from the outer injection nozzle 21 rotates at a low speed, and thus the pressure of the ultra high pressure water against the maintenance surface is largely acted upon, thereby crushing the maintenance surface. Deep pie.

In addition, since the inner spray nozzle 41 rotates at high speed, the ultra high pressure water injected from the inner spray nozzle 41 rotates at a high speed, so that the pressure of the ultra high pressure water sprayed from the outer spray nozzle 21 is increased. It acts less than the pressure, but the injection of ultra-high pressure water to the repair surface is made quickly so that it is deeply dug to uniformly smooth the crushed surface of irregular height, so that the crushing and smoothing work on the repair surface can be performed simultaneously. will be.

As described above, according to the present invention, as the surface is severely irregularly formed during the shredding operation of the repair surface using ultra high pressure water, the shredding operation and the smoothing operation of the maintenance surface may be simultaneously performed without a separate operation for refinishing the fracture surface. In this way, not only can the maintenance work be quick, but the work can be economically simple and efficient.

In addition, the present invention is configured to rotate by the low-speed crushing unit by the hydraulic motor and the high-speed crushing unit is configured to be rotated at a high speed by the ultra-high pressure sprayed from the low-speed crushing unit to ultra high pressure also has the effect that can be modularized and simplified.

Claims (10)

A shaft 1 rotating at a low speed by the power of the motor 111 and having a first water supply passage 11 perpendicular to the center portion thereof; An outer injection part 2 rotating with the shaft 1 to inject the ultra-high pressure water transmitted through the shaft 1 to the water-retaining surface; Injector device of the waterjet system, characterized in that consisting of; the inner ejection portion (4) rotatably provided inside the outer ejection portion (2), the inner ejection portion (4) to rotate at high speed by the reaction force of the ultra high pressure water on the maintenance surface; . The method of claim 1, Injection nozzle apparatus of the water jet system, characterized in that the motor 111 is composed of a hydraulic motor. The method of claim 1, The outer injection unit (2) is the injection nozzle device of the waterjet system, characterized in that the ultra-high pressure water is configured to be injected in the same rotational direction as the shaft (1). The method of claim 1, The outer injection unit (2) and the inner injection unit (4), the injection nozzle device of the waterjet system, characterized in that the ultra-high pressure water is configured to be injected in the same rotational direction as the shaft (1). The method of claim 1, The outer injector 2 is configured to spray ultra high pressure water in the same rotational direction as the shaft 1, and the inner injector 4 is configured to inject ultra high pressure water in a direction opposite to the rotational direction of the shaft 1. Injection nozzle unit of a waterjet system. The method of claim 1, The outer injection part 2 is coupled to an upper manifold 22 having a plurality of outer injection nozzles 21 communicating with the first water supply passage 11 of the shaft 1 at the lower side of the shaft 1. Are composed, The inner sprayer 4 has a lower portion having a plurality of inner spray nozzles 41 rotatably coupled to the lower portion of the upper manifold 22 by the connecting portion 3 and communicating with the upper manifold 22. Spray nozzle device of the waterjet system, characterized in that the side manifold (42) is configured by combining. The method of claim 6, By forming the outer nozzle inclined portion 23 and the inner nozzle inclined portion 43 to form the same inclination angle as the rotation direction of the shaft 1 on the end side of the outer injection nozzle 21 and the inner injection nozzle 41 Spray nozzle device of water jet system characterized in that. The method of claim 6, The outer nozzle inclined portion 23 is formed on the end side of the outer injection nozzle 21 to form the same inclination angle as the rotational direction of the shaft 1, and the outer nozzle inclined portion 23 is formed on the end side of the inner injection nozzle 41. And an inner nozzle inclined portion 43 in the opposite direction to the spray nozzle device of the water jet system. The method of claim 6, The connecting portion 3 is configured to be coupled to the lower side of the upper manifold 22 by the spiral coupling portion 31 of the upper side, the lower portion is a rotational support formed in the central portion of the upper side of the lower manifold 42 An insertion hole 33 into which the shaft 32 is inserted is formed, and a bearing 34 is provided inside the insertion hole 33 to freely rotate the rotation support shaft 32 by the bearing 34. An injection nozzle apparatus of a waterjet system, characterized in that configured to support. The method of claim 6, The outer jet nozzle 21 and the inner jet nozzle 41 are detachably mounted to the upper and lower manifolds 42 by a nozzle detachable part 5.

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