KR200415409Y1 - Agitating device for improving ground with plural hammers - Google Patents

Abstract

The present invention relates to an agitator for improving the ground, wherein an air supply pipe is formed therein, and an auger shaft rotated by a driving motor, and the tip of the auger shaft extends downward by a predetermined length, has a lower portion at the extended tip. It is formed to be open, but the inside of the hollow-cylindrical casing consisting of a plurality of hollow-cylindrical cylindrical receiving portion, and a plurality of known drilling hammer coupled in communication with the air supply pipe by a predetermined coupling means inside each of the receiving portion, characterized in that It is done.

Auger Shaft, Receptacle, Casing, Drilling Hammer

Description

Ground improvement stirring apparatus having a plurality of hammers {AGITATING DEVICE FOR IMPROVING GROUND WITH PLURAL HAMMERS}

1 is a front view of the ground improvement stirring device according to the present invention,

Figure 2 is a cross-sectional view of the ground improved stirring apparatus according to the present invention,

3 is a partial exploded cross-sectional view of the ground improvement stirring device according to the present invention,

4 is an enlarged cross-sectional view of a pneumatic drilling hammer as an excavation hammer mounted to the auger shaft tip of the ground improvement stirring device according to the present invention,

5 is a perspective view of an inner cylinder of the components constituting the pneumatic drilling hammer of FIG. 4, and

6 is a perspective view of a hammer bit of the components constituting the pneumatic drilling hammer of FIG.

The present invention relates to a ground improvement stirring device, and more particularly, to a ground improvement stirring device having a plurality of hammers.

In general, when constructing a structure directly on the ground, if the ground is soft ground composed of soft soil such as sea clay, stratified clay, etc., the ground is improved and reinforced, and rivers, reservoirs, embankments, In the case of requiring landfills such as landfills, vertical walls are being formed in the ground.

The ground stirring device used for the improvement of the soft ground and the formation of the vertical order wall is usually made by digging into the desired ground to a desired depth and spraying a high binder such as cement paste or solidified material to remove the ground. By stirring the high binder, the ground is improved or the order walls are formed.

However, in digging into the ground to be improved, when rock layers such as weathered rock and soft rock or stony layers such as amber stones exist in the ground to be improved, such rock layers or stone layers must be dug into and improved.

Conventional ground improvement agitator disclosed in Korean Patent Application Publication No. 10-2004-0025527, filed by the present applicant and published on March 24, 2004, includes an excavation blade for crushing and excavating a rock layer or a stone layer. In addition, a pneumatic drilling hammer is adopted at the bottom of the auger shaft.

The drilling hammer includes a hammer bit whose upper surface is hit by a piston reciprocating by pneumatic pressure, and strikes a rock layer or the like by a plurality of protrusions provided on the lower surface by a piston strike.

In addition, since the hammer bit is splined to the auger shaft, the hammer bit is moved up and down by the impact of the piston and simultaneously rotates with the auger shaft.

However, according to the conventional ground improvement stirring device, since one drilling hammer is mounted on one auger shaft, a drilling hammer having a diameter of 6 inches or 8 inches is usually used. When the drilling hammer having a large diameter is used in this way, the area of contact with the rock layer is increased, so that the impact strength is reduced.

In general, a 6-inch diameter drilling hammer mounted on the ground improvement stirring device is about 6 million won, 8-inch diameter drilling hammer price is about 8 million won, 4 inch diameter drilling hammer price 200 It is about 10,000 won. Therefore, the use of one 6-inch or 8-inch diameter drilling hammer has a problem that the drilling diameter is small compared to the use of two 4-inch diameter drilling hammers.

The present invention has been made to solve the above problems, and one object of the present invention is to provide a ground improvement stirring device configured to have a large impact strength and a large excavation diameter.

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In order to achieve the above object of the present invention, the ground improvement stirring device of the present invention, the air supply pipe is formed therein and rotated by a drive motor, and the tip of the auger shaft extends downward by a predetermined length Thereafter, a lower portion is formed to be opened at the extended tip, and a plurality of hollow-cylindrical casings are formed inside the plurality of hollow-cylindrical cylinder accommodating portions, and a plurality of contiguously coupled to the air supply pipes by predetermined coupling means inside the respective accommodating portions. It is characterized by including a known drilling hammer.

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Hereinafter, an embodiment of the ground improvement stirring device according to the present invention will be described in detail with reference to the drawings.

As shown in Figure 1 and 2, in the ground improvement stirring apparatus according to the present invention, a plurality of hollow park cylindrical receiving portion 110 is formed in the hollow park cylindrical casing 10 formed at the tip of the auger shaft 21, Each of the plurality of hollow cylindrical accommodating portions 110 is provided with a plurality of well-known drilling hammers 200, respectively.

In the present embodiment, the hollow park cylindrical receiving portion 110 and the excavation hammer 200 are each formed two.

In the ground improvement stirring apparatus, the auger shaft 21 is usually composed of three. In the present embodiment, the auger shaft 21 located at the center of the three auger shafts 21 is provided with a high binder supply pipe 21a. Excavation wing 24 is installed, the auger shaft (21) located on both sides has been illustrated that the drilling hammer 200 and the feed screw 130 is installed. The three auger shafts 21 are connected to each other by a known connecting rod 300.

The high binder supply pipe 21a is formed in the axial direction inside the central auger shaft 21, and the excavation blade 24 is provided at the tip of the central auger shaft 21. As shown in FIG. The drilling bit 24a is formed in the bottom surface of the front end of the drilling blade 24. Then, the drilling hammer 200 is provided at the front end of the auger shaft 21 on both sides, the feed screw 130 is provided on the outer peripheral surface of the casing of the excavation hammer 200 of the auger shaft 21 on both sides.

In this embodiment, after the front end of both auger shafts 21 extends downward by a predetermined length, the hollow-cylindrical casing 10 whose lower part is opened is formed in this extended front end. Inside the casing 10, a plurality of hollow park cylindrical accommodating portions 110 are formed.

Inside the both auger shaft 21, the air supply pipe 120 is formed in the axial direction.

In addition, as illustrated in FIG. 3, an internal thread portion 115 is formed in the upper inner center of the accommodating part 110 so as to be connected to the air supply pipe 120 of the auger shaft 21. A male screw portion 216a is formed at the rear end of the drilling hammer 200 as described in detail below. The female screw portion 115 of the receiving portion 110 and the male screw portion 216a of the drilling hammer 200 function as coupling means for coupling the receiving portion 110 and the drilling hammer 200 to each other. It will be appreciated that any other coupling means is possible without being limited thereto.

Excavation hammer 200 coupled to the receiving portion 110 formed at the tip of the auger shaft 21 is known, in the present embodiment is illustrated as using a pneumatic drilling hammer 200 as a drilling hammer, hydraulic drilling A hammer, an electric drill hammer, or the like may be applied.

As shown in detail in FIG. 4, the pneumatic drilling hammer 200 includes a sleeve 210 into which compressed air is introduced through an air inlet hole 216b of a coupling head 216 fitted to a rear end thereof, and an air inlet hole ( Check valve 280 for selectively opening and closing the check end 216c formed in the coupling head 216 by the action of the compressed air and spring 182 introduced through the 216b, the check valve 280 is in the longitudinal direction A valve chest 270 having a valve guide portion 272 mounted to be slidably and having a plurality of recess grooves 274 through which compressed air passes, and a valve 260 fitted to an outer circumferential surface of the rear end thereof. In the circumferential direction, the valve seat 250 in which a plurality of circumferential holes 254 are formed and the compressed air introduced along the outer circumferential surface of the valve seat 250 slide in the longitudinal direction along the inner wall of the sleeve 210. A piston 230 that is movably mounted, the piston The rear end portion 233 of the 230 is a rock layer formed by a plurality of protrusions 222 of the inner end 240 while the inner cylinder 240 is slidably embedded, and the piston 230 is repeatedly moved along the longitudinal direction. The hammer bit 220 to strike the strike, and the chuck 212 is coupled to the front end of the sleeve 210 to move the hammer bit 220 in the longitudinal direction.

On the outer circumferential surface of the rear end of the coupling head 216 coupled to the rear end of the sleeve 210, a male screw portion 216a for engaging with the female screw portion 115 of the receiving portion 110 is formed. In addition, the coupling head 216 is hermetically screwed to the rear end of the sleeve 210 via the O-ring 284. The valve rear end 280b of the check valve 280 that selectively blocks the inflow of compressed air has a structure capable of closing the check end 216c of the coupling head 216, and has a spring at the valve front end 280a. 282 is fitted.

An O-ring 288 is fitted to the rear end of the valve seat 250 to maintain airtightness with the valve chest 270, and an O-ring 286 for airtightness with the inner cylinder 240 is fitted on the outer circumferential surface thereof. Inside the piston 230, a through hole 234 through which compressed air introduced along the outer circumferential surface of the valve seat 250 strikes the piston 230 and passes therethrough. The rear end of the through hole 234 is guided to slide in the longitudinal direction while being inserted into the piston guide part 252 formed at the front end of the valve seat 250. Similarly, the front end of the through hole 234 is guided to slide along the longitudinal direction while being inserted into the piston guide part 228 formed at the rear end of the hammer bit 220.

The rear end portion 233 of the piston 230 has its outer peripheral surface sliding along the inner wall of the inner cylinder 240, and the middle portion 236 of the piston 230 also has its outer peripheral surface extending the inner wall of the sleeve 210. Sliding along, and directly to the price end 226 of the hammer bit 220 through the tip 232. A plurality of through holes 242 and 244 are formed at the front end of the inner cylinder 240 into which the rear end 233 of the piston 230 is inserted. The outer peripheral surface of the rear end of the hammer bit 220 is moved along the length direction in a state supported by the bit ring 214. An air discharge hole 224 is formed in the hammer bit 220 to be connected to the through hole 234 of the piston 230.

In FIG. 5, the inner cylinder 240 is shown in detail as a perspective view. As shown in FIG. 5, the outer circumferential surface of the valve seat 250 is provided with a plurality of grooves 258 by a plurality of protrusions 256. In operation, compressed air introduced through the groove 258 is supplied downward. In addition, a plurality of through holes 242 and 244 are formed below the inner cylinder 240. Among these, the upper second row through hole 244 is arranged to cross the lower first row through hole 242 in the circumferential direction, and is formed less than the first row through hole 242.

In FIG. 6, the hammer bit 220 is shown in detail as a perspective view. As shown in FIG. 6, the outer circumferential surface of the price end 226 of the hammer bit 220 is provided with a plurality of protrusions. In addition, a screw portion 212a screwed to the tip of the sleeve 210 is formed on the outer circumferential surface of the chuck 212 that is splined to allow the hammer bit 220 to move in the longitudinal direction.

In the pneumatic drilling hammer configured in this way, if the compressed air supplied from the compressor through the air supply pipe 120 is introduced through the inlet hole 216b of the coupling head 216, the spring 282 is compressed by pneumatic check valve The check end 216c blocked by the rear end 280b of 280 is opened. The compressed air introduced into the open gap passes through the groove 274 formed in the valve chest 270 and the groove 258 of the valve seat 250 in order, and then the first row through hole 242 of the inner cylinder 240. Through the impact on the rear end surface of the middle portion 236 of the piston 230. At this time, since the second row through hole 244 of the inner cylinder 240 is blocked by the rear end 233 of the piston 230, the compressed air is a through hole of the piston 230 through the second row through hole 244. 234 does not flow.

When the compressed air impinges on the rear end surface of the middle portion 236 of the piston 230 through the first row through hole 242 of the inner cylinder 240, the piston 230 follows the inner wall of the inner cylinder 240. While advancing rapidly, the hammer bit 220 is pushed forward by vigorously hitting the price end 226 of the rear end of the hammer bit 220 through the tip end 232 of the piston.

When the ground layer to be improved is a rock layer such as a weathered rock layer or soft rock layer or a rock layer such as amber stone, when compressed air is supplied at a high pressure, the hammer bit 220 advances at a high speed along the inner wall of the chuck 212 at the tip. The rock layer is crushed by hitting the rock layer or the rock layer through a plurality of attached protrusions 222. The hammer bit 220 which discharges the compressed air after striking the rock layer or the rock layer retreats upward by recoil.

When the piston 230 advances downward, the second row through hole 244 blocked by the rear end 233 of the piston 230 is opened, and the compressed air continues to be supplied, so that the piston 230 moves downward. In this state, the compressed air is introduced into the through hole 234 of the piston 230 through the second row through hole 244 and then discharged downward of the hammer bit 220 through the air discharge hole 224. Therefore, the compressed air discharged downward of the hammer bit 220 through the air discharge hole 224 serves to push the rock fractured by the hammer bit 220 upwards, so that the hammer bit 220 performs excavation work. Allow you to continue.

Compressor for supplying compressed air to the ground improvement agitator is to be mounted separately to the ground improvement agitator, which has not been described in detail herein, and the air supply pipe 120 of the auger shaft 21 is connected to the compressor. You will see that.

In addition, since the compressed air discharged below the hammer bit 220 serves to disturb and disrupt the ground to be ground to be improved, the ground to be ground is more finely ground.

In addition, a feed screw 130 is formed on the outer circumferential surfaces of the auger shaft 21 and the casing 10. The feed screw 130 that rotates in accordance with the rotation of the auger shaft 21 pulls up the ground to be ground to be improved, the drilling bit 24a of the excavation wing 24 and the hammer bit 220 of the excavation hammer 200. To continue the excavation work.

In addition, a check valve may be installed in the air flow path inside the excavation hammer 200. In the present embodiment, it is illustrated that the check valve 290 is installed in the air inlet hole 216b of the coupling head 216 inserted into the rear end of the drilling hammer 200. The check valve 290 opens when air passing through the air inlet hole 216b flows downward but closes when it flows upward, so that the air blown out from the hammer bit 220 of the drilling hammer 200 is improved. After bumping against the soil or stone to prevent backflow into the air supply pipe 120 of the auger shaft 21 to prevent contamination of the air supply pipe 120 of the auger shaft 21.

As described above, according to the ground improvement stirring device of the present invention, in the hollow-cylindrical casing, two hollow-cylindrical cylindrical accommodation portions are formed, and in a structure in which a well-known excavation hammer is attached to each of the plurality of hollow cylindrical accommodation portions, excavation is carried out. The use of two 4 inch diameter drilling hammers increases the area of impact to the rock layer, resulting in greater impact strength, while the two 4 inch drilling hammers revolve to increase the drilling diameter. Excavation diameter of the price ratio is larger than the use of one 6 inch to 8 inch diameter drilling hammer worth 10,000 won to 8 million won.

Claims (6)

An auger shaft 21 is formed inside the air supply pipe 120 and rotated by a drive motor, After the tip of the auger shaft 21 extends downward by a predetermined length, the lower end of the auger shaft 21 is formed to be open to the inside of the hollow park cylindrical casing 10 consisting of a plurality of hollow park cylindrical receiving portion 110, The ground improvement stirring device, characterized in that it comprises a plurality of known drilling hammers (200) connected in series with the air supply pipe (120) by a predetermined coupling means inside each of the receiving portion (110). According to claim 1, The hollow park cylindrical receiving portion 110 and the excavation hammer 200 is characterized in that each of the two ground improvement stirring device. The method according to claim 1 or 2, The coupling means is composed of a female screw portion 115 formed in the upper inner center of each of the hollow-cylindrical cylindrical receiving portion 110 and a male screw portion 216a formed at the rear end of the drilling hammer 200, The female screw unit 115 is ground agitation device, characterized in that formed in communication with the air supply pipe (120). The method according to claim 1 or 2, The auger shaft 21 and the outer peripheral surface of the casing 10, characterized in that the feed screw 130 is formed, the stirring device for improving the ground. The method according to claim 1 or 2, Ground agitation device, characterized in that the check valve 290 is installed in the air flow path of the drilling hammer (200). delete

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