KR101300243B1 - Water powered hammer - Google Patents

Abstract

The present invention relates to a hammer driven by water, the buffer ring 4 is coupled to the lower portion of the back head (2), the ring 3 is coupled to the lower portion of the buffer ring 4, the pipe (below the ring 3) 5) is coupled, the valve cap 6 is coupled to the lower portion of the pipe (5), one end of the valve spring (7) is inserted into the lower portion of the valve cap (6), the other end of the valve spring (7) Is inserted into and installed in the valve (8), the valve (8) is installed in the valve housing (9) in which the housing inner (10) is installed, and the piston (11) is inserted into the inner lower part of the valve housing (9). , The ring 12, the piston bush 13, the bit ring 14 is sequentially installed in the lower portion of the piston 11, the bit is installed in the lower portion of the bit ring 14, the present invention is inside the valve housing According to the position of the piston installed in the piston, the upper and lower positions of the high pressure water is sequentially supplied while being driven is a significant effect The.

Description

Water powered hammer

The present invention relates to a hammer driven by water, and more particularly, to a hammer driven by water driven while the high pressure water is sequentially supplied to the upper and lower positions of the piston according to the position of the piston.

In general, in order to increase the safety of the ground by erecting a pillar that is the foundation when constructing a building, or to insert a steel pipe in the form of an arch when digging a tunnel, the ground is first excavated to a predetermined depth. As shown in FIG. 1, a heavy pressure propulsion apparatus 100 installed at a place where a rod 120 is to be mounted, a drilling rig 110 connected to the heavy pressure propulsion apparatus 100, and a drilling rig 110. The rod 120 is supported and rotated by, and the hammer 130 is coupled to one end of the rod 120 and the like.

And the conventional air hammer (Registration No. 10-783777) that the applicant has already applied for the air hammer wear sleeve because the air used in the wear sleeve has a low density, so that the wind speed should be about 30 m / sec to push up the debris due to the perforation, The air discharge passage formed in the has a disadvantage that requires a large cross section.

     Therefore, the water hammer that solves this problem is that the hammer is operated with water, the present applicant has applied for a water driven hammer as 10-2010-70959, the prior art is a hydraulic pressure section including a wear sleeve, drilling rod The hammer is driven by a water comprising a back head coupled to the bottom of the hammer, and a hammer bit and a casing bit, the wear sleeve of the hydraulic portion is characterized in that the spiral water discharge passage is formed.

     In addition, the water pressure portion of the hammer driven by water includes a back head, a wear sleeve, a check valve, a buffer, a water distributor, a cylinder, a piston, a chuck, and the like. The wear sleeve is coupled to, the chuck is coupled to the bottom of the wear sleeve, the check valve is installed in the water inlet hole formed in the back head and the inside of the wear sleeve, buffering is installed along the outer periphery of the lower end of the back head, A water distributor is installed at the lower part of the buffering to lower the piston properly, and a cylinder is installed at the lower part of the check valve and the water distributor in the wear sleeve, and the piston is located at the lower part of the cylinder to move up and down by high pressure water. By hammering and hammering the hammer bit coupled to the chuck, the chuck is fixed and supported by the hammer bit as well as the water driven by the movement to move In the, in the wear sleeve of the hammer driven by the water it is characterized in that it is formed with a water discharge passage of the spiral.

The outer diameter of the wear sleeve is smaller than the outer diameter of the bit.

     However, the prior art as described above has a difficulty in sequentially supplying the high pressure water to the upper and lower positions of the piston, thereby causing a failure in the hammer driven by the water.

Therefore, the present invention has been made to solve the above problems, to provide a hammer driven by water driven by supplying high pressure water sequentially to the upper and lower positions of the piston according to the position of the piston installed inside the hammer. will be.

The present invention relates to a hammer driven by water, the buffer ring 4 is coupled to the lower portion of the back head (2), the ring 3 is coupled to the lower portion of the buffer ring 4, the pipe (below the ring 3) 5) is coupled, the valve cap 6 is coupled to the lower portion of the pipe (5), one end of the valve spring (7) is inserted into the lower portion of the valve cap (6), the other end of the valve spring (7) Is inserted into and installed in the valve (8), the valve (8) is installed in the valve housing (9) in which the housing inner (10) is installed, and the piston (11) is inserted into the inner lower part of the valve housing (9). A ring 3, a piston bush 13, and a bit ring 14 are sequentially installed below the piston 11, and a bit is installed below the bit ring 14.

The present invention has a remarkable effect that is driven while the high pressure water is sequentially supplied to the upper and lower positions of the piston according to the position of the piston installed in the valve housing.

1 is an exploded view of an upper valve housing of a hammer driven by the present invention
Figure 2 is an exploded view of the lower piston part of the hammer driven by the present invention
3 is a view of a wear sleeve of a hammer driven by the present invention
Figure 4 is an assembly drawing of the hammer driven by the present invention
Figure 5 is a water flow diagram when the piston of the hammer driven by the present invention is located in the lower initial position
Figure 6 is a water flow diagram when the piston of the hammer driven by the present invention is located in the middle
Figure 7 is a water flow diagram when the piston of the hammer driven by the present invention is located at the top
8A, 8B, 9A, and 9B are vertical cross-sectional views showing piston operation relationships and corresponding vertical flow paths.

The present invention relates to a hammer driven by water, the buffer ring 4 is coupled to the lower portion of the back head (2), the ring 3 is coupled to the lower portion of the buffer ring 4, the pipe (below the ring 3) 5) is coupled, the valve cap 6 is coupled to the lower portion of the pipe (5), one end of the valve spring (7) is inserted into the lower portion of the valve cap (6), the other end of the valve spring (7) Is inserted into and installed in the valve (8), the valve (8) is installed in the valve housing (9) in which the housing inner (10) is installed, and the piston (11) is inserted into the inner lower part of the valve housing (9). The ring 12, the piston bush 13, and the bit ring 14 are sequentially installed at the lower part of the piston 11, and the bit is installed at the lower part of the bit ring 14.

     In addition, when the piston 11 is at the bottom end of the valve housing 9 and does not block the lower horizontal hole 17a formed at the lower part of the valve housing 9, water is formed in the vertical direction of the valve housing 9 in the vertical direction. After entering the valve housing 9 along the vertical flow path 16a, passing through the lower horizontal hole 17a, and then through the valve horizontal hole 19 formed in the longitudinal center of the valve 8, the internal hollow of the piston 11 It is characterized by being drawn in and outflow.

     In addition, when the piston 11 is in the middle of the valve housing 9 to block the lower horizontal hole 17a formed in the lower portion of the valve housing 9, water is formed in the vertical direction of the valve housing 9 in the vertical direction. After the housing 9 is drawn along the vertical flow path 16a, the housing 9 flows downward to fill the space between the piston 11 and the wear sleeve 1.

     In addition, the piston 11 is at the top of the valve housing 9 to block the lower horizontal hole 17b formed in the lower part of the valve housing 9, and also to the upper horizontal hole 18a in the space 15 of the valve portion. , 18c are positioned together and filled with water by the upper horizontal hole 18a into the space 15 of the valve portion so as to communicate with each other.

     The present invention will be described in detail with reference to the accompanying drawings. 1 is a partial exploded view of the upper valve housing of the hammer driven by the present invention, Figure 2 is a partial exploded view of the lower piston of the hammer driven by the present invention, Figure 3 is a wear sleeve of the hammer driven by the present invention, Figure 4 is 5 is an assembly drawing of the hammer driven by the present invention, FIG. 5 is a flow diagram when the piston of the hammer driven by the present invention is located at the lower initial position, and FIG. Fig. 7 is a flow diagram when the piston of the hammer driven by the present invention is positioned at the top. Figs. 8A, 8B, 9A, and 9B are vertical cross-sectional views showing a vertical flow path corresponding to a piston operation relationship.

     In the present invention, the buffer ring 4 is coupled to the lower portion of the back head 2, and the ring 3 is coupled to the buffer ring 4. A pipe 5 is installed below the ring 3, and a valve cap 6 is coupled to the bottom of the pipe 5, and one end of the valve spring 7 is inserted into and installed below the valve cap 6. The other end of the valve spring 7 is inserted into the valve 8.

     The valve 8 is installed inside the valve housing 9 in which the housing inner 10 is installed.

     Accordingly, the piston 11 is inserted into the lower part of the valve housing 9, and the ring 12, the piston bush 13, and the bit ring 14 are sequentially installed in the lower part of the piston 11, and the bit A bit is installed below the ring 14.

    On the other hand, in the operation method of the water-driven hammer of the present invention, the lower horizontal hole (17a) formed in the lower portion of the valve housing 9 in the initial state in which the piston 11 is at the bottom of the valve housing (9) After the water is introduced along the vertical passage 16a of the valve housing 9 formed in the vertical direction of the valve housing 9, the water passes through the lower horizontal hole 17a, and then the valve 8 longitudinal direction. It enters into the inner hollow part of the piston 11 through the valve horizontal hole 19 formed in the center, and will flow out.

     Afterwards, when a person raises the piston a little by using a manpower or a mechanism, the piston is operated to raise the piston 11 and to be in the middle of the valve housing 9 to open the lower horizontal hole formed in the lower part of the valve housing 9. When closing, water is drawn along the vertical flow path of the valve housing 9 formed in the vertical direction of the valve housing 9, and then flows downward to fill the space between the piston 11 and the wear sleeve 1. And the pressure raises the piston further upwards.

     Then, the piston 11 is raised to be at the top of the valve housing (9) to block the lower horizontal hole (17b) formed in the lower portion of the valve housing (9), and also the upper portion in the space (15) of the valve portion The horizontal holes 18a and 18c are located together and filled with water by the upper horizontal holes 18a into the space 15 of the valve portion so as to communicate with each other. And the pressure lowers the raised piston at a high speed, and the bit mounted at the bottom of the hammer operated by the present invention excavates the ground.

     Therefore, the present invention has a remarkable effect of being driven while the high pressure water is sequentially supplied to the upper and lower positions of the piston according to the position of the piston installed inside the valve housing.

1: Wear sleeve 2: Back head
3: Ring 4: Buffer ring
5: Pipe 6: Valve Cap
7: Valve spring 8: Valve
9: Valve housing 10: Housing inner
11: Piston 12: Ring
13: Piston Bush 14: Bit Ring
15: space of the valve portion 16: vertical flow path
17a, 17b: lower horizontal hole 18a, 18b, 18c: upper horizontal hole
19: valve horizontal hole

Claims (4)

A buffer ring 4 is coupled to the lower portion of the back head 2, a ring 3 is coupled to the lower portion of the buffer ring 4, and a pipe 5 is coupled to the lower portion of the ring 3, and the pipe 5 is connected thereto. The valve cap 6 is coupled to the lower portion, one end of the valve spring 7 is inserted into the lower portion of the valve cap 6, and the other end of the valve spring 7 is inserted into the valve 8. The valve 8 is installed inside the valve housing 9 in which the housing inner 10 is installed, and a piston 11 is inserted into an inner lower portion of the valve housing 9, and a ring (lower) is provided in the lower portion of the piston 11. 3), the piston bush 13, the bit ring 14 is installed in sequence, the lower portion of the bit ring in the hammer driven by the water is installed,
When the piston 11 is at the lowermost end of the valve housing 9 and does not block the lower horizontal hole 17a formed below the valve housing 9, water is formed in the vertical direction of the valve housing 9. (9) After entering along the vertical flow path (16a), after passing through the lower horizontal hole (17a), through the valve horizontal hole (19) formed in the longitudinal direction of the valve (8) into the internal hollow portion of the piston (11) To spill,
When the piston 11 is in the middle of the valve housing 9 to block the lower horizontal hole 17a formed in the lower part of the valve housing 9, water is formed in the vertical direction of the valve housing 9 in the valve housing ( 9) After being drawn along the vertical flow path 16a, it flows downward to fill the space between the piston 11 and the wear sleeve 1,
The piston 11 is at the top of the valve housing 9 to block the lower horizontal hole 17b formed in the lower part of the valve housing 9, and also the upper horizontal holes 18a and 18c in the space 15 of the valve portion. ) Are hammered with water, characterized in that they are located together and filled with water by the upper horizontal hole (18a) into the space (15) of the valve portion to communicate with each other delete delete delete

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