JP4891548B2 - Dredge equipment - Google Patents

Description

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

  As shown in FIG. 12, the conventional dredge pump 60 includes a high-pressure water jet pipe 63 having an ejector nozzle 62 at a tip portion 61 bent in a U-shape, and the ejector nozzle 62 in the vicinity of a suction port 64. And a sand discharge pipe 65 for sucking and delivering surrounding soil water (slurry) by jetting high-pressure water into the suction port 64, and a stirring jet nozzle 66 below the suction port 64. The jet pipe 67 provided in the above was installed horizontally.

In addition, as shown in FIG. 13, the dredger device 68 has a plurality of dredging pumps 71 suspended in a straight line from a pier 69 installed at a place where sand is accumulated to a sand deposit 70 on the seabed. A water supply pipe 72 that pumps high-pressure water and a sand discharge pipe 73 that discharges the collected earth and sand water are connected to 71. Another soot pump and soot device is disclosed in, for example, Japanese Patent Application Laid-Open No. 2002-266369.
JP 2002-266369 A

  However, the dredging pump 60 as described above has the jet pipe 67 installed horizontally, and the jet nozzle 66 for stirring is installed on the lower side thereof, so that the flow of drift sand into the sand pocket is reduced and stirring is performed. There was a problem that efficient suction could not be done without success. As a solution to this problem, without deepening the installation position of the dredge pump (when the installation position of the dredge pump is deepened, the water pressure sent to the discharge pipe is increased, which increases the cost of electricity and the efficiency is reduced), and the sand pocket The size of the sand pocket is increased by increasing the size of the sand pocket and increasing the amount of sand that can be collected, and liquefying a wide range of sand (injecting sand by jetting high-pressure water from the jet nozzle of the jet pipe). There are times when it expands.

  On the other hand, since the dredge pump 71 is installed linearly in the dredge device 68, as shown in (3) and (4) of FIG. A wide portion 76 having a deep depth in cross section and a portion 77 having a narrow width in cross section and a shallow depth in cross section are formed. When the sand drift 75 passes over the portion 76 that is wide in plane and deep in cross section, the cross section of the ocean current increases, so the speed decreases temporarily, and the sand drift 75 settles in the sand pocket 74. To do. However, when the sand drift 75 passes over the portion 77 that is narrow in plane and shallow in cross section, the speed of the ocean current does not decrease, so the sand drift 75 passes through the sand pocket 74 without sinking. There was a problem that. Solutions to this problem include increasing the depth of the sand pocket and increasing the width.

  The present invention has been made in view of the problems as described above, and the purpose of the present invention is to improve the size of sand pockets by liquefying a wide range of sand without deepening the installation position. To provide a dredge device capable of increasing the depth and width of a pump and a sand pocket.

The gist of the dredging device consists of a jetty installed at the place where the sand is deposited, a plurality of dredging pumps suspended from the jetty to the bottom sediment, and pumping high-pressure water to the dredging pump with a centrifugal pump. And a drain pipe that delivers sediment water collected by a dredging pump,
  The dredge pumps are arranged in a staggered manner along the pier at the dredging location.
  A pier installed at a place where sand is accumulated; a plurality of dredging pumps suspended from the pier to a sedimentation portion on the seabed; and a water supply pipe for pumping high-pressure water to the dredging pump with a centrifugal pump; It consists of a sand discharge pipe that delivers sediment water collected by the dredging pump, where the dredging sand passage has a small interval between dredging pumps, and the dredging sand passage has a small dredging pump installation. This is to increase the interval.
  Furthermore, a pier installed at the place where the sand is accumulated, a plurality of dredging pumps suspended from the pier to the sand deposit on the seabed, and a water supply pipe for pumping high-pressure water to the dredging pump with a centrifugal pump It consists of a sand discharge pipe that delivers the sediment water collected by the dredging pump, where the dredged sand passage has a deeper installation position for the dredged sand passage, and the dredged sand passage has a smaller dredging sand installation position. The position is shallow.

Furthermore, the dredging pump is arranged in a staggered manner along the pier where dredging is performed, and a collapsible jet nozzle is installed to collapse the shoulder of the sand pocket while the dredging pump is installed. It includes.

The dredge pump includes a high-pressure water injection pipe provided with an ejector nozzle at the tip bent upward, and the ejector nozzle is positioned in the vicinity of the suction port. And a ring-shaped jet pipe located below the suction port, and jet nozzles installed toward the suction port are provided at appropriate intervals. The dredge pump has a high-pressure water injection pipe provided with an ejector nozzle at the tip bent upward, and the ejector nozzle is positioned in the vicinity of the suction port. a sediment tube delivering suck sediment water, a water supply pipe of L-shaped placing the tip below the suction port, just below the ejector nozzle from the tip of the water supply pipe Is composed of a Vita jet pipe, the 該噴 flow pipe that jet nozzles are provided multidirectional, it is intended to include.

By providing the jet nozzle in the annular jet pipe (three-dimensional position), the bottom area of the sand pocket formed by the eaves is increased, so that the capacity is increased. When the sand pocket becomes large in this way, even if the sand is drowned with the same energy, a lot of sand can be dredged over a wide area, so that the dredging can be carried out efficiently. Further, since the jet nozzle is installed toward the suction port, the earth and sand water around the jet pipe can be smoothly sucked into the suction port. Further, by providing the jet nozzle extending in the downward direction with the jet pipes directed in multiple directions, the liquefaction range of the sand pocket can be expanded, so that the sand pocket can be enlarged.

  In addition, because the dredge pumps in the dredging device are arranged in a staggered manner, there are no narrow or shallow portions of the sand pocket in plan view, so drift sand that passes over the sand pocket can be efficiently taken into the sand pocket. Can be jealous. In addition, by installing a collapsing jet nozzle that collapses the shoulder of the sand pocket while the dredge pump in the dredging device is installed, the range of dredging can be expanded in a plane, so it passes over the sand pocket. Efficient sand can be taken in the sand pocket efficiently.

  Also, in dredging equipment, the location where there is a large amount of sand drift is reduced by reducing the installation interval of the dredging pump at locations where there is a large amount of sand drift. The drift sand passing over the sand pocket can be efficiently taken into the sand pocket and dredged efficiently, and the dredging pump is not excessively installed at a place where the passing amount of the drift sand is small.

  Also, in the dredging device, the location of the dredged sand passing through is increased by deepening the installation position of the dredging pump at the location where the passing amount of drifting sand is deep, and the location where the passing amount of the drifting sand is shallow by reducing the installation location of the dredging pump. In many places, the width of the sand pocket becomes large, so that the sand drift can be efficiently taken into the sand pocket without passing the sand drift and can be efficiently dredged.

  In addition, by arranging the dredge pumps with different installation intervals or installation depths, the drifting sand passing over the sand pocket can be efficiently taken into the sand pocket and dredged efficiently.

  In addition, by installing a collapsible jet nozzle that collapses the shoulder of the sand pocket while a dredge pump with a different installation interval or depth is installed, the range of dredging can be expanded in a plane. The sand drift passing over the sand pocket can be efficiently taken into the sand pocket and dredged more efficiently.

  In addition, the jet pipes of dredging pumps with different installation intervals or installation depths or dredging pumps with staggered arrangements with different installation intervals or installation depths are made annular, and jet nozzles are provided inside them (three-dimensional This increases the bottom area of the sand pocket formed by the scissors, so that more efficient scissors can be achieved.

  Also, dredging pumps with different installation intervals or depths, and jet nozzles with dredging pumps with staggered arrangements with different installation intervals or installation depths are provided with jet nozzles that are oriented in multiple directions. As a result, the liquefaction range of the sand pocket can be expanded, so that the sand pocket can be enlarged and more efficient wrinkling can be achieved.

Hereinafter, embodiments of a dredge apparatus according to the present invention will be described with reference to the drawings. First, the dredge pump will be described, and then the dredge apparatus using the dredge pump will be described. In each embodiment, the same components are described with the same reference numerals, and only different components are different. A description will be given with reference numerals.

  1 and 2 show a bag pump 1 according to the first embodiment. The dredge pump 1 includes a high-pressure water injection pipe 4 having an ejector nozzle 3 at a tip 2 bent into a U-shape, and the ejector nozzle 3 is located in a suction port 5. The suction pipe 6 that sucks in the surrounding water by the injection of, and the annular jet pipe 7 positioned below the ejector nozzle 3 and the suction port 5.

  The high-pressure water injection pipe 4 and the jet pipe 7 are disposed opposite to each other so as to sandwich the suction pipe 6, and these are connected by two connecting members 8. The high-pressure water injection pipe 4 and the jet pipe 7 are connected to a water supply pipe 9 that is branched in two. The centrifugal pump 10 installed in the water supply pipe 9 supplies high-pressure water. ing.

  Further, the sand discharge pipe 6 for pumping the earth and sand water is connected to a lateral movement cage 11, and this cage 11 is connected to the slurry pit 13. Further, the tip 2 of the high-pressure water injection pipe that is bent in a U-shape and faces upward is located immediately below the suction pipe 6, and the ejector nozzle 3 at the tip is located in the suction port 5 in the skirt portion 14 of the suction pipe 6. is doing. The skirt portion 14 is connected to the diffusion portion 16 via the throat portion 15, and a suction portion 17 formed so as to be wide at the lower side and narrow toward the upper side is detachably installed inside the skirt portion 14.

  On the other hand, the jet pipe 7 located on the lower side of the suction port 5 is formed in a planar circular ring shape, and one branched water supply pipe 9 is connected thereto. In the jet pipe 7, a jet nozzle 18 having an annular center point coincident with the center point of the suction port 5 is installed toward the suction port 5, and the agitated sand is jetted to the suction port 5 side. Yes. The jet nozzle 18 can be provided not in a concentric circle on the inner peripheral surface of the jet pipe 7 but in a vertical direction.

  Therefore, when high-pressure water is supplied from the water supply pipe 9 to the high-pressure water injection pipe 4 by the centrifugal pump 10, this is jetted from the ejector nozzle 3 to the suction port 5. Water is sucked from the suction port 5. On the other hand, when high-pressure water is supplied from the water supply pipe 9 to the jet pipe 7 by the centrifugal pump 10, this is jetted from the jet nozzle 18 of the jet pipe 7 toward the suction port 5, and blows up sand and the like and is sucked from the suction port 5. It is. Then, the earth and sand water sucked from the suction port 5 is raised to the upper ridge 11 through the sand discharge pipe 6, is sent to the slurry pit 13 through this, and is delivered from there to a predetermined place by the pressure pump 12.

FIG. 3 shows the sand pockets 19 and 20 formed by the dredge of the dredge pump 1. A normal dredge pump is installed at a depth of 10 m from the seabed ground and the angle of repose is 45 °. In this case, the capacity of the sand pocket 19 is 1,047 m ³ . However, when the liquefaction range of the accumulated sand is increased by 1 m in diameter with the dredging pump 1 from this state, the capacity of the sand pocket 20 increases to 1,212 m ³ . At this time, since the installation depth of the ejector nozzle 3 is not changed, the efficiency of the soot can be basically increased without changing the supply energy.

  In addition, the jet pipe 7 is not limited to a planar circle as described above, and may be an ellipse or a polygon.

FIG. 4 shows a bag pump 21 of the second embodiment. This dredging pump 21 has a jet pipe 7 extending downward at the tip of an L-shaped water supply pipe 9 and provided with jet nozzles 18 oriented in a plurality of directions. The configuration is the same as that of the bag pump 1 of the first embodiment. Since the center axis of the jet pipe 7 and the center point of the ejector nozzle 3 are aligned and provided directly below , the depth of the sand pocket can be easily expanded. Further, since the jet nozzle 18 is installed in various directions such as downward, upward, obliquely upward, and laterally, the sedimentary sand can be liquefied effectively.

FIG. 5 shows sand pockets 22 and 23 formed by the dredging of the dredging pump 21 described above. A normal dredging pump is installed at a depth of 10 m from the seabed ground, and the angle of repose is 45. In the case of °, the capacity of the sand pocket 22 is 1,047 m ³ . However, when the liquefaction range of the accumulated sand is increased by 1 m by using the dredge pump 21 from this state, the capacity of the sand pocket 23 increases to 1,394 m ³ . At this time, since the installation depth of the ejector nozzle 3 is not changed, the efficiency of the soot can be basically increased without changing the supply energy.

  6 to 8 show the scissor device 25 according to the first embodiment. As shown in FIG. 6, the dredge device 25 is applied to a so-called sand bypass construction method in which sand 26 accumulated on the upper side is moved to the lower side by a sand discharge pipe 39, and a portion 27 where the sand is accumulated. Installed. Thus, when there is a shield 28 such as a port, fishing port or jetty in a direction perpendicular to the coastline, sand 27 accumulates on the upper side with respect to the prevailing direction of the waves due to coastal drift sand, and erodes on the lower side.

  The dredging device 25 includes a pier 29 installed at a location 27 where sand is accumulated, a plurality of dredging pumps 31 suspended from the pier 29 to a sedimentation unit 30 on the seabed, A water supply pipe 33 that pumps high-pressure water by a pump 32 and a sand discharge pipe 39 that delivers earth and sand water collected by a pump 31 for dredging.

  The dredge pump 31 includes a high-pressure water injection pipe 37 having an ejector nozzle 36 at a tip 35 bent into a U-shape, and the ejector nozzle 36 is positioned toward the suction port 38. It is composed of a sand discharge pipe 39 for sucking and delivering the surrounding earth and sand water by jetting high-pressure water, and a jet pipe 40 located below the suction port 38. The high-pressure water jet pipe 37 and the jet pipe 40 are in the middle. The water supply pipe 33 branched into two is connected, and high-pressure water is supplied by the centrifugal pump 32 installed in the water supply pipe 33.

  An automatic valve 41, a flow meter 42, and a pressure gauge 43 are installed in the water supply pipe 33 branched in two toward the dredge pump 31 side, and these are respectively connected to a personal computer (hereinafter referred to as a personal computer) 44 in the control room. Electrically connected, the automatic valve 41 is automatically opened and closed by a signal from here.

  On the other hand, the sand discharge pipe 39 is connected to the upper cage 34, which is connected to the slurry pit 45, and this slurry pit 45 is connected to the pressure pump 46. A pressure gauge 43, a flow meter 42, and a density meter 47 are also installed in the sand discharge pipe 39, and these are also electrically connected to the personal computer 44 described above.

Further, as shown in FIG. 8, the dredging pump 31 is installed in a staggered arrangement along the jetty 29 at the dredging location , so that the narrow portion of the sand pocket 48 is eliminated and the wide portion 49 is increased. At the same time, since the shallow portion of the sand pocket 49 is reduced and the deep portion 50 is increased, the drifting sand 51 passing over the sand pocket 48 can be reliably taken into the sand pocket 48, and efficient dredging can be performed. .

  FIG. 9 shows a scissor device 52 according to the second embodiment. This dredging device 52 is configured to reduce the dredging pump installation interval 54 at the point 53 where the passing amount of the drifting sand 51 is large, and to increase the setting interval 54 of the dredging pump at the point 55 where the passage amount of the drifting sand is small. Other than this, the configuration is the same as that of the scissor device 25 of the first embodiment. As a result, the portion 53 where the amount of sand drift is large overlaps with the adjacent sand pocket 48, the width of the sand pocket 48 is narrow and there is no shallow portion, and the wide and deep portion 49 is increased. Therefore, a large amount of the drifting sand 51 passing over the sand pocket 48 can be taken into the sand pocket 48 and dredged efficiently. On the other hand, since the dredging pump 31 is not excessively installed at the portion 55 where the amount of sand drift is small, an efficient design can be achieved.

  FIG. 10 shows the scissor device 56 of the third embodiment. In this dredging device 56, the location 53 where the amount of sand drifting is large has a deeper installation position of the dredging pump 31, and the location 55 where the amount of sand drifting is small is a shallow installation location of the dredging pump 31, Other than that, the configuration is the same as that of the scissor device 25 of the first embodiment. As a result, the sand pocket 48 has a large sand pocket 48 and the overlap with the adjacent sand pocket 48 also increases at the portion 53 where the amount of sand drifting is large. Therefore, a large amount of sand drift 51 passing over the sand pocket 48 is taken into the sand pocket 48. Can be dredged efficiently. On the other hand, since the dredging pump 31 is not excessively installed at the portion 55 where the amount of sand drift is small, an efficient design can be achieved.

  The dredge pumps 31 in the dredge devices 52 and 56 of the second and third embodiments can also be installed in a staggered arrangement (not shown). Since the sand pockets 48 are overlapped in a planar manner in this manner, the narrow portion of the sand pocket disappears and the wide portion 49 increases, and the shallow portion of the sand pocket decreases and the deep portion 50 increases. The sand drift 51 passing over the pocket 48 can be reliably taken into the sand pocket 48, and an efficient dredging can be performed.

  FIG. 11 shows a scissor device 57 according to the fourth embodiment. This dredge device 57 is installed between the dredge pumps 31 in which the collapsing jet nozzle 59 for collapsing the shoulder shoulder 58 of the sand pocket is arranged in a staggered manner, and other than this, the dredge device of the first embodiment 25. Since the liquefaction range of the accumulated sand is expanded by the collapsing jet nozzle 59, the sand drift 51 passing over the sand pocket 48 can be efficiently taken into the sand pocket 48 and dredged more efficiently.

  In addition, the collapsing jet nozzle 59 can also be installed between the dredging pumps 31 whose installation interval 54 or installation depth is changed as in the dredging devices 52 and 56 of the second and third embodiments. As a result, the range of dredging can be broadened in a plane, so that the sand drift 51 passing over the sand pocket 48 can be efficiently taken into the sand pocket 48 and dredged more efficiently.

  The dredging pumps 1 and 21 according to the first or second embodiment are installed in the dredging devices 25, 52, 56, and 57 according to the first to fourth embodiments and other dredging devices. be able to. By installing the dredge pumps 1 and 21, the capacity of the sand pocket 48 can be increased without changing the installation depth of the ejector nozzle 3, that is, basically without changing the supply energy. Can be raised.

It is sectional drawing of the scissors pump of 1st Embodiment. It is a perspective view of the dredge pump of 1st Embodiment. It is a conceptual diagram of a sand pocket. It is a front view of the dredge pump of 2nd Embodiment. It is a conceptual diagram of a sand pocket. It is a planar conceptual diagram of the dredge apparatus of 1st Embodiment. It is a three-dimensional conceptual diagram of the scissors apparatus of 1st Embodiment. (1) is the perspective view which carried out the staggered arrangement of the pumps for firewood, (2) is the same top view. (1) is sectional drawing which changed the installation space | interval of the dredge pump, (2) is the same top view. (1) is sectional drawing which changed the installation depth of the dredge pump, (2) is the same top view. (1) is a perspective view in which a collapsible jet nozzle is installed between stirrer-mounted dredge pumps, and (2) is a plan view of the same. It is a perspective view of the conventional bag pump. It is a conventional dredge apparatus, (1) is sectional drawing, (2) is a top view, (3) And (4) is sectional drawing of a sand pocket.

Explanation of symbols

1, 21, 31, 60, 71 Saddle pump 2, 35, 61 Tip 3, 36, 62 Ejector nozzle 4, 37, 63 High-pressure water injection pipe 5, 36, 64 Suction port 6, 39, 65, 73 Discharge Sand pipe 7, 40, 67 Jet pipe 8 Connecting material 9, 33, 72 Water supply pipe 10, 32 Centrifugal pump 11, 34 １２ 12, 46 Pump 13, 45 Slurry pit 14 Skirt part 15 Throat part 16 Diffusion part 17 Suction part 18 , 66 Jet nozzle 19, 20, 22, 23, 48, 74 Sand pocket 25, 52, 56, 57, 68 Dredge 26 Sediment water 27 Place where sand is deposited 28 Shield 29, 69 Jetty 30, 70 Sedimentation Part 41 Automatic valve 42 Flow meter 43 Pressure gauge 44 PC 47 Density meter 49, 76 Wide part 50 Deep part 51, 75 Drift sand 53 Excessive points 54 Installation interval 55 Low passages 58 Shoulder 59 Disintegration jet nozzle

Claims (7)

A pier installed at a place where sand is accumulated, a plurality of dredging pumps suspended from the pier to the sediment on the seabed, a water supply pipe for pumping high-pressure water to the dredging pump with a centrifugal pump, It consists of a sand drain pipe that delivers earth and sand water collected by a pump.
The dredge pumps are arranged in a staggered manner along the pier at the dredging location;
浚 渫 device characterized by. A pier installed at a place where sand is accumulated, a plurality of dredging pumps suspended from the pier to the sediment on the seabed, a water supply pipe for pumping high-pressure water to the dredging pump with a centrifugal pump, It consists of a sand drain pipe that delivers earth and sand water collected by a pump.
In places where there is a large amount of sand drift, the installation interval of the dredging pump has been reduced, and in places where there is little passage of the drift sand, the installation interval of the dredge pump has been increased.
浚 渫 device characterized by. A pier installed at a place where sand is accumulated, a plurality of dredging pumps suspended from the pier to the sediment on the seabed, a water supply pipe for pumping high-pressure water to the dredging pump with a centrifugal pump, It consists of a sand drain pipe that delivers earth and sand water collected by a pump.
The installation location of the dredging pump has been deepened at locations where there is a lot of drifting sand, and the installation location of the dredge pump has been shallowed at locations where there is little passage of drifting sand.
浚 渫 device characterized by. The dredge pumps are staggered along the pier where dredging
The scissor device according to claim 2 or 3, wherein A collapsing jet nozzle was installed to collapse the shoulder of the sand pocket while the dredge pump was installed,
The scissor device according to any one of claims 1 to 4, wherein The dredge pump has a high-pressure water injection pipe provided with an ejector nozzle at the tip bent upward, and the ejector nozzle is located in the vicinity of the suction port. It is composed of a sand discharge pipe for sucking and delivering and an annular jet pipe located below the suction port, and jet nozzles installed toward the suction port are provided at appropriate intervals in the jet pipe. ,
The scissor device according to any one of claims 1 to 5, wherein The dredge pump has a high-pressure water injection pipe provided with an ejector nozzle at the tip bent upward, and the ejector nozzle is located in the vicinity of the suction port, and the surrounding earth and sand water is removed by jetting the high-pressure water into the suction port. A sand discharge pipe for sucking and delivering; an L-shaped water supply pipe having a tip disposed below the suction port; and a jet pipe extending from the tip of the water pipe directly below the ejector nozzle. The pipe was provided with jet nozzles in multiple directions,
The scissor device according to any one of claims 1 to 5, wherein

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