JP2006233747A - Dredger and dredging method - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a dredger and its dredging method which lift up earth and sand to the water surface efficiently. <P>SOLUTION: The dredger is provided with a pair of opening buckets 22, 22, a sand pump 17 with suction inlets located in the buckets 22, 22, and screens 27, 27 moving up and down between the buckets 22, 22 and the suction inlets 20. Since the buckets 22, 22 are used to excavate earth and sand at the bottom of the water, it is possible to excavate even if the earth and sand on the bottom of the water have a high N value. The earth and sand taken into the buckets 22, 22 are agitated by the screens 27, 27 to enhance their fluidity and improve the efficiency of their transportation in a sand pump. Further the dredger can remove obstacles like driftwood, etc. mixed in the dredged earth and sand with the screens 27, 27, eliminate the possibility of catching the obstacles in the suction inlet and enable their smoother lifting to the water surface. <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

  The present invention relates to a dredge apparatus and a dredge method.

  As a method of dredging sediments such as rivers, dams and seas, general dredging using a pump ship, grab ship, bucket ship, dipper ship, etc. There is a method of performing general soot after crushing using.

  Among them, a grab ship that excavates earth and sand with a grab bucket composed of a pair of buckets that can be opened and closed is capable of dredging at deep water depth, and can cope with soil quality from soft mud to hard soil. However, when dredging using a grab ship, the excavated earth and sand are lifted to the surface together with the grab bucket, and it takes time to raise and lower the grab bucket. In the case of, work efficiency was low. Also, when lifting the grab bucket, earth and sand spilled from the grab bucket mixed with the surrounding water, and measures had to be taken to prevent water pollution.

In order to perform dredging without lifting the grab bucket, the grab bucket is provided with an inlet for the earthing pipe having an outlet on the water, and mud is introduced into the inlet of the earthing pipe in the closed grab bucket. There is one provided with a top plate (see, for example, Patent Document 1).
Japanese Patent Publication No. 8-3188

  However, the method of introducing mud into the entrance of the unloading pipe by the upper plate in the closed grab bucket has a problem that the transport efficiency is poor because the fluidity of the mud is low. In addition, obstacles such as driftwood mixed in the mud may be caught at the entrance of the soil pipe, and it is necessary to lift the grab bucket to the water to remove the obstacles.

  The subject of this invention is providing the dredging apparatus and dredging method which can convey the dredged earth and sand efficiently on water.

  In order to solve the above problems, as shown in FIGS. 1 to 7, the invention described in claim 1 is a saddle device 10, and a pair of buckets 22, 22 provided to be openable and closable, and the bucket 22. , 22 and a sand pump 17 having a suction port 20 and screens 27, 27 moving up and down between the buckets 22, 22 and the suction port 20.

  According to the first aspect of the present invention, since the bottom sediment is excavated by the pair of buckets 22 and 22 provided to be openable and closable, even when the N value of the bottom sediment is high and hard, excavation is possible. Moreover, by stirring the earth and sand taken into the buckets 22 and 22 with the screens 27 and 27, the fluidity of the earth and sand can be increased, and the conveyance efficiency by the sand pump 17 can be improved. In addition, obstacles such as driftwood contained in the earth and sand can be removed by the screens 27 and 27, and there is no fear of the obstacle getting caught in the suction port 20, and the earth and sand can be continuously conveyed onto the water.

  The invention according to claim 2 is the dredge apparatus 10 according to claim 1, wherein a plurality of the suction ports 20 are provided, and the sand pump 17 main body can be switched to any suction port 20. It is characterized by being.

  According to the second aspect of the present invention, the earth and sand that has passed through the screens 27 and 27 are sucked by switching the connection between any of the plurality of inlets 20 and the main body of the sand pump 17 to suck the earth and sand. Further stirring is possible.

  The invention according to claim 3 is the scissor device 10 according to claim 1 or 2, wherein the suction port 20 is provided so as to be movable up and down.

  According to the third aspect of the present invention, the earth and sand that has passed through the screens 27 and 27 can be further agitated by sucking the earth and sand while moving the suction port 20 up and down.

  Invention of Claim 4 is a dredging apparatus of Claim 3, Comprising: The density | concentration of the sand hose which discharges the water and the earth and sand which were suck | inhaled by the said sand pump on water, and the earth and sand which passes the said sand hose And a density meter for measuring, wherein the suction port is moved up and down according to the density of earth and sand passing through the sand hose.

  According to the invention described in claim 4, the density of the earth and sand sucked by the sand pump, passed through the sand hose and discharged onto the water is measured by the density meter, and the suction port of the sand pump is moved up and down accordingly. Thus, the density of the earth and sand passing through the sand hose can be maintained in an appropriate range, and the sand pump can be prevented from being overloaded or blocked, and the conveyance efficiency can be improved.

  Invention of Claim 5 is a dredging apparatus as described in any one of Claims 1-4, Comprising: The sand hose which discharges the water and the earth and sand which were inhaled by the said sand pump on water, and the said sand hose And a flow meter for measuring the flow rate of water and earth and sand passing through the sand hose, and the number of revolutions of the sand pump is varied according to the flow rate of water and earth and sand passing through the sand hose.

  According to the fifth aspect of the present invention, it is possible to prevent the sand pump from being overloaded by changing the rotational speed of the sand pump in accordance with the flow rate of water and earth and sand passing through the sand hose.

  A sixth aspect of the present invention is the scissor device according to any one of the first to fifth aspects, further comprising an opening / closing detection mechanism that detects opening / closing of the bucket.

  According to the sixth aspect of the present invention, since the opening / closing detection mechanism detects the opening / closing of the bucket, it is possible to detect that there is an obstacle that prevents the opening / closing of the bucket.

  A seventh aspect of the present invention is the scissor device according to any one of the first to sixth aspects, further comprising a vertical movement detection mechanism that detects the vertical movement of the screen.

  According to the seventh aspect of the present invention, by detecting the vertical movement of the screen by the vertical movement detection mechanism, it is possible to detect that there is an obstacle in the bucket that prevents the vertical movement of the screen.

  The invention according to claim 8 is a dredging method, in which the bottom sediment is excavated with a pair of buckets 22, 22 provided so as to be openable and closable, and then the buckets 22, 22 are closed and the buckets 22, 22 are inside. The screens 27 and 27 provided on the screen are moved up and down to stir the earth and sand in the buckets 22 and 22, and the sand and sand passed through the screens 27 and 27 are repeatedly transported to the water by the sand pump 17. .

  According to the eighth aspect of the invention, since the bottom sediment is excavated by the pair of buckets 22 and 22 provided to be openable and closable, even when the N value of the bottom sediment is high and hard, excavation is possible. Moreover, by stirring the earth and sand taken into the buckets 22 and 22 with the screens 27 and 27, the fluidity of the earth and sand can be increased, and the conveyance efficiency by the sand pump 17 can be improved. In addition, obstacles such as driftwood contained in the earth and sand can be removed by the screens 27 and 27, and there is no fear of the obstacle getting caught in the suction port 20, and the earth and sand can be continuously conveyed onto the water.

  According to the present invention, the earth and sand taken in the bucket is stirred in the bucket by a screen, thereby increasing the fluidity of the earth and sand in the bucket, improving the conveyance efficiency by the sand pump, and efficiently conveying it onto the water. it can.

  Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.

[First Embodiment]
1 and 2 are views showing a structure for attaching the dredging device 10 of the first embodiment of the present invention to the work boat 1, wherein FIG. 1 is a front view and FIG. 2 is a left side view.

  The support frame 2 protrudes from the upper part of the work boat 1 or the like on the water, and is fixed to the work boat 1 or the like at the lower end. The upper end of the support frame 2 protrudes horizontally from the ship upper side toward the water upper side, and an electric chain hoist 3 is attached to the water upper side protruding end. The electric chain hoist 3 suspends and supports the eaves device 10 through the chain 4 so as to be movable up and down.

  An electric hose reel 5 is provided on the work boat 1. The electric hose reel 5 is housed in a state where a sand hose 6 is wound. One end of the sand hose 6 is connected to the eaves device 10 via a guide sheave 7 provided at the upper end of the support frame 2. The other end of the sand hose 6 is connected to a processing plant such as a sand settling tank. The electric hose reel 5 sends the sand hose 6 to the guide sheave 7 as the dredge device 10 is lowered, and winds and stores the sand hose 6 as the dredge device 10 is raised.

  The dredge apparatus 10 according to the present embodiment has a grab bucket shape including a pair of buckets 22, 22 provided to be openable and closable. Hereinafter, the dredge apparatus 10 will be described. 3 and 4 are views showing the dredge apparatus 10 in a state where the buckets 22 and 22 are closed, FIG. 3 is a front view, and FIG. 4 is a side view. 5 is a front view showing the dredge apparatus 10 with the buckets 22 and 22 open. FIG. 6 is a dredge apparatus with the buckets 22 and 22 and the cylinders 26 and 26 that drive the buckets 22 and 22 removed. FIG.

  The hanging frame 11 has a rectangular frame shape in plan view, and the chain 4 is attached to the upper side of the four corners. The upper end of the chain 12 is attached to the lower side of the four corners of the hanging frame 11. The lower end of the chain 12 is attached to the upper end of the frame 13.

  The frame 13 is formed in a rectangular parallelepiped frame shape from an upper frame 14, a lower frame 15, and four pillars 16. Chains 12 are attached to the left and right sides of the upper frame 14. The upper ends of the cylinder 26 and the cylinder 31 are swingably attached to the left and right side portions of the upper frame 14. The four columns 16 are provided at the four corners of the upper frame 14 and the lower frame 15, and connect the upper frame 14 and the lower frame 15.

  A sand pump 17 is provided inside the frame 13. The sand hose 6 is connected to the discharge port 18 of the sand pump 17. At the lower part of the sand pump 17, four suction parts 19 that protrude downward from the lower frame 15 are provided. The suction portion 19 is provided with a suction port 20 that opens downward. The suction part 19 is configured to be able to switch the connection with the main body of the sand pump 17 by a valve (not shown) so that water and earth and sand can be sucked from any one of the four suction ports 20. Each suction part 19 is formed to be extendable in the vertical direction.

  The lower frame 15 of the frame 13 is provided with a pair of parallel rotating shafts 21 and 21 on the left and right sides. Each rotary shaft 21 is provided with a bucket 22 and a screen 27. In this embodiment, the bucket 22 and the screen 27 are attached to the same shaft, but they may be attached to different shafts.

  The pair of left and right buckets 22, 22 are each in a closed state, a bottom plate 23 disposed from each rotary shaft 21 toward the lower center of the saddle device 10, and a front side end and a back side end of the bottom plate 23. Are formed from two side plates 24 and 24 attached in parallel to each other.

  An upper end of the bottom plate 23 is rotatably attached to the rotary shaft 21. Further, an arm 25 projecting sideways is provided at the upper end of the bottom plate 23, and the lower end of the cylinder 26 is rotatably attached to the arm 25. When the cylinders 26 and 26 expand and contract, the buckets 22 and 22 rotate with respect to the rotary shafts 21 and 21 via the arms 25 and 25, and the buckets 22 and 22 are opened as shown in FIG. Or close it. In the closed state, the left and right buckets 22, 22 are in contact with each other at the lower ends of the bottom plate 23 and the side ends of the two side plates 24, 24.

  The pair of left and right screens 27 and 27 are formed in a comb shape having a plurality of arc-shaped teeth 28, and a base portion 29 is rotatably attached to the rotary shaft 21. The teeth 28 of each screen 27 are provided between the adjacent teeth 28 so as to be wider than the width of the teeth 28 and at a sufficient interval to allow the dredged earth and sand to pass. The pair of left and right screens 27 and 27 are arranged so that their teeth 28 mesh with each other.

  The base 29 of the screen 27 is provided with an arm 30 projecting sideways, and the lower end of a cylinder 31 is rotatably attached to the arm 30. When the cylinder 31 expands and contracts, the screen 27 rotates with respect to the rotary shaft 21 via the arm 30, and the screen 27 moves up and down.

  Next, a method for dredging the bottom of the water using the dredger device 10 will be described. First, as shown in FIG. 7A, the chain 4 is unwound from the electric chain hoist 3 with the cylinders 26 and 26 shortened to the shortest, that is, with the buckets 22 and 22 fully opened, and the dredge device 10 is directed to the bottom of the water. To lower. At this time, the cylinders 31 and 31 are in an extended state, and the screens 27 and 27 are in a state closest to the suction port 20.

  When the dredge device 10 reaches the bottom of the water, the cylinders 26 and 26 are extended, and the buckets 22 and 22 are closed as shown in FIG. At this time, the bottom sediment is excavated by the buckets 22 and 22, and the soil is taken in between the buckets 22 and 22 and the screens 27 and 27.

  Next, the sand pump 17 is started, and the suction of water and earth and sand from the suction port 20 is started. At the same time, the cylinders 31, 31 are shortened, and the screens 27, 27 are lowered as shown in FIG. As a result, the earth and sand in the buckets 22 and 22 are loosened, and the loose earth and sand are passed through the upper portions of the screens 27 and 27.

  Next, the cylinders 31 and 31 are extended, and the screens 27 and 27 are raised as shown in FIG. This scrapes the loosened earth and sand. At the same time, the sand pump 17 is driven to suck the loosened earth and sand together with water from the suction port 20. The sucked water and earth and sand are sent to the water through the sand hose 6 by the sand pump 17. By repeating the above operation, wrinkles can be performed continuously.

Thus, according to the dredge apparatus 10 of the present embodiment, since the bottom sediment is excavated by the buckets 22 and 22, excavation can be performed even when the N value of the bottom sediment is high. Moreover, by repeating the vertical movement of the screens 27 and 27 in the buckets 22 and 22 and stirring the earth and sand in the buckets 22 and 22, the fluidity of the earth and sand can be increased and water and earth and sand can be sucked in efficiently. , Transport efficiency can be improved. On the other hand, obstacles such as driftwood and large stones contained in the earth and sand do not pass through the screens 27, 27 and remain below the screens 27, 27, so there is no possibility that the inlet 20 will be clogged with obstacles.
Moreover, since the earth and sand are stirred in the buckets 22 and 22, the surrounding water quality is not polluted.

  In addition, as the screens 27 and 27 move up and down, earth and sand may be sucked while switching the suction part 19 connected to the sand pump 17. By switching the suction part 19 connected to the sand pump 17, the location of the suction port 20 for sucking earth and sand is changed, and the effect of stirring the earth and sand in the buckets 22 and 22 is obtained.

  Further, as the screens 27 and 27 move up and down, earth and sand may be sucked while the suction part 19 is expanded and contracted. By expanding and contracting the suction portion 19, an effect of stirring the earth and sand in the buckets 22 and 22 by moving the suction port 20 for sucking earth and sand up and down can be obtained. Furthermore, although not shown in the drawing, jet nozzles may be provided in the buckets 22 and 22 and the earth and sand in the buckets 22 and 22 may be agitated by jet jet water.

  Also, a gamma ray density meter is provided in the sand hose 6, and the density of earth and sand in the water passing through the sand hose 6 and the earth and sand is measured by the gamma ray density meter, and the screen 27 and the suction unit 19 are controlled according to the density of the earth and sand. Good. Thereby, the conveyance efficiency of earth and sand can be maintained optimally.

  Moreover, in the said embodiment, although the dredger apparatus 10 was attached to the electric chain hoist 3 provided in the support frame 2 protrudingly provided by the upper part of the work boat 1 etc. on the water, for example, an electric chain is attached to the front ends, such as a backhoe and a crawler crane. A hoist may be provided and the dredge apparatus 10 may be attached.

[Second Embodiment]
Next, a second embodiment of the present invention will be described.
The dredge apparatus 110 according to the present embodiment has a grab bucket shape including a pair of buckets 122 and 122 provided to be openable and closable. Hereinafter, the dredge apparatus 110 will be described. FIG. 8 is a front view showing the dredge apparatus 110 with the buckets 122, 122 closed. 9 is a plan view of the saddle device 110 from which the buckets 122 and 122 are omitted, and FIG. 10 is a side view of the saddle device 110 from which the cylinder 141, the guide 142, the connecting portion 143 and the like are omitted.

  11 is a front view showing the dredge apparatus 10 in a state where the sand pump 117 is lowered into the buckets 122, 122, and FIG. 12 is a front view showing the dredge apparatus 10 in a state where the buckets 122, 122 are opened. FIG. 13 is a front view showing the dredge apparatus 10 in a state where the tip of the screen 130 is raised in the buckets 122 and 122.

The suspension frame 111 has a rectangular frame shape in plan view like the suspension frame 11, and the chain 104 is attached to the upper side of the four corners. The chain 104 is fed out from an electric chain hoist (not shown) as in the first embodiment.
The upper end of the chain 112 is attached to the lower side of the four corners of the hanging frame 111. The lower end of the chain 112 is attached to the upper end of the frame 113.

The frame 113 is formed in a rectangular parallelepiped frame shape from an upper frame 114, a lower frame 115, and four pillars 116. In addition, in order to show the structure in the flame | frame 113, the flame | frame 113 is shown with the dashed-two dotted line in FIGS. Chains 112 are attached to the left and right sides of the upper frame 114. Further, the upper ends of the cylinders 123 and 123 are swingably attached to the left and right sides of the upper frame 114.
The four columns 116 are provided at the four corners of the upper frame 114 and the lower frame 115, and connect the upper frame 114 and the lower frame 115.

  The lower ends of the left and right cylinders 141 and 141 are attached to the upper surface of the lower frame 115. The upper ends of the cylinders 141 and 141 are attached to guides 142 and 142, respectively. The two guides 142 and 142 are connected by a connecting portion 143 and a pump support portion 144. The pump support part 144 supports the sand pump 117.

  In addition, guide brackets 145 and 145 are provided on the upper surface of the lower frame 115. As shown in FIG. 9, the guide brackets 145 and 145 are fitted with guides 142 and 142, respectively, and guide the guides 142 and 142 that move as the cylinders 141 and 141 expand and contract up and down.

A suction part 119 is provided below the sand pump 117 so as to protrude downward from the lower frame 115. The suction portion 119 is provided with a suction port 120 that opens downward.
A sand hose 106 is connected to the discharge port 118 of the sand pump 117. The sand hose 106 is the same as the sand hose 6 of the first embodiment, but the sand hose 106 of the present embodiment is provided with a flow meter 146 and a density meter 147. The flow meter 146 measures the flow rate of water and earth and sand passing through the sand hose 106. The density meter 147 measures the density of the sediment in the water and sediment passing through the sand hose 106.

  In addition, jet nozzles 148 and 148 are provided below the sand pump 117. The jet nozzles 148 and 148 are connected to a jet pump (not shown) on water by a hose (not shown), and fresh water is ejected from the jet nozzles 148 and 148. By this jet water, the earth and sand in the buckets 122 and 122 are agitated.

  The sand pump 117 and the jet nozzles 148 and 148 are lowered into the buckets 122 and 122 by contracting the cylinders 141 and 141 (FIG. 11), and are lifted by extending the cylinders 141 and 141 (FIG. 8).

  The lower frame 115 of the frame 113 is provided with a pair of parallel rotation shafts 121 and 121 on the left and right sides. Each rotary shaft 121 is provided with a bucket 122.

  The buckets 122 and 122 are rotatably attached to the rotating shaft 121. Further, the lower ends of the cylinders 123 and 123 are rotatably attached to the buckets 122 and 122, respectively. The cylinder 123 is provided with a stroke detection mechanism (open / close detection mechanism) (not shown) that detects the stroke length.

When the cylinders 123 and 123 contract, the buckets 122 and 122 rotate with respect to the rotating shafts 121 and 121, and the buckets 122 and 122 open as shown in FIG.
On the other hand, when the cylinders 123 and 123 extend, the buckets 122 and 122 rotate with respect to the rotating shafts 121 and 121 and close as shown in FIG.

The buckets 122 and 122 are a pair of left and right, and are formed of a slit portion 124, a screen 130, and two side plates 126 and 126, respectively.
The slit portion 124 is disposed from each rotary shaft 121 toward the lower center of the saddle device 110 with the buckets 122 and 122 closed, and includes a plurality of slits 125. The teeth 134 of the screen 130 are inserted into the slits 125. Since the positions of the slits 125 provided in the two slit portions 124 and 124 are staggered, they are staggered so that the teeth 134 of the two screens 130 and 130 are engaged with each other.

  The two side plates 126 and 126 are attached in parallel to each other at the front side end and the back side end of the slit portion 124. When the buckets 122 and 122 are closed, the lower ends of the slit portion 124 and the side end portions of the two side plates 126 and 126 are in contact with each other.

The screen 130 includes a rotation shaft 131, an arm 132, a cylinder 133, and teeth 134.
The rotation shaft 131 is provided on the outer side of the left and right slit portions 124, 124, respectively. The arm 132 protrudes from the rotating shaft 131 to the outside of the bucket 122. The cylinder 133 is connected at both ends to the tip of the arm 132 and the slit portion. Further, the cylinder 133 is provided with a stroke detection mechanism (up / down motion detection mechanism) (not shown) for detecting the stroke length.

  The teeth 134 are formed integrally with the rotary shaft 131 and are inserted through the slits 125 of the slit portion 124. As the cylinders 133 and 133 expand and contract, the arms 132 and the teeth 134 rotate about the rotation shaft 131, and the tips of the teeth 134 rise or fall inside the slit portion 124 (FIG. 13).

  In addition, the vertical movement of the teeth 134 can be performed simultaneously with the vertical movement of the sand pump 117, or each can be performed independently.

  Next, a method for dredging the bottom of the water using the dredging device 110 will be described. First, in a state where the cylinders 123 and 123 are most shortened, that is, in a state where the buckets 122 and 122 are fully opened as shown in FIG. Lower. At this time, the cylinders 133 and 133 are contracted, and the screens 130 and 130 are fully opened.

  When the dredge device 110 reaches the bottom of the water, the cylinders 123 and 123 are extended, and the buckets 122 and 122 are closed as shown in FIG. At this time, sediment at the bottom of the water is excavated by the slit portion 124 and the tip of the screen 130, and the sediment is taken into the buckets 122 and 122.

  In addition, when obstacles, such as a driftwood and a big stone, are contained between the buckets 122 and 122, it is thought that the buckets 122 and 122 do not close an obstacle and the cylinders 123 and 123 do not extend completely. For this reason, it is possible to detect that the buckets 122 and 122 have pinched an obstacle by detecting that the cylinders 123 and 123 are not completely extended by the stroke detection mechanism (open / close detection mechanism). In this case, the dredging device 110 may be resumed after the dredging device 110 is lifted onto the water and the obstacle is removed.

  Next, the sand pump 117 is activated, and the suction of water and earth and sand from the suction port 120 is started. At the same time, the cylinders 133 and 133 are extended, and the tips of the teeth 134 and 134 of the screens 130 and 130 are raised in the buckets 122 and 122 as shown in FIG. , 130 is lowered. Thereby, the earth and sand in the buckets 122 and 122 are loosened. Further, as necessary, jet jet water is ejected from the jet nozzles 148 and 148 to loosen the earth and sand in the buckets 122 and 122.

  When obstacles such as driftwood or large stones are included between the teeth 134, 134 of the screens 130, 130 and the suction port 120 of the sand pump 117, the tips of the teeth 134, 134 of the screens 130, 130 are raised. Therefore, it is considered that the cylinders 133 and 133 do not extend completely. For this reason, the obstacles in the buckets 122 and 122 can be detected by detecting that the cylinders 133 and 133 are not fully extended by the stroke detection mechanism (vertical movement detection mechanism). In this case, the dredging device 110 may be resumed after the dredging device 110 is lifted onto the water and the obstacle is removed.

  The loose earth and sand are sucked from the suction port 120 of the sand pump 117. At this time, the flowmeter 146 measures the flow rate of water and earth and sand passing through the sand hose 106, and the density meter 147 measures the density of earth and sand passing through the sand hose 106.

  When the flow meter 146 detects that the flow rate has become smaller than the predetermined appropriate value, it is considered that the load of the sand pump 117 is large, so the rotational speed of the sand pump 117 is decreased. Thereby, the overload of the sand pump 117 can be prevented. In addition, when it is thought that the cause that the flow volume became small is that the sand pump 117 or the sand hose 106 was obstruct | occluded, the sand pump 117 is stopped, and dredging is restarted after eliminating the obstruction | occlusion.

  Further, when the density meter 147 detects that the density of the earth and sand is lower than a predetermined appropriate value, the cylinders 141 and 141 are contracted, and the suction port 120 of the sand pump 117 is lowered and sucked as shown in FIG. Increase the density of earth and sand. On the other hand, when the density of earth and sand is high, the cylinders 141 and 141 are extended to raise the suction port 120 of the sand pump 117, and the density of the earth and sand to be sucked is lowered. By controlling in this way, the density of the earth and sand passing through the sand hose 106 can be maintained in an appropriate range, and an overload or blockage of the sand pump 117 can be prevented, and the conveyance efficiency can be improved.

The above control is automatically performed by a control unit (not shown), but may be performed manually.
By repeating the above operation, wrinkles can be performed continuously.

  Thus, according to the dredge apparatus 110 of this embodiment, the fluidity of the earth and sand is increased by stirring the earth and sand in the buckets 122 and 122 by the jet water jets ejected from the jet nozzles 148 and 148, and the water and Suction of earth and sand can be performed efficiently, and the conveyance efficiency can be improved.

Moreover, the density of the earth and sand passing through the sand hose 106 is measured by the density meter 147, and the screen 130 and the suction port 120 are moved up and down according to the density of the earth and sand, so that the earth and sand transport efficiency can be optimally maintained. .
Further, by measuring the flow rate of water and earth and sand passing through the sand hose 106 with the flow meter 146, problems such as blockage of the sand pump 117 or the sand hose 106 can be found and dealt with due to the change in flow rate.

It is a front view which shows the attachment structure to the work boat 1 of the dredging apparatus 10 with which this invention was applied. It is a left view which shows the attachment structure to the work boat 1 of the dredging apparatus 10 to which this invention was applied. It is a front view which shows the dredge apparatus 10 of the state in which the buckets 22 and 22 were closed. It is a side view which shows the dredge apparatus 10 of the state in which the buckets 22 and 22 were closed. It is a front view which shows the saddle device 10 in the state where the buckets 22 and 22 opened. It is a front view which shows the dredge apparatus 10 of the state which removed the buckets 22 and 22 and the cylinders 26 and 26. FIG. (A)-(c) is a front view explaining the dredging method of the water bottom by the dredger apparatus 10. FIG. It is a front view which shows the dredge apparatus 110 of the state in which the buckets 122 and 122 were closed. It is a top view of the dredge apparatus 110 which abbreviate | omitted the bucket 122,122. It is a side view of the dredge apparatus 110 which abbreviate | omitted the cylinder 141, the guide 142, the connection part 143, etc. It is a front view which shows dredge apparatus 10 of the state which lowered | hung the sand pump 117 in the bucket 122,122. It is a front view which shows the dredge apparatus 10 of the state which opened the bucket 122,122. It is a front view which shows the scissors apparatus 10 of the state which raised the front-end | tip of the screen 130 in the bucket 122,122.

Explanation of symbols

6, 106 Sand hose 10, 110 Dredging device 17, 117 Sand pump 20, 120 Suction port 22, 122 Bucket 27, 130 Screen 146 Flow meter 147 Densimeter

Claims (8)

A pair of buckets provided to be openable and closable;
A sand pump having an inlet in the bucket;
A scissor device comprising a screen that moves up and down between the bucket and the suction port.   2. The dredge device according to claim 1, wherein a plurality of the suction ports are provided, and the sand pump main body can be switched to an arbitrary suction port.   The scissor device according to claim 1 or 2, wherein the suction port is provided so as to be movable up and down. A sand hose for discharging water and earth and sand sucked by the sand pump onto the water;
A density meter for measuring the density of the earth and sand passing through the sand hose,
The dredge apparatus according to claim 3, wherein the suction port is moved up and down according to the density of earth and sand passing through the sand hose. A sand hose for discharging water and earth and sand sucked by the sand pump onto the water;
A flow meter for measuring the flow rate of water and earth and sand passing through the sand hose,
The dredging device according to any one of claims 1 to 4, wherein the number of rotations of the sand pump is changed in accordance with a flow rate of water and earth and sand passing through the sand hose.   The dredge apparatus according to any one of claims 1 to 5, further comprising an open / close detection mechanism that detects opening / closing of the bucket.   The scissor device according to any one of claims 1 to 6, further comprising a vertical motion detection mechanism that detects vertical motion of the screen. Excavate the bottom sediment with a pair of buckets that can be opened and closed,
Next, while the bucket is closed, the screen provided inside the bucket is moved up and down to stir the earth and sand in the bucket,
A dredging method characterized in that the sand and sand passed through the screen is repeatedly transported onto the water by a sand pump.

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