KR20100089050A - Water operating hammer - Google Patents

Abstract

PURPOSE: A hammer operated using water, which has a discharge groove for water and sludge from a wear sleeve, is provided to increase the service life of a hammer and to reduce costs for replacing hammers. CONSTITUTION: A hammer operated using water comprises a casing, a water pressure part, a back head, a hammer bit and a casing bit. The water pressure part comprises a wear sleeve(322). The back head is combined on the bottom of a drilling rod. The water exhaust path of spiral shape is formed on the wear sleeve of the water pressure part.

Description

Water driven hammer {WATER OPERATING HAMMER}

The present invention relates to a hammer driven by water in which a groove for discharging water and sludge (crushed female pieces) is formed in a wear sleeve of a hammer driven by water.

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.

In addition, since the air hammer used in the wear sleeve has a low density of air, the air blower formed in the air hammer wear sleeve has a large air discharge path. There was a disadvantage that required a cross section.

Therefore, in the present invention, since the water used for the hammer driven by water has a high density, the discharge speed of the water does not have to be fast, so that the cross section of the discharge passage of the water discharge groove formed in the hammer wear sleeve driven by the water may be reduced. In addition, the water discharge passage on the wear sleeve is formed in a spiral shape in consideration of the rotation of the hammer and the speed of water discharge during the drilling process, so that the water discharge is substantially linear, thereby reducing the water resistance and consequently reducing the wear or damage of the bit due to the excavation work. It is intended to provide a hammer driven by water, which reduces the cost of replacement and reduces the cost of the hammer by extending the life of the hammer.

The present invention relates to a water-driven hammer, casing 310, a hydraulic pressure section including a wear sleeve 322, a back head 321a coupled to the lower end of the drilling rod 120 and In the hammer driven by the water comprising a hammer bit 330 and the casing bit 340, the wear sleeve 322 of the pressure receiving portion is characterized in that the spiral water discharge passage is formed.

Therefore, since the water used for the hammer driven by the water of the present invention has a high density, the discharge speed of the water does not have to be fast, so that the water discharge passage is formed small in the wear sleeve, and the rotation of the hammer and the discharge speed of the water are considered in the drilling process. Therefore, it is formed in a spiral shape so that the discharge of water becomes substantially linear, thereby reducing the resistance of the water and consequently reducing the wear or damage of the bit due to the excavation work, thereby reducing the replacement cost and prolonging the life of the hammer, thereby reducing the cost. .

1 is a schematic diagram for explaining a ground excavation method of a hammer driven by water of the present invention.
Figure 2 is an internal cross-sectional view for explaining the water pressure portion of the hammer driven by the water of the present invention.
3 is a perspective view for explaining a casing bit of a water driven hammer of the present invention.
4 is a bottom view for explaining a casing bit of a water driven hammer of the present invention.
Figure 5 is a perspective view for explaining the casing bit mounting state of the hammer driven by the water of the present invention.
Figure 6 is a perspective view of the water driven hammer of the present invention
7 is a detailed view of a wear sleeve of a hammer driven by the water of the present invention.
8 is a plan view of a water driven hammer of the present invention.
9 is a front view of a water driven hammer of the present invention.

The present invention relates to a water-driven hammer, a hydraulic pressure unit 400 including a wear sleeve 322, a back head 321a coupled to the lower end of the drilling rod 120, a hammer bit 330 and In the water-driven hammer comprising a casing bit 340, the wear sleeve 322 of the pressure receiving portion is characterized in that the spiral water discharge passage is formed.

     In addition, the water pressure unit 400 of the hammer driven by water includes a back head 321a, a wear sleeve 322, a check valve 323a, a buffering 326c, a water distributor 424a, and a cylinder. 325, a piston 326a, a chuck 327, and the like, and a wear sleeve 322 is coupled to a lower end of the back head 321 a, and a chuck (below) to the lower end of the wear sleeve 322. 327 is coupled, and a check valve 323a is installed in the water inlet hole formed in the back head 321a and the wear sleeve 322, and buffers 326c along the outer circumference of the lower end of the back head 321a. Is installed, and a water distributor 424a is installed at the lower portion of the buffer ring 326c to properly lower the piston 326a, and the cylinder 325 is provided with a check valve 323a and an inner portion of the wear sleeve 322. It is installed in the lower portion of the water distributor 424a, the piston 326a is located in the lower portion of the cylinder 325 is coupled to the chuck 327 as the vertical movement by the high pressure water The hammer bit 330 strikes and drills, and the chuck 327 fixes and supports the hammer bit 330, as well as the hammer driven by the water to move, the spiral of the wear sleeve of the hammer driven by the water The water discharge passage is characterized in that it is formed.

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

The present invention will be described in detail with reference to the accompanying drawings. 1 is a schematic view for explaining the ground excavation method of the hammer driven by water of the present invention, Figure 2 is an internal cross-sectional view for explaining the hydraulic portion of the hammer driven by the water of the present invention, Figure 3 is driven by the water of the present invention 4 is a bottom view illustrating a casing bit of a hammer driven by water of the present invention, and FIG. 5 is a diagram illustrating a casing bit mounting state of a hammer driven by water according to the present invention. 6 is a perspective view of the water-driven hammer of the present invention, Figure 7 is a detailed view of the wear sleeve of the water-driven hammer of the present invention, Figure 8 is a plan view of the water-driven hammer of the present invention, 9 is a front view of a water driven hammer of the present invention.

The water pressure unit 400 of the hammer driven by water includes a back head 321a, a wear sleeve 322, a check valve 323a, a buffer ring 326c, and a water distributor. 424a, cylinder 325, piston 326a, chuck 327, and the like.

In such a configuration, the wear sleeve 322 is a main frame of the hydraulic unit, and upper and lower threads of the wear sleeve 322 are formed to engage the back head 321 a and the chuck 327, and the wear sleeve 322 is There is no need to specifically limit the material, but it is preferable to use a material used for a gun barrel having excellent durability and strength, or a material having an equivalent strength.

The back head 321a is to allow the drilling rod (120 of FIG. 1) and the air hammer 300 inserted into the ground to be connected to each other, and the rod (120 of FIG. 1) is formed at the top of the back head 321a. Screw thread is formed to enable connection with the inside, and a through hole through which the high pressure water supplied through the rod (120 in FIG. 1) is formed therein.

At this time, the back head 321a should be coupled to and supported by the lower portion of the wear sleeve 322, and the back head washer 321b is interposed between the back head 321a and the wear sleeve 322. The coupling is improved, and further, the back head O-ring 321c can be used to seal the coupling portion of the back head 321 a and the wear sleeve 322.

The check valve 323a is for preventing the back flow of water pressure during the operation of the hammer. The check valve 323a is provided below the check valve 323a installed in the high pressure water inlet hole formed in the back head 321a and the wear sleeve 322. The spring 323b is installed to enable the vertical movement of the check valve 323a.

The buffer ring 326c is for absorbing the impact of the piston 326a to be described later, which is provided along the outer circumference of the lower end of the back head 321a. The water distributor 424a installed at the lower portion of the buffer ring 326c is for distributing the high pressure water evenly so that the piston 326a can be properly lowered. A plurality of holes are formed in the water distributor 424a.

In this case, when the holes are not evenly drilled, the hammer bit 330, which will be described later, may be damaged because the piston 326a may not be driven evenly, so that the plurality of holes are formed at equal positions and intervals. desirable. In addition, the water distributor O-ring 324b may be installed between the water distributor 424a and the wear sleeve 322 so that the high pressure water may be sealed when the water distributor 424a is combined with the wear sleeve 322. desirable.

The cylinder 325 is for applying the high pressure water to the piston 326a to enable the vertical movement of the piston 326a, and the check valve 323a and the water distributor 424a inside the wear sleeve 322. It is installed at the bottom. And, the piston 326a is located in the lower portion of the cylinder 325 by hitting the hammer bit 330 coupled with the chuck 327 as the vertical movement by the high-pressure water as described above to drive.

At this time, the piston stop ring 326b is installed on the inner wall surface of the wear sleeve 322 as the lowest end of the piston 326a movement position so that the piston 326a strokes only a certain distance. In addition, a bit retainer ring 329a is installed between the hammer bit 330 and the wear sleeve 322 to support the hammer bit 330 so that the hammer bit 330 can be lowered only by a predetermined distance, and the bit retainer ring ( O-rings for airtightness are to be provided on the outer periphery of 329a).

The chuck 327 is intended to fix and support the hammer bit 330 as well as to support the hydraulic pressure unit. The chuck 327 installed in the wear sleeve 322 has a spline formed therein. Guide the vertical movement of the hammer bit 330, as well as the hammer bit 330 is rotated in accordance with the rotation of the casing.

The hammer bit 330 as described above is for crushing the rock directly, the bottom of the hammer bit 330 is embedded with a tip such as hard stone material, the shape of the tip and the bottom shape of the hammer bit 330 It is also divided into a hard rock and a soft rock.

By such a configuration, when high pressure water first flows through the back head 321a, the high pressure water introduced pushes the check valve 323a and passes through the water distributor 424a along the outer surface of the cylinder 325. Filling the lower space, the high pressure water is pushed up the piston (326a).

At this time, the pushed up piston 326a is raised while compressing the water of the upper portion, the water of the upper portion compressed at the maximum rising position pushes down the piston 326a with a stronger force than the pushed up water, a strong force The piston 326a pushed down to hit the hammer bit 330 and the high pressure water above the piston 326a may be discharged through the discharge hole formed in the hammer bit 330 (see 331 of FIG. 6). It is configured to be.

In addition, the main technical characteristics of the present invention, the air used in the conventional air hammer had to have a high discharge wind speed, but the high pressure water used in the hammer wear sleeve driven by the water of the present invention has a higher density than the air, the speed is Even though it is slow, it serves to push up the debris due to the perforation sufficiently, so that the water discharge passage formed in the water driven hammer wear sleeve does not require a larger cross section than air. Therefore, the speed of air is 30 m / sec, whereas water may be 0.8 m / sec to 1.2 m / sec.

The water discharge passage formed in the water-driven hammer wear sleeve has a width of 15 mm to 30 mm, a diameter of 120 mm to 130 mm, and usually 127 mm.

The depth is 8mm to 12mm, and above all, the flow rate of water discharged based on the outer diameter of the hammer bit 330, the outer diameter of the wear sleeve 322, and the area of the groove of the wave may be 0.8 m / sec to 1.2 m / sec.

In addition, the outer diameter of the wear sleeve is slightly smaller (about 98%) than the outer diameter of the bit to guide the inside of the drill for good straightness during the drilling process. In addition, the groove of the wave, which is the water discharge passage, is spiraled so that the discharge of water can be linear in consideration of the rotation of the water driven hammer and the discharge speed of the water during the drilling process.

And if the water discharge passage is formed in a straight line in the wear sleeve, the hammer rotation and water discharge speed are not taken into consideration during the drilling process, so the discharge of water is not substantially linear, resulting in severe water resistance and consequently the wear of the bit due to the excavation work. Alternatively, the damage is excessive, there is a fear that the bit replacement cost is large, and the life of the hammer is shortened.

    Therefore, the hammer driven by water of the present invention forms a water discharge passage in the wear sleeve in a spiral shape in consideration of the rotation of the hammer during the drilling process and the discharge rate of water so that the discharge of water becomes substantially linear, thereby reducing the resistance of the water and consequently digging. Less wear or damage to the bit due to work.

100: medium pressure propulsion device 110: drilling rig
120: rod 130, 210: hammer
220, 330: hammer bits 211, 310: casing
212, 312: screw 321a: backhead
322: wear sleeve 322-1: water discharge groove
323a: check valve 325: cylinder
326a: Piston 326c: Buffering
327 Chuck 330 Hammer Bits
340: casing bit 344: sludge discharge groove
213, 345 tip 400: hydraulic part
424a: Water Dispenser

Claims (2)

Casing 310, the hydraulic unit 400 including the wear sleeve 322, the back head 321a coupled to the lower end of the drilling rod 120, hammer bit 330 and casing bit 340 The hammer driven by water, comprising a water discharge groove (322-1) is formed in the wear sleeve (322). The water driven hammer of claim 1, wherein the water discharge groove (322-1) is spiral.

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