KR101828050B1 - Convey apparatus for excavation - Google Patents

Abstract

The present invention discloses a transfer device for excavation. The transfer device for excavation of the present invention comprises: a supply unit sucking and supplying water and particles of various sizes at a site in which excavation is performed; a plurality of belts separating the particles transferred from the supply unit and the particles and arranged to be stacked on each other to separate the particles by size; a driving unit disposed on each of the belts to rotate the belts; and a discharging unit discharging the water to the outside by centrifugally separating the water dropped from the belt disposed at the lowermost among the belts, wherein at least a portion of each of the belts is formed into a mesh shape, and the size of the holes of the mesh of each of the belts becomes smaller from the upper side to the lower side of the belts.

Description

[0001] Conveying apparatus for excavation [

The present invention relates to an apparatus, and more particularly, to a feed apparatus for excavation.

Generally, in order to construct a geothermal heating and cooling system, an underground heat exchanger can be buried in the ground by excavating the ground. At this time, a hammer bit can be used to excavate the ground, and water can be supplied to prevent dust or heat from being generated on the excavated ground.

When the ground is excavated as described above, soil, stone, etc. disposed on the ground can be diluted with water. Such water can be discharged to the outside through a pump or the like, and the excavation can be continuously performed through the hammer bit.

As described above, the water discharged to the outside may contain soil, stone, etc. It is impossible to discharge the soil and the stone to the outside because of environmental pollution or the like. Therefore, various devices may be used to separate water, soil, and stone separately to prevent this. As a result, the construction cost can be increased and the construction time can be increased.

Embodiments of the present invention provide an excavation conveying apparatus capable of quickly and efficiently separating water and other materials generated during excavation work.

According to an aspect of the present invention, there is provided a method of separating water from water, comprising: a supply unit for sucking and supplying water and various sizes of particles at a site where the water is excavated; A plurality of belts, a driving unit disposed on each of the belts, for rotating the belts, and a control unit for centrifugally separating the water and the water dropped from the belt disposed on the lowermost side of the plurality of belts, And at least a portion of each of the belts is formed in a mesh shape, and the size of the holes of the mesh of each of the belts is reduced from the upper side to the lower side of the plurality of belts.

 In addition, the size of each of the belts may be reduced from the upper side to the lower side of the plurality of belts.

The apparatus may further include a load measuring unit connected to the driving unit and measuring a weight of each of the belts.

The apparatus may further include a rotation driving unit connected to the driving unit to rotate the driving unit and the belt when the weight measured by the load measuring unit exceeds a predetermined weight.

According to another aspect of the present invention, there is provided a water treatment system comprising: a supply part for sucking and supplying water and various sizes of particles at a site to be excavated; and a water supply part for separating the particles transferred from the supply part, A plurality of belts, a driving unit disposed on each of the belts, for rotating the belts, and a control unit for centrifugally separating the water and the water dropped from the belt disposed on the lowermost side of the plurality of belts, A driving unit connected to the driving unit and configured to measure a weight of each of the belts; a driving unit connected to the driving unit, the driving unit and the belt, when the weight measured by the load measuring unit exceeds a predetermined weight, Wherein a size of each of the plurality of belts is reduced from an upper side to a lower side of the plurality of belts Wherein at least a portion of each of the belts is formed in a mesh shape and the size of a hole of the mesh of each of the belts is reduced from the upper side to the lower side of the plurality of belts, The same excavation transfer apparatus can be provided.

According to another aspect of the present invention, there is provided a water treatment apparatus comprising: a supply unit for sucking and supplying water and particles of various sizes at a site to be excavated; a first belt for passing water transferred from the supply unit, A second belt disposed on the lower surface of the first belt for passing water having passed through the first belt and for separating particles of a predetermined size or larger among particles passing through the first belt, A second driving unit that is disposed on the second belt and rotates the second belt; a second driving unit that is disposed on the lower side of the second belt, A discharge part for discharging water to the outside by centrifugally separating water and particles dropped from the funnel part; and a discharge part connected to the first driving part and measuring the weight of the first belt A second load measuring unit connected to the second driving unit and measuring the weight of the second belt, a second load measuring unit connected to the first driving unit and measuring the weight measured by the first load measuring unit, A first rotation driving part for rotating the first driving part and the first belt in a direction perpendicular to a conveying direction of the first belt when the predetermined weight is exceeded, and a second rotation driving part connected to the second driving part, A second rotation driving unit for rotating the second driving unit and the second belt in a direction perpendicular to the conveyance direction of the second belt when the measured weight exceeds a predetermined weight, Wherein a size of the first belt is larger than a size of the second belt and a size of a hole of the mesh of the first belt is larger than a size of the second belt It may be larger than the hole size of the mesh.

Embodiments of the present invention can effectively separate water and soil or stone. Further, embodiments of the present invention are capable of separating the material that occurs during excavation in a short time.

1 is a conceptual diagram showing a conveying device for excavation according to an embodiment of the present invention.
FIG. 2 is a plan view showing a plurality of belts shown in FIG. 1. FIG.
3 is a conceptual view showing the discharge portion shown in Fig.

BRIEF DESCRIPTION OF THE DRAWINGS The present invention will become more apparent from the following detailed description taken in conjunction with the accompanying drawings, in which: FIG. The present invention may, however, be embodied in many different forms and should not be construed as being limited to the embodiments set forth herein. Rather, these embodiments are provided so that this disclosure will be thorough and complete, and will fully convey the scope of the invention to those skilled in the art. Is provided to fully convey the scope of the invention to those skilled in the art, and the invention is only defined by the scope of the claims. It is to be understood that the terminology used herein is for the purpose of describing particular embodiments only and is not intended to be limiting of the invention. In the present specification, the singular form includes plural forms unless otherwise specified in the specification. It is noted that the terms "comprises" and / or "comprising" used in the specification are intended to be inclusive in a manner similar to the components, steps, operations, and / Or additions. The terms first, second, etc. may be used to describe various elements, but the elements should not be limited by terms. Terms are used only for the purpose of distinguishing one component from another.

1 is a conceptual diagram showing a conveying device for excavation according to an embodiment of the present invention. FIG. 2 is a plan view showing a plurality of belts shown in FIG. 1. FIG. 3 is a conceptual view showing the discharge portion shown in Fig.

1 to 3, a conveying apparatus for excavation 100 includes a supply unit 110, a plurality of belts 120, a driving unit 130, a discharge unit 140, a load measuring unit 150, 160, a receiving portion 170, a filter portion 180, and a funnel portion 190. [

The supplying unit 110 is connected to the ground where the excavation is performed, and can suck water and foreign substances in the excavated holes and discharge it to the outside. At this time, the foreign matter may include soil, stone, and the like. This supply 110 may include a pump and may include piping connected to the pump. At this time, the supply unit 110 may supply water, soil, stone, or the like to a central portion of the plurality of belts 120.

The plurality of belts 120 can be arranged in a multi-step manner. For example, the plurality of belts 120 may include a first belt 121 and a second belt 122 disposed below the first belt 121. At this time, the number of the plurality of belts 120 is not limited to the above number, but may be variously arranged such as three or four. In this case, the plurality of belts 120 may be arranged in a laminated form. Hereinafter, for convenience of explanation, the plurality of belts 120 will be described in detail with reference to the case where the belt 120 includes the first belt 121 and the second belt 122.

The first belt 121 can separate water, soil, stone, etc., supplied from the supply unit 110, from the water and the soil, the stone having a particle size of a predetermined value or more. Specifically, at least a portion of the first belt 121 may be formed in the form of a mesh. At this time, the mesh of the first belt 121 can pass soil or a stone having a predetermined size or less.

The second belt 122 is disposed on the lower side of the first belt 121 and is made of water, soil, and stone having passed through the first belt 121, It can be separated from soil or stone. At this time, at least a portion of the second belt 122, similar to the first belt 121, may be formed as a mesh. In this case, the size of the hole of the mesh of the first belt 121 may be larger than the size of the hole of the mesh of the second belt 122. Accordingly, when the number of the plurality of belts 120 is large, it is possible to separate the stone and the soil into particles of various sizes.

The areas of the first belt 121 and the second belt 122 may be different from each other. For example, the first length L1 of the first belt 121 and the second length L2 of the second belt 122 may be equal to each other. The first width W1 of the first belt 121 and the second width W2 of the second belt 122 may be different from each other. At this time, the first width W1 may be larger than the second width W2. In other embodiments, the first length L1 and the second length L2 may be different from each other, and the first width W1 and the second width W2 may be different from each other. In this case, the first length L1 may be greater than the second length L2. As another embodiment, it is also possible that the first length L1 and the second length L2 are formed to be different from each other, and the first width W1 and the second width W2 are formed to be different from each other. At this time, one length L1 is formed to be larger than the second length L2, and the first width W1 may be formed to be larger than the second width W2. Hereinafter, for convenience of explanation, the first width W1 is formed to be larger than the second width W2, and the first length L1 and the second length L2 are equal to each other will be described in detail .

In this case, the first mesh width A1 of the mesh of the first belt 121 may be equal to the second mesh width A2 of the mesh of the second belt 122. In this case, the area of the mesh of the first belt 121 and the area of the mesh of the second belt 122 may be the same. Accordingly, the mesh of the second belt 122 and the mesh of the first belt 121 are completely overlapped with each other when viewed from above, thereby effectively separating particles of various sizes while passing through the first belt 121 and the second belt 122 can do.

The driving unit 130 may be connected to the belt 120 to rotate the belt 120. The driving unit 130 may include a first driving unit 131 connected to the first belt 121 and a second driving unit 132 connected to the second belt 122. Since the first and second driving units 131 and 132 are similar to each other, the first driving unit 131 will be described below in detail.

The first driving part 131 may include a first rotating part 131a contacting the first belt 121 and a first driving motor 131b connected to the first rotating part 131a. The first driving unit 131 may further include a first speed reducer (not shown) for connecting the first rotating unit 131a and the first driving motor 131b. Hereinafter, a case where the first driving unit 131 does not include the first speed reducer will be described in detail.

The first rotation part 131a may be formed in a roller shape. In one embodiment, the first rotation part 131a may have the same size as the first width W1. In another embodiment, the first rotation part 131a may be formed to have a size different from the first width W1 and may contact only a part of the first belt 121. [ In this case, the first rotation portion 131a may be disposed on the side surface of the first belt 121, and may not contact the portion of the first belt 121 formed with the mesh.

The discharge unit 140 may be disposed below the plurality of belts 120. At this time, the discharge part 140 can centrifuge the foreign matter having a size of water and particles smaller than a predetermined value. Specifically, the discharge portion 140 may include an exhaust housing 141, a rotation housing 142, and a rotation motor 143. At this time, the discharge housing 141 may have a space formed therein and may include a first discharge port 141a for guiding water or the like to the outside. In addition, the discharge housing 141 may include a second discharge port 141b for discharging the foreign material inside the rotary housing 142 to the outside. The rotary housing 142 may be rotatably disposed within the discharge housing 141. At this time, the inner surface of the discharge housing 141 may be spaced apart from the outer surface of the rotary housing 142. In addition, a hole is formed on the outer surface of the rotary housing 142 so that water can be discharged to the outside according to the rotation, and the hole can prevent the particles from passing through the foreign matter having a predetermined size or more. The rotation housing 142 may have an opening 142a connected to the outside and a separate cap 144 may be disposed in the opening 142a. At this time, when the cap 144 is opened, the opening 142a may be opened, and the opening 142a and the second outlet 141b may be connected. In this case, the bottom surface of the rotation housing 142 may be inclined around the opening 142a. In particular, the bottom surface of the rotation housing 142 may be formed such that the opening 142a is disposed at the lowest position.

The load measuring unit 150 may include a first load measuring unit 151 connected to the first driving unit 131 and a second load measuring unit 152 connected to the second driving unit 132. The first load measuring unit 151 and the second load measuring unit 152 may include a load cell capable of sensing a load (or weight) applied to the first driving unit 131 and the second driving unit 132, Sensors, and the like.

The rotation driving unit 160 may be connected to the driving unit 130. In particular, the rotation driving unit 160 may be connected to the driving unit 130 through the load measuring unit 150. The rotation driving unit 160 may include a first rotation driving unit 161 connected to the first load measuring unit 151 and a second rotation driving unit 162 connected to the second load measuring unit 152 . The positions of the first rotation driving part 161 and the second rotation driving part 162 may be varied to change the positions of the first driving part 131 and the second driving part 132. [ For example, the first rotation driving portion 161 and the second rotation driving portion 162 may include a cylinder. The first rotation driving part 130 and the second rotation driving part 162 move the rails and the rails respectively and move the moving blocks and the moving blocks connected to the first driving part 131 and the second driving part 132, And a motor (or cylinder, etc.) connected to move the motion block on the rails. Hereinafter, for convenience of explanation, the first rotation driving unit 161 and the second rotation driving unit 162 each include a cylinder, respectively. The first rotation driving part 161 and the second rotation driving part 162 may be disposed at an angle to the first driving part 131 and the second driving part 132, respectively.

The storage portion 170 may be disposed to correspond to each of the plurality of belts 120. At this time, the storage part 170 may be formed in a box shape, and foreign matter falling from each of the belts 120 may be received and stored. At this time, the storage portion 170 may include a first storage portion 171 disposed to correspond to the first belt 121, and a second storage portion 172 disposed to correspond to the second belt 122 . Although not shown in FIG. 1, the receiving portion 170 may include a third accommodating portion (not shown) disposed to correspond to a side surface of the first belt 121 and a second accommodating portion (Not shown), which is provided on the rear side of the first housing portion.

The filter unit 180 may be disposed at the first outlet 141a. The filter unit 180 may include a settling box 181 connected to the first outlet 141a and a filter 182 disposed inside the settling box 181. In this case, the filter 182 may be formed to remove small particles, and may remove small particles of soil or the like from the water.

The funnel portion 190 is disposed between the plurality of belts 120 and the discharge portion 140 so that water, soil or the like that has passed through the plurality of belts 120 is prevented from being carried to the outside, can do.

In the operation of the above-described excavation transfer apparatus 100, when excavating the ground, pressure can be applied to the ground surface through the hammer bit while supplying water to the ground. In this case, soil, stone, etc. may be mixed with water on the ground. The user can draw water by connecting the supply part 110 to a part where soil, stone, etc. are mixed together with water as described above. The soil, stone, etc., sucked together with the water may be supplied to the first belt 121 through the supply part 110.

Water mixed with soil, stone, etc. may be supplied to the mesh of the first belt 121. At this time, only soil or stone having a particle size of a predetermined value or more remains in the mesh of the first belt 121, and water and the remaining soil or stone may fall down. The first belt 121 is continuously rotated by operating the first driving unit 131 so that foreign matter having a particle size larger than a predetermined value can be continuously lifted from the water supplied from the supplying unit 110.

The water, soil, stone, and the like dropped from the first belt 121 can be removed from the second belt 122 by the soil or the stone having a predetermined size or larger. In addition, soil or stone having a particle size smaller than a predetermined size may be dropped to the discharge portion 140. In this case, the second driving unit 132 is also continuously driven to rotate the second belt 122, thereby preventing the soil or the stone from being excessively accumulated on the mesh of the second belt 122.

In this case, at least one of the soil and the stone may be removed by a predetermined size when the first belt 121 and the second belt 122 pass through sequentially.

The water, soil, stone, and the like dropped into the discharge part 140 may be stored in the rotary housing 142. At this time, the rotation motor 143 can continuously rotate to discharge water to the discharge housing 141 side within the rotation housing 142. The water can be discharged to the outside through the first discharge port 141a along the bottom surface of the discharge housing 141. [

Meanwhile, during the operation as described above, the first load measuring unit 151 and the second load measuring unit 152 can measure loads applied to the first driving unit 131 and the second driving unit 132, respectively. Since the methods of controlling based on the loads measured by the first load measuring unit 151 and the second load measuring unit 152 are similar to each other, the first load measuring unit 151 is referred to as a reference Will be described in detail.

When the soil or stone passing through the first belt 121 is accumulated inside the first belt 121 in the form of an endless track, an excessive load is applied to the first driving part 131 and the first driving part 131 may be broken have. The total load applied on the first belt 121 can be measured by measuring the load applied to the first driving unit 131 by the first load measuring unit 151. [ The load measured as described above can be compared with a predetermined reference load. When the load measured by the first load measuring unit 151 exceeds a preset reference load, the first rotation driving unit 161 operates to rotate the first belt 121 and the first driving unit 131 have. Specifically, the first rotation driving part 161 can rotate the first belt 121 in one direction by increasing the length. In particular, the first rotation driving part 161 may rotate the first belt 121 in a direction perpendicular to the conveying direction of the first belt 121. In another embodiment, the first rotation driving part 161 may shake the first belt 121 by varying the length. In such a case, soil and stone can be dropped or removed from the first belt 121, and a part thereof can be stored in the third storage portion.

Similarly to the first driving unit 131, the second driving unit 132 may shake or rotate the second belt 122 to remove the soil or the stones in the second belt 122. In this case, the operation of the excavation conveying apparatus 100 may be stopped. Specifically, the operations of the first driving unit 131, the second driving unit 132, and the rotating motor 143 may be stopped.

In the case of the discharging part 140, it can be automatically stopped by providing a separate load sensor 145. At this time, the load sensor can measure the load inside the rotary housing 142. When the load measured by the load sensor exceeds a preset load, the operation of the rotation motor 143 can be stopped, and an external user can be informed by an alarm or by displaying an image.

In this case, the rotation motor 143 is operated to rotate the rotation housing 142 so that the opening 142a and the second outlet 141b correspond to each other. The user can open at least one of the soil and the stone through the opening 142a by opening the cap 144 through the second outlet 141b. At this time, the user can separately supply water to the rotating housing 142 as needed.

Therefore, it is possible to effectively remove foreign matter such as soil, stone, etc., generated during excavation through the simple structure, and to separate the water. In addition, the excavation conveying apparatus 100 can remove foreign matter in water during excavation, thereby preventing contamination that may occur during excavation.

Although the present invention has been described in connection with the above-mentioned preferred embodiments, it is possible to make various modifications and variations without departing from the spirit and scope of the invention. Accordingly, it is intended that the appended claims cover all such modifications and variations as fall within the true spirit of the invention.

100: Feeder 144: Cap
110: supply unit 145: load sensor
120: Belt 150: Load measuring part
121: first belt 151: first load measuring part
122: second belt 152: second load measuring part
130: driving part 160: rotation driving part
131: first driving part 161: first rotation driving part
132: second driving part 162: second rotation driving part
140: discharge part 170: storage part
141: exhaust housing 180: filter section
142: rotating housing 190:
143: Rotary motor

Claims (6)

A supply part for sucking and supplying water and particles of various sizes at a site to be excavated;
A plurality of belts for separating the particles transferred from the supply unit and the particles and arranged to be stacked on each other to separate the particles by size;
A driving unit disposed on each of the belts to rotate the belts;
A discharge unit for discharging the water to the outside by centrifugally separating the water dropped from the belt disposed at the lowermost one of the plurality of belts;
A load measuring unit connected to the driving unit and measuring a weight of each of the belts; And
And a rotation driving unit connected to the driving unit and rotating the driving unit and the belt when the weight measured by the load measuring unit exceeds a predetermined weight,
Wherein at least a portion of each of the belts is formed in a mesh shape, and a size of a hole of the mesh of each of the belts is reduced from the upper side to the lower side of the plurality of belts. The method according to claim 1,
And the size of each of the belts is reduced from the upper side to the lower side of the plurality of belts. delete delete A supply part for sucking and supplying water and particles of various sizes at a site to be excavated;
A plurality of belts for separating the particles transferred from the supply unit and the particles and arranged to be stacked on each other to separate the particles by size;
A driving unit disposed on each of the belts to rotate the belts;
A discharge unit for discharging the water to the outside by centrifugally separating the water dropped from the belt disposed at the lowermost one of the plurality of belts;
A load measuring unit connected to the driving unit and measuring a weight of each of the belts; And
And a rotation driving unit connected to the driving unit and rotating the driving unit and the belt when the weight measured by the load measuring unit exceeds a predetermined weight,
The size of each of the belts becomes smaller from the upper side to the lower side of the plurality of belts,
Wherein at least a part of each of the belts is formed in a mesh shape, and a size of a hole of the mesh of each of the belts becomes smaller from the upper side to the lower side of the plurality of belts,
And a region where the mesh of each belt is formed is the same for the plurality of belts. A supply part for sucking and supplying water and particles of various sizes at a site to be excavated;
A first belt for passing water transferred from the supply unit and separating particles of a predetermined size or more among the particles;
A second belt disposed on a lower surface of the first belt for passing water passing through the first belt and separating particles of a predetermined size or larger among particles passing through the first belt;
A first driving unit disposed on the first belt and rotating the first belt;
A second driving unit disposed on the second belt and rotating the second belt;
A funnel portion disposed below the second belt and collecting water and particles falling from the second belt;
A discharge unit for centrifugally separating the water and the particles dropped from the funnel to discharge water to the outside;
A first load measuring unit connected to the first driving unit and measuring a weight of the first belt;
A second load measuring unit connected to the second driving unit and measuring the weight of the second belt;
And a first driving unit connected to the first driving unit and configured to rotate the first driving unit and the first belt in a direction perpendicular to the conveying direction of the first belt when the weight measured by the first load measuring unit exceeds a predetermined weight, A rotation driving unit;
And a second driving unit connected to the second driving unit and configured to rotate the second driving unit and the second belt in a direction perpendicular to the conveying direction of the second belt when the weight measured by the second load measuring unit exceeds a predetermined weight, A rotation driving unit; And
And a filter unit connected to the discharge unit and separating the particles larger than a predetermined size from the water discharged through the discharge unit,
Wherein the size of the first belt is greater than the size of the second belt,
Wherein a size of the hole of the mesh of the first belt is larger than a hole of the mesh of the second belt.

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