KR101839080B1 - A excavating device and construction method of water-intaking facility using it - Google Patents

Abstract

The present invention relates to a method for constructing a water intake facility using an excavation equipment, and more particularly relates to a method of constructing a seawater water collection facility using an excavation equipment, comprising: (a) a step of installing a collector well; (b) a step of setting an excavation main body; (c) a step of performing excavation without separating a hammer from a hammer main body; and (d) a step of separating the hammer main body from the hammer and collecting the hammer main body.

Description

Technical Field [0001] The present invention relates to an excavating apparatus and a water-taking facility using the same,

The present invention relates to a drilling rig capable of separating a hammer for excavation and a method of constructing a water intake facility using the same.

On the beach where the sea and the land are in contact, the natural scenery of the beach is crowded with consumers who consume a large amount of seawater, such as seafood restaurants, shops, and seawater for tourists.

Conventionally, a pump is installed in a seawater consumer, a hose is connected from the pump to the sea surface, and a seawater supply facility is provided to supply seawater through the hose when the pump is operated.

Thus, since the conventional seawater supply facility is configured to supply the sea water by connecting the hose from the pump installed at the seawater consumer site to the sea surface in an exposed state, it is possible to provide the sea water with relatively simple facility It is a fact that it has the merit of doing.

However, when the conventional sea water supply facilities are installed in the seawater demand site and are trying to cover the sea water, there are several problems as follows.

First, since the hose from the seawater consumer to the sea surface is exposed and exposed to the beach, the hose is easily broken or lost due to typhoons or tsunamis, which makes it impossible to use seawater. Or a maintenance cost for restoring the lost hose to the original state.

Second, in most seawater consumers, the hose is connected to the edge of the sea surface by the hose to shorten the length of the hose to inhale the unfiltered seawater. Therefore, floating substances or spores of seaweed or shellfish, There is a problem that the seawater contaminated when the red tide occurs is directly supplied to the seawater consumer.

Third, since the seawater is sucked into the hose only by the suction force of the pump from the sea surface to the seawater demanding place, there is a possibility that the pump is operated in an overload state to cause a failure, and a large- There is a problem in that the power consumption is excessively consumed and the operation cost is increased.

Fourth, there is a problem that the natural landscape of the beach is seriously damaged because the hose which is exposed to the sea surface for each sea water demand causes the phenomenon that the hose is jammed on the beach and disorganized and scattered.

In order to overcome the above-mentioned problem, the present invention has proposed a patent No. 10-0782359, which overcomes the above-mentioned problem. However, the patent is an invention that is possible when there is no obstacle on the ground layer like sand. If water is found, the intake pipe is out of the scope of the construction plan, and there is a problem that the construction failure occurs or the construction can not be done due to the increase of the press-in pressure of the construction drilling equipment.

Korean Patent No. 10-0782359

SUMMARY OF THE INVENTION The present invention has been made in order to solve the above-mentioned problems, and it is an object of the present invention to provide a water purification system for a water purification system, The present invention is to provide a drilling apparatus and a method of constructing a water intake facility using the same, which can supply water of high quality with high cleanliness by collecting and supplying the seawater by the water pressure by the water head and the natural filtration water collecting method using the sea floor layer.

In order to achieve the above object, the present invention provides a drilling rig coupled to a drilling main body for horizontally excavating a ground for constructing a seawater catchment facility, the drilling rig having one end connected to the drilling main body, A piston having a casing and one end coupled to the inflow hole and having a check valve installed in the casing and a piston moving linearly in the casing by the air discharged from the check valve, A hammer body having first protrusions protruding along the longitudinal direction on the inner circumferential surface at predetermined intervals and having an inner circumferential surface and second protrusions protruding at regular intervals along the inner circumferential surface; And the third protrusions protruding along the longitudinal direction on the outer circumferential surface are formed at regular intervals, Wherein the hammer is inserted into the inner space of the hammer body, the hammer being inserted into the second protrusions, the hammer having one end thereof inserted into the inner space, and a plurality of intake holes, Wherein the hammer main body and the hammer are coupled to the intake pipe at the time of excavation to rotate in one direction so that the third protrusion is caught by the first and second protrusions, So that the hammer is hooked on one end of the water intake pipe, and then the hammer body is pulled out while rotating in the other direction so that the third projection is slipped into the space between the second projections Wherein the hammer body is separated from the hammer and collected therefrom.

The method may further comprise the steps of: (a) installing a collection fixture to be embedded at a predetermined depth in the beach (B) at the location; (b) (C) a tubular casing having one end joined to the excavating body and having an inlet hole at the other end thereof, and one end connected to the inlet hole, so as to face the bottom of the casing And a first protrusion protruding in the longitudinal direction on the inner circumferential surface in a tubular shape provided inside the other end of the casing, A hammer body which is formed at an interval and has an engaging chuck whose one end is protruded at regular intervals along the inner circumferential surface of the second protrusion, A third protrusion protruding along the longitudinal direction on the outer circumferential surface is formed at a predetermined interval, and the third protrusion is inserted between the second protrusions, the hammer having one end thereof fitted to the coupling chuck, Wherein a plurality of water intake holes are formed in the tubular member, and one end of the hammer body is inserted into the inner space, and an excavating equipment including a water intake pipe in which the hammer is hooked at one end is coupled to the excavation body, (C) digging toward the seabed layer, wherein the excavation equipment is rotated in one direction so that the third protrusion is caught by the first and second protrusions to exclude the hammer from the hammer body, ), The hammer body is pulled so that the hammer is hooked on one end of the water intake pipe, and rotates in the other direction so that the third projection is engaged with the second projection By the method of exiting a space provides an intake facility construction method using the drilling equipment, characterized in that comprising the step that the hammer body which is collected separate from the hammer.

The present invention having the above-described configuration has the following effects.

First, the present invention can easily install the water intake pipe according to the construction plan even if the type of the submarine ground layer or the ground such as the rock is found when installing the water intake pipe by the apparatus and method using the excavation equipment. In addition, since the hammer (bit) is detachable, the body of the excavation equipment can be easily separated after the excavation of the stratum, and the body can be reused.

Second, the present invention is a natural filtration water collecting method using a water pressure due to a water head difference from the sea surface and a seabed layer, and collects and supplies clean seawater in which floating matters or spores of seaweeds or fish and shellfishes are reliably removed, Can be supplied.

Third, the present invention is a method of installing a water depth correction near the sea level and then digging the water into the sea floor from the sea water correction and taking in water. In addition to the East Sea which maintains a certain depth, Of sea water.

BRIEF DESCRIPTION OF THE DRAWINGS Figure 1 is a view of an excavation equipment of the present invention.
Fig. 2 is a view showing the separation of the hammer in Fig. 1. Fig.
3 is a cross-sectional view of Fig.
4 is a view showing that a hammer is fitted to a coupling chuck.
5 is a view showing that the engaging projection of the intake pipe is inserted into the engaging groove of the hammer.
6 to 14 are views showing a method of constructing a water intake facility according to the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, an excavation apparatus according to the present invention will be described in detail with reference to the accompanying drawings.

FIG. 1 is a view showing a drilling rig according to the present invention, and FIG. 2 is a view showing that a hammer is separated in FIG.

Fig. 3 is a sectional view of Fig. 1, and Fig. 4 is a view showing that a hammer is fitted to a joining chuck.

5 is a view showing that the engaging projection of the intake pipe is inserted into the engaging groove of the hammer.

The present invention relates to an excavation equipment (10), in particular, to a drilling rig coupled to a drilling body for horizontally excavating a ground for constructing a seawater collection facility, wherein one end is coupled to the excavation body (20) A check valve 120 installed inside the casing 110 with one end connected to the inlet hole 111 and a check valve 120 installed inside the casing 110, A piston 130 which linearly moves in the casing 110 by the air to be discharged and a first protrusion 141 protruding along the longitudinal direction on the inner circumferential surface in a tubular shape provided inside the other end of the casing 110 A hammer main body 100 formed at a predetermined interval and having a first protrusion 142 protruding at regular intervals along an inner circumferential surface of the inner circumferential surface of the hammer main body 100; Follow the longitudinal direction The hammer 200 having one end inserted into the engaging chuck 140 by a method in which the third protrusion 210 is inserted between the second protrusions 142 by a member having protruded third protrusions 210 formed at regular intervals, And a plurality of water intake holes 310, which are holes through which water is taken on the outer circumferential surface, into which one end of the hammer body 100 is inserted into the inner space and the hammer 200 is hooked at one end The hammer body 100 and the hammer 200 are coupled to the water intake pipe 300 while being excavated and rotated in one direction so that the third protrusion 210 is rotated in the first and second The hammers 200 are hooked on the projections 141 and 142 so that the hammers 200 are not separated from the hammer body 100 and the hammers 200 are hooked on one end of the take- 100, and rotates in the other direction to move the third projection 210 into the space between the second projections 142 By the method shown it is characterized in that the hammer body 100 is collected is separate from the hammer (200).

The present invention is composed of a hammer body 100, a hammer 200 and a water intake pipe 300. Even if there is an obstacle such as a rock in the ground layer during excavation from the water collecting compartment 40 toward the seabed, And can reuse the hammer main body.

On the beach where the sea and the land are in contact, the natural scenery of the beach is crowded with consumers who consume a large amount of seawater, such as seafood restaurants, shops, and seawater for tourists.

Conventionally, a pump is installed in a seawater consumer, a hose is connected from the pump to the sea surface, and a seawater supply facility is provided to supply seawater through the hose when the pump is operated.

Thus, since the conventional seawater supply facility is configured to supply the sea water by connecting the hose from the pump installed at the seawater consumer site to the sea surface in an exposed state, it is possible to provide the sea water with relatively simple facility It is a fact that it has the merit of doing.

However, when the conventional sea water supply facilities are installed in the seawater demand site and are trying to cover the sea water, there are several problems as follows.

First, since the hose from the seawater consumer to the sea surface is exposed and exposed to the beach, the hose is easily broken or lost due to typhoons or tsunamis, which makes it impossible to use seawater. Or a maintenance cost for restoring the lost hose to the original state.

Second, in most seawater consumers, the hose is connected to the edge of the sea surface by the hose to shorten the length of the hose to inhale the unfiltered seawater. Therefore, floating substances or spores of seaweed or shellfish, There is a problem that the seawater contaminated when the red tide occurs is directly supplied to the seawater consumer.

Third, since the seawater is sucked into the hose only by the suction force of the pump from the sea surface to the seawater demanding place, there is a possibility that the pump is operated in an overload state to cause a failure, and a large- There is a problem in that the power consumption is excessively consumed and the operation cost is increased.

Fourth, there is a problem that the natural landscape of the beach is seriously damaged because the hose which is exposed to the sea surface for each sea water demand causes the phenomenon that the hose is jammed on the beach and disorganized and scattered.

In order to overcome the above-mentioned problem, the present invention has proposed a patent No. 10-0782359, which overcomes the above-mentioned problem. However, the patent is an invention that is possible when there is no obstacle on the ground layer like sand. If water is found, the intake pipe is out of the scope of the construction plan, and there is a problem that the construction failure occurs or the construction can not be done due to the increase of the press-in pressure of the construction drilling equipment.

SUMMARY OF THE INVENTION The present invention has been made in order to solve the above-mentioned problems, and it is an object of the present invention to provide a water purification system for a water purification system, The present invention is to provide a drilling apparatus and a method of constructing a water intake facility using the same, which can supply water of high quality with high cleanliness by collecting and supplying the seawater by the water pressure by the water head and the natural filtration water collecting method using the sea floor layer.

The present invention can easily install the water intake pipe according to the construction plan even if the type of the submarine ground layer or the obstacle such as the rock is found at the installation of the water intake pipe by the apparatus and method using the excavation equipment. In addition, since the hammer (bit) is detachable, the body of the excavation equipment can be easily separated after the excavation of the stratum, and the body can be reused. In addition, the present invention collects and supplies clean seawater in which floating matters or spores of seaweeds or shellfishes are reliably removed by the water filtration by the water head difference from the sea surface and the natural filtration water collecting method using the seabed ground layer, Can be supplied. In addition, the present invention is a method of installing a water depth correction near the sea level and then digging into a subsea area by collecting water from the water level. In addition to the East Sea which maintains a certain depth, Of sea water.

The hammer body 100 has a tubular casing 110 whose one end is coupled to the excavating body 20 and has an inlet hole 111 at the other end thereof and one end thereof is coupled to the inlet hole 111, A check valve 120 installed inside the casing 110 and a piston 130 linearly moving in the casing 110 by the air discharged from the check valve 120 and a piston 130 installed inside the other end of the casing 110 The first protrusions 141 protruding along the longitudinal direction on the inner circumferential surface in a tubular shape at predetermined intervals and the second protrusions 142 protruding along the inner circumferential surface along one side at an interval, Lt; / RTI > The casing 110 may be a tubular member coupled to the excavating body 20, and the other end may have an inflow hole 111, which is a passage of air injected from the excavating body 20. The check valve 120 is a member which is coupled to the inflow hole 111 at one end to discharge air introduced from the inflow hole into the internal space to cause the piston to perform linear motion. The piston 130 is a member that linearly moves within the casing 110 by air discharged from the check valve 120. When the piston 130 is linearly moved by the air discharged from the check valve 120, the upper end of the piston 130 is engaged with the check valve 120 and the lower end of the piston 130 is engaged with the coupling chuck 140. The movement of the piston 130 is a common method used in an air hammer. The joining chuck 140 is a tubular member provided inside the other end of the casing 110, serving as a member for helping the hammer body and the hammer to be assembled and detached. The coupling chuck 140 may be installed on the inside of the other end of the casing 110 by various methods. For example, a thread may be formed on the outer circumferential surface of the coupling chuck 140 and may be installed through a screw connection. The first protrusions 141 are formed at regular intervals on the inner circumferential surface of the coupling chuck 140 along the longitudinal direction and the second protrusions 142 are protruded at regular intervals along the inner circumferential surface at one end It can take the form of a regular circular ring. A third projection, which will be described later, is inserted into the groove formed between the second projections 142, so that the coupling chuck 140 and the hammer 200 can be engaged.

The hammer 200 is a member in which a plurality of bits are coupled. The third protrusion 210 protrudes along the longitudinal direction on the outer circumferential surface at a predetermined interval. The third protrusion 210 is inserted into the second protrusion 142 And one end thereof is fitted to the coupling chuck 140 in such a manner as to be engaged. The hammer 200 is a member that can be excavated irrespective of the type of stratum to be excavated in a form in which a plurality of bits are combined, and an obstacle can be drilled through the excavation even if it appears in the middle of excavation. The hammer 200 is a member in which one end of the hammer 200 is fitted to the coupling chuck 140 in such a manner that the third projection 210 is inserted into the groove between the second projections 142 and then rotated in one direction.

The hammers 200 may have a discharge hole 220 at one side thereof. The discharge hole 220 discharges air injected by the excavating body 20 through the inlet hole 111 and the check valve 120 and then through the discharge hole 220 of the hammer 200 So that excavation can be facilitated.

In addition, the hammers 200 may have coupling grooves 230 formed on the outer peripheral surface of the other end at regular intervals. When the hammer body 100 and the hammer 200 are separated from each other after the excavation is completed, the coupling protrusion 320 of the intake pipe 300 described later is inserted into the coupling groove 230 to fix the hammer 200, The main body 100 can be easily separated.

The water intake pipe 300 is a tubular member having a plurality of water intake holes 310 through which water is taken on the outer circumferential surface thereof. One end of the hammer body 100 is inserted into the internal space, . The water intake pipe 300 may be formed to have a diameter smaller than the diameter of the hammer and inserted into the hole drilled by the hammer as a hammer. In addition, the water intake pipe 300 is a pipe for receiving seawater through the water intake hole 310 after the excavation is finished and the hammer body 100 is recovered.

In addition, the water intake pipe 300 may further include coupling protrusions 320 formed at predetermined intervals at one end thereof. The engaging projection 320 is inserted into the engaging groove 230 of the hammer 200 when the hammer 200 is disengaged to fix the hammer 200 so as not to move.

When the hammer body 100 and the hammer 200 are coupled to the water intake pipe 300 during the excavation, the third protrusion 210 is rotated in the first and second protrusions 141 and 142 The hammers 200 are hooked so that the hammers 200 are not separated from the hammer body 100 and the hammer body 100 is pulled out so that the hammers 200 are caught on one end of the take- The hammer body 100 may be separated from the hammer 200 in such a manner that the third protrusion 210 comes out through the space between the second protrusions 142 .

In the present invention, a plurality of rods 30 are installed between the other end of the casing 110 and the excavating body 20 according to excavated strata, and the water intake pipes A plurality of connection tubes 50 may be connected to the first and second tubes 300 and 300. When a plurality of rods 30 are installed, the hammer body 100 is collected at the time of collection, and only the intake pipe 300 and the coupling pipe 50 are finally left in the excavation hole. The rod 30 is a general connecting member used in the air hammer, and also serves to transfer the air injected from the excavating body 20 to the hammer main body 100. The connection pipe 50 is a conventional pipe used for excavation, and has a rod 30 therein, which serves to protect the rod 30 during excavation.

6 to 14 are views showing a method of constructing a water intake facility according to the present invention.

A method for constructing a seawater collection facility using an excavation equipment, the method comprising the steps of: (a) modifying a house to be buried at a planned depth in the beach (B) (B) setting the excavating body (20) so as to direct the seabed layer to the floor in the corrugation (40); (c) A check valve 120 installed inside the casing 110 by being coupled to the inflow hole 111 at one end and a check valve 120 installed at the other end of the check valve 120, A piston 130 which moves linearly in the casing 110 by air discharged from the casing 110 and a first projection (not shown) projecting along the longitudinal direction on the inner circumferential surface in a tubular shape provided inside the other end of the casing 110 141 are formed at regular intervals, and one inside A hammer main body 100 constituted by a coupling chuck 140 having second projections 142 projecting at regular intervals along an inner peripheral surface thereof and a plurality of third projections 140 projecting along the longitudinal direction on the outer peripheral surface thereof, A hammer 200 having one end engaged with the coupling chuck 140 in such a manner that the third projection 210 is inserted between the second projections 142 by a member formed with a predetermined interval between the coupling protrusions 210, (300) having one end of the hammer body (100) inserted into the inner space and the hammer (200) being hooked at one end, the pipe being a tubular member having a plurality of intake holes (310) The apparatus 10 is coupled to the excavation body 20 and then excavated from the corrugation 40 toward the seabed layer so that the excavation equipment 10 is rotated in one direction, 1 and 2 projections 141 and 142 so that the hammer 200 is engaged with the hammer body 100, (D) after the step (c), the hammer body (100) is rotated in the other direction while pulling the hammer body (100) so that the hammer (200) is caught by one end of the water intake pipe And separating the hammer body 100 from the hammer 200 in such a manner that the third protrusion 210 is pulled out into a space between the second protrusions 142.

The present invention relates to a method of constructing a water intake facility using excavation equipment capable of excavating irrigation water irrigation irrespective of the type of stratum and an obstacle when installing the irrigation facility.

The present invention can easily install the water intake pipe according to the construction plan even if the type of the submarine ground layer or the obstacle such as the rock is found at the installation of the water intake pipe by the apparatus and method using the excavation equipment. In addition, since the hammer (bit) is detachable, the body of the excavation equipment can be easily separated after the excavation of the stratum, and the body can be reused. In addition, the present invention collects and supplies clean seawater in which floating matters or spores of seaweeds or shellfishes are reliably removed by the water filtration by the water head difference from the sea surface and the natural filtration water collecting method using the seabed ground layer, Can be supplied. In addition, the present invention is a method of installing a water depth correction near the sea level and then digging into a subsea area by collecting water from the water level. In addition to the East Sea which maintains a certain depth, Of sea water.

(a) is a step of installing the house correction 40 so as to be buried at a predetermined depth in the beach B of the corresponding location where the water intake facility is to be installed.

In the collecting unit 40, a reinforcing bar is assembled while assembling the formwork on the beach B of the corresponding position, and an unhardened concrete is placed in the formwork to mold and cure the body unit at a required height and form a mold from the completed body unit After the disassembly, a series of work processes in which the body unit is gradually lowered while carrying out the sato in the body unit is taken out by the waiting earth removal equipment, and the body units are sequentially layered from the lowermost part to the top part, (B) of the location.

At this time, before the bottom body unit is formed, the upper part is opened on the beach B at the position corresponding to the form, and the lower part is inclined downward to form a pointed blade The steel support frame is placed in advance, the iron support frame and the reinforcing bars are placed in the mold support frame while placing the mold on the iron support frame, and then the uncured concrete is laid in place, .

When the lower body of the lower body is brought into contact with the lower surface of the body, the frictional resistance generated by contacting the lower body with the lower body is minimized so that the body unit So that it is possible to securely and quickly embed the collecting filter 40 in the beach B at the corresponding position. In addition, the collecting bases help to stabilize the bottom of the order to be installed later. The bottom of the order is pumped into the sea (B) of the location, and the seawater and the fresh water introduced into it are pumped, and the soil is removed to expose the bottom surface. Placed free from concrete or reinforced concrete. In addition, when the above-mentioned bottom is installed, the non-permeable concrete or reinforced concrete is placed and cured at a height of 80 to 100 cm on the bottom surface of the bottom of the bottom, Ensure that fresh water is blocked. When the collecting is to be buried in the beach B of the corresponding position, the lower end of the collecting fin is placed deeper than the upper part of the seabed, So that it does not interfere with the connection to the lower part. As described above, the lower end of the collecting compartment 40 is installed so as to be positioned deeper than the upper part of the seabed layer, and then the excavated water is collected and taken in the sea. In this way, Can be supplied.

(b) is a step of setting the excavation body 20 so as to direct the seabed layer to the order bottom in the water collection crystal 40.

When setting the excavation main body 20, first, the support frame prepared on the ground is poured into a separate heavy equipment (not shown) and placed on the bottom of the water column in the water collecting 40, 20 are installed on both sides of the support frame so as to set the excavation body 20 in accordance with the height for installing the water intake pipes.

The excavation main body 20 may be a conventional one capable of moving along the guide and having a propelling shaft installed to be rotatable and excavating from the concentrate 40 toward the seabed.

(c) includes a tubular casing 110 having one end coupled to the excavating body 20 and having an inlet hole 111 opened at the other end thereof and one end connected to the inlet hole 111, A piston 130 installed inside the casing 110 by a check valve 120 installed inside the casing 110 and a piston 130 moving linearly in the casing 110 by air discharged from the check valve 120, (140) having first projections (141) projecting along the longitudinal direction on the inner circumferential surface in a tubular shape at regular intervals and second projections (142) protruding along the inner circumferential surface at one And a third protrusion 210 protruding in the longitudinal direction on the outer circumferential surface of the hammer main body 100. The third protrusion 210 protrudes from the second protrusion 142 And the other end is inserted into the coupling chuck 140, And a plurality of water intake holes (310), which are holes through which water is taken in the outer peripheral surface, are inserted into the inner space of the hammer body (100), and the hammer (200) The excavation equipment 10 consisting of a water intake pipe 300 connected to the excavation body 10 is coupled to the excavation body 20 and then excavated from the water collection chamber 40 toward the seabed layer so that the excavation equipment 10 is rotated in one direction The third protrusion 210 is engaged with the first and second protrusions 141 and 142 to exclude the hammer 200 from the hammer body 100.

The hammer body 100 has a tubular casing 110 whose one end is coupled to the excavating body 20 and has an inlet hole 111 at the other end thereof and one end thereof is coupled to the inlet hole 111, A check valve 120 installed inside the casing 110 and a piston 130 linearly moving in the casing 110 by the air discharged from the check valve 120 and a piston 130 installed inside the other end of the casing 110 The first protrusions 141 protruding along the longitudinal direction on the inner circumferential surface in a tubular shape at predetermined intervals and the second protrusions 142 protruding along the inner circumferential surface along one side at an interval, Lt; / RTI > The casing 110 may be a tubular member coupled to the excavating body 20, and the other end may have an inflow hole 111, which is a passage of air injected from the excavating body 20. The check valve 120 is a member which is coupled to the inflow hole 111 at one end to discharge air introduced from the inflow hole into the internal space to cause the piston to perform linear motion. The piston 130 is a member that linearly moves within the casing 110 by air discharged from the check valve 120. When the piston 130 is linearly moved by the air discharged from the check valve 120, the upper end of the piston 130 is engaged with the check valve 120 and the lower end of the piston 130 is engaged with the coupling chuck 140. The movement of the piston 130 is a common method used in an air hammer. The joining chuck 140 is a tubular member provided inside the other end of the casing 110, serving as a member for helping the hammer body and the hammer to be assembled and detached. The coupling chuck 140 may be installed on the inside of the other end of the casing 110 by various methods. For example, a thread may be formed on the outer circumferential surface of the coupling chuck 140 and may be installed through a screw connection. The first protrusions 141 are formed at regular intervals on the inner circumferential surface of the coupling chuck 140 along the longitudinal direction and the second protrusions 142 are protruded at regular intervals along the inner circumferential surface at one end It can take the form of a regular circular ring. A third projection, which will be described later, is inserted into the groove formed between the second projections 142, so that the coupling chuck 140 and the hammer 200 can be engaged.

The hammer 200 is a member in which a plurality of bits are coupled. The third protrusion 210 protrudes along the longitudinal direction on the outer circumferential surface at a predetermined interval. The third protrusion 210 is inserted into the second protrusion 142 And one end thereof is fitted to the coupling chuck 140 in such a manner as to be engaged. The hammer 200 is a member that can be excavated irrespective of the type of stratum to be excavated in a form in which a plurality of bits are combined, and an obstacle can be drilled through the excavation even if it appears in the middle of excavation. The hammer 200 is a member in which one end of the hammer 200 is fitted to the coupling chuck 140 in such a manner that the third projection 210 is inserted into the groove between the second projections 142 and then rotated in one direction.

The hammers 200 may have a discharge hole 220 at one side thereof. The discharge hole 220 discharges air injected by the excavating body 20 through the inlet hole 111 and the check valve 120 and then through the discharge hole 220 of the hammer 200 So that excavation can be facilitated.

The water intake pipe 300 is a tubular member having a plurality of water intake holes 310 through which water is taken on the outer circumferential surface thereof. One end of the hammer body 100 is inserted into the internal space, . The intake pipe 300 may be formed to have a diameter smaller than the diameter of the hammers and inserted into the holes excavated by the hammers 200, such as the hammers 200. In addition, the water intake pipe 300 is a pipe for receiving seawater through the water intake hole 310 after the excavation is finished and the hammer body 100 is recovered.

When the excavation equipment 10 is rotated in one direction so that the third protrusion 210 is caught by the first and second protrusions 141 and 142 so that the hammer 200 is detached from the hammer body 100 And after the excavation is completed, the hammer body 200 is pulled out of the hammer body 100 so as to be caught by one end of the water intake pipe 300 and rotated in the other direction so that the third projection 210 The hammer body 100 may be separated from the hammer 200 by being withdrawn through a space between the first and second protrusions 142 so that the hammer body 100 can be reused.

In the present invention, a plurality of rods 30 are installed between the other end of the casing 110 and the excavating body 20 according to excavated strata, and the water intake pipes A plurality of connection tubes 50 may be connected to the first and second tubes 300 and 300. The rod 30 is a general connecting member used in the air hammer, and also serves to transfer the air injected from the excavating body 20 to the hammer main body 100. The connection pipe 50 is a conventional pipe used for excavation, and has a rod 30 therein, which serves to protect the rod 30 during excavation.

In addition, when the excavation is performed, the water intake pipe 300 is buried so as to be located 3 to 4 m deeper than the upper part of the seabed ground layer, thereby preventing the water intake pipes 300 from being damaged or lost by typhoons or tsunamis, Allows seawater to be filtered sufficiently through the seabed so that it can acquire clean seawater.

In step (d), after the planned excavation is completed, the hammer 200 is rotated in the other direction while pulling the hammer body 100 so that the hammer 200 is caught by one end of the intake pipe 300, The hammer body 100 is separated from the hammer 200 by a method of escaping into a space between the two protrusions 142. [ That is, the step (d) is a step of recovering the hammer body 100 from the installed water intake pipe 300 to allow the water intake pipe 300 to receive the seawater. Here, when a plurality of rods 30 are installed, the hammer body 100 is collected at the time of collection of the hammer body 100, so that only the intake pipe 300 and the connection pipe 50 are finally left in the excavation hole.

In addition, the present invention may further include an engagement groove 230 formed at a predetermined interval on the outer circumferential surface of the other end of the hammer 200, and a coupling protrusion 320 formed at a predetermined interval at one end of the intake pipe 300. when the hammer body 100 and the hammer 200 are separated from each other in step (d), the coupling protrusion 320 of the intake pipe 300 is inserted into the coupling groove 230 to fix the hammer 200, 100) can be easily separated. The engaging projection 320 is inserted into the engaging groove 230 of the hammer 200 when the hammer 200 is disengaged to fix the hammer 200 so as not to move.

After the water intake pipe 300 is installed, the excavating main body 20 and the supporting frame set on the bottom of the water column in the water collecting unit 40 are taken out to the outside by the heavy equipment, And a seawater supply line L in which a pump LP is installed is connected to the seawater desalination unit 40. The top plate is integrally formed on the upper part of the body of the water collecting unit 40, And completes the construction of the seawater collecting facility of the present invention by performing a subsequent operation to completely fill the seawater.

While the present invention has been described with respect to preferred embodiments thereof, it is to be understood that the scope of the present invention, And the scope of the technical idea of the present invention is not limited by the description with reference to the drawings or the drawings. It will also be appreciated by those skilled in the art that the concepts and embodiments of the invention set forth herein may be used as a basis for modifying or designing other structures for carrying out the same purposes of the present invention It will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the present invention as defined by the appended claims and their equivalents. And various changes, substitutions, and alterations can be made without departing from the scope of the invention.

10: Excavation equipment 20: Excavation body
30: Load 40: Edit House
50: Connector
100: Hammer body
110: casing 120: check valve
130: piston 140:
200: hammer 210: third projection
220: Exhaust hole 230: Coupling groove
300: Water intake pipe
310: intake hole 320: coupling projection

Claims (8)

delete delete delete delete A method for constructing a seawater catchment facility using an excavation equipment,
(a) installing a house correction (40) so as to be embedded at a predetermined depth in a beach (B) at the corresponding position;
(b) setting the excavating body (20) so as to direct the seabed to the bottom of the water in the water collection (40);
(c) a tubular casing 110, one end of which is coupled to the excavating body 20 and an inlet hole 111 is opened at the other end thereof, and one end of which is coupled to the inlet hole 111, A check valve 120 installed in the casing 110 and a piston 130 linearly moving in the casing 110 by the air exhausted from the check valve 120 and a pipe 130 disposed inside the other end of the casing 110 A first protrusion 141 protruding along the longitudinal direction on the inner circumferential surface at predetermined intervals and a second protrusion 142 protruding along the inner circumferential surface at one end inside the protrusion 142 at regular intervals, A third protrusion 210 is formed between the second protrusions 142 by a member having a plurality of third protrusions 210 protruding in the longitudinal direction on the outer circumferential surface thereof at regular intervals, And one end is fitted into the coupling chuck 140 The hammers 200 are inserted into the inner space of the hammering body 100 by a tubular member having a plurality of water intake holes 310 through which water is taken in the outer peripheral surface, The excavation apparatus according to any one of claims 1 to 3, wherein the excavation equipment (10) is connected to the excavation body (20) and then excavated from the corrugation (40) Engaging the third protrusion 210 with the first and second protrusions 141 and 142 to prevent the hammer 200 from being detached from the hammer body 100; And
(d) After the step (c), the hammer body 200 is rotated in the other direction while pulling the hammer body 100 so that the hammer 200 is hooked to one end of the water intake pipe 300, The hammer body 100 is separated from the hammer 200 by a method of escaping into a space between the projections 142,
A discharge hole 220 formed at one side of the hammer 200 and a coupling groove 230 formed at a predetermined interval on the outer peripheral surface of the other end of the hammer 200; Further comprising a plurality of rods (30) installed between the other end of the casing (110) and the excavating body (20) according to the protrusions (320) and the layer to be excavated,
In the step (c), the air injected by the excavating body 20 flows through the inflow hole 111 and the check valve 120 and is discharged through the discharge hole 220 of the hammer 200 A plurality of connection pipes 50 are connected to the water intake pipe 300 in accordance with the number of the rods 30 installed in the step (c)
Wherein the coupling protrusion (320) of the water intake pipe (300) is inserted into the coupling groove (230) of the hammer (200) in the step (d).
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