JPWO2019187355A1 - Underwater and surface sediment / float removal device - Google Patents

Abstract

A hood that is installed in the water of the settling basin, has a space that accommodates water inside and is open downward, and at least part of its inner wall surface is formed to incline downward It is equipped with a drainage pipe for draining the water taken into the hood at or near the top of the hood to effectively remove suspended matter that does not completely settle in the settling basin by means of a suspended matter removal device on the water surface and the water surface. Provided is a sediment / floating matter removing device capable of removing the sediment.

Description

  TECHNICAL FIELD The present invention relates to a device for effectively removing sediments and suspended matter in water and on the surface of water in a water purification facility.

  In the conventional water purification treatment, many sedimentation tanks have a mechanism in which suspended solids are settled and the supernatant water is transported to a filtration tank by a collection trough (Patent Documents 1 and 2).

  However, there are floating substances that do not settle due to various factors such as poor aggregation and flow velocity. When these suspended solids are transported to the filter tank by the water collection trough, the filter tank is burdened.

  Further, although there are devices such as inclined plates that promote the sedimentation of suspended solids (Patent Documents 3 and 4), it is difficult to deposit suspended solids with a small specific gravity, and it is difficult to completely sediment the suspended solids with these devices. Met.

  Further, conventionally, it has been necessary to periodically insert an underwater robot or the like in a large-capacity water storage tank or elevated water tank to remove the deposits at the bottom.

Japanese Patent Laid-Open No. 2009-61407 JP-A-2007-69181 Japanese Patent Laid-Open No. 11-347316 JP 2005-13892A

  Therefore, the present invention provides a device for removing sediment / floating matter in water and on the surface of the water, which can overcome the drawbacks of the conventional water treatment equipment and effectively remove the suspended matter that does not completely settle in the settling tank. Is the task.

  The present invention is to solve the above-mentioned problems and is installed in the water of a sedimentation basin, has a space that is open at the bottom and accommodates water, and at least a part of its inner wall surface is at the lower side. Device for removing sediments / floats from water and a water surface, which is provided with a hood that is formed so as to be inclined toward the bottom of the hood, and a drain pipe for draining water taken into the hood is provided at or near the top of the hood. Is.

  Further, in the present invention, the hood is provided with a discharge hole at a top thereof, a intake port opening downward at a lower part thereof, and a ceiling wall extending from the peripheral edge of the intake port while converging to the discharge hole, A sediment / floating matter removing device for water and a water surface, comprising a drain pipe connected upward from the discharge hole so as to communicate with a space in the hood.

  In the invention, the hood has a pair of ceiling walls that are continuously provided on the upper side so as to extend toward the lower side while being separated from each other. Drainage that has a side wall formed to a predetermined height from the portion, extends along the continuous portion, has an opening formed in its peripheral wall, and both ends thereof penetrate the side wall and project outside the hood. It is a device for removing sediment and suspended matter in water and on the surface of water, which is equipped with a pipe.

  The apparatus for removing sediments / floats from water and water according to the present invention has a hood having a ceiling wall formed so that at least a part of its inner wall faces downward and is inclined. Collects in the direction of the top of the ceiling wall and can be efficiently guided to the top or a drainage pipe provided near the top to effectively remove the underwater and suspended matter on the water surface that cannot completely settle. Further, the upper surface of the ceiling wall plays the role of an inclined plate, which can promote the sedimentation of flocs and the like.

(A) A perspective view of an apparatus for removing sediment / floating matter in water and on the water surface according to the present invention. (B) The same sectional view. (A) Sectional drawing of what provided the flow path assembly in the inside of the hood of the sediment / floating matter removal apparatus of the underwater and the water surface concerning this invention. (B) Sectional drawing of a different embodiment which provided the flow path assembly inside the hood. (C) Sectional drawing of a different embodiment which provided the flow path assembly in the inside of a hood. (D) Sectional drawing of a different embodiment which provided the flow path aggregate in the inside of a hood. (A) A perspective view of a hood of a different embodiment of the apparatus for removing sediments / floats of water and water according to the present invention. (B) The perspective view of the hood of a different embodiment. (A) Sectional drawing of the hood of another embodiment of the apparatus for removing sediment / floating matter in water and on the water surface according to the present invention. (B) Sectional drawing of the hood of a different embodiment. (C) Sectional drawing of the hood of a different embodiment. (D) Sectional drawing of the hood of a different embodiment. (A) A horizontal cross-sectional view of the flow path assembly of the apparatus for removing sediment / floating matter in water and on the water surface according to the present invention. (B) A horizontal cross-sectional view of a flow channel assembly of a different embodiment. (C) A horizontal cross-sectional view of a flow channel assembly of a different embodiment. (D) A horizontal cross-sectional view of a flow channel assembly of a different embodiment. (E) A horizontal cross-sectional view of a flow channel assembly of a different embodiment. (A) A perspective view of the hood of the apparatus for removing sediments / floats of water and the surface of the water according to the present invention, which is provided with side walls. (B) The same sectional view. (C) Sectional drawing which provided the flow path aggregate in the inside of the hood. (D) Sectional drawing which provided the flow path assembly of different embodiment inside the hood. (A) AA 'sectional view of the apparatus for removing sediments / suspended matter on the surface of water according to the present invention, in which a fin is provided in a flow path assembly, (b) the same BB' sectional view, (c) Sectional drawing of AA 'of another embodiment which provided the fin in the flow path assembly of the apparatus for removing sediments / suspended material of the surface of water according to this invention, (d) same BB' sectional view. (A) Sectional drawing of the fin provided in the side wall of the apparatus for removing sediment / suspended material in water and on the surface according to the present invention. (B) The same top view. (A) A perspective view of the hood of the apparatus for removing sediment / suspended material from underwater and on the water surface according to the present invention, in which a blade portion is provided. (B) The same sectional view. (C) Sectional drawing of a different embodiment of the same blade part. (A) Sectional drawing of the division | segmentation state of what assembled | assembles the part which divided | segmented the plurality of parts of the sediment / float removal apparatus of the underwater and the water surface concerning this invention, and comprised one hood. (B) A sectional view of the assembled state of the hood. (A) The figure which represents typically about the installation example of the sediment / floating matter removal apparatus of the underwater and the water surface concerning the present invention. (B) The figure which represents typically about the different installation example of the sediment / floating matter removal apparatus of water and the surface of water. (C) The figure which represents typically about the different installation example of the sediment / floating matter removal apparatus of water and the surface of water. FIG. 3 is a cross-sectional view of an installation example of the apparatus for removing sediments / floats of water and water according to the present invention, in which a plurality of hoods are arranged one above the other. FIG. 3 is a diagram schematically showing an installation example of the apparatus for removing sediment / floating matter on water and on the surface according to the present invention, in which a downward hood and an upward hood are provided so as to face each other with a predetermined gap. (A) A diagram schematically showing an installation example of the apparatus for removing sediment / floating matter in water and on the surface according to the present invention, in which a plurality of hoods are continuously installed without gaps in the front-rear direction with respect to the flow of water. . (B) Sectional drawing of the hood which provided the air diffuser inside. FIG. 3 is a diagram schematically showing an installation example of the apparatus for removing sediment / floating matter in water and on the surface of water according to the present invention, in which an air diffuser is provided below a hood. (A) A diagram schematically showing an installation example of the apparatus for removing sediment / floating matter in water and on the surface according to the present invention, in which a plurality of hoods are provided one above the other. (B) The figure which represents typically the thing of a different embodiment which provided several hoods by piled up and down. (A) A diagram schematically showing an installation example of the apparatus for removing sediment / floating matter in water and on the surface according to the present invention, in which a plurality of hoods are provided one above the other. (B) Sectional drawing showing the aspect of the hood and the drainage pipe of FIG. FIG. 3 is a diagram schematically showing an installation example of the apparatus for removing sediments / floats of water and the surface of water according to the present invention, in which a plurality of hoods are provided one above the other. (A) An example of installation of the apparatus for removing sediment / floating matter in water and on the surface according to the present invention, in which a downward facing hood and an upward facing hood are provided so as to face each other with a predetermined gap therebetween. Fig. (B) The figure which represents typically the thing of a different embodiment which provided the downward hood and the upward hood so as to oppose each other. (C) The figure which shows typically the thing of a different embodiment which provided the downward hood and the upward hood so as to oppose each other. (D) A diagram schematically showing a different embodiment in which a downward hood and an upward hood are provided so as to face each other. (A) The figure which represents typically what provided several hoods up and down. (B) The figure which represents typically the thing of a different embodiment which provided several hoods by piled up and down. (C) The figure which represents typically the thing of a different embodiment which provided with several hoods piled up and down. (D) The figure which represents typically the thing of different embodiment which provided several hoods up and down. (A) The figure which represents typically what provided several hoods up and down. (B) The figure which represents typically the thing of a different embodiment which provided several hoods by piled up and down. (C) Sectional drawing of a drainage pipe. (A) Sectional drawing of what provided the water collecting part inside the hood. (B) AA sectional drawing of the same drain pipe. (C) Sectional drawing of a different embodiment of what provided the water collecting part inside the hood. (D) Sectional drawing of a different embodiment of what provided the water collecting part inside the hood. (A) The front view of the hood of the sediment / floating matter removal apparatus of the underwater and the water surface of another embodiment which concerns on this invention. (B) The side view. (C) A partial vertical center sectional view of the same side surface. (D) A central longitudinal cross-sectional view of the same. (A) A perspective view of a hood of the apparatus for removing sediment / floating matter in water and on the water surface according to the embodiment of FIG. 18. (B) The perspective view of the hood of a different embodiment. (A) The side view of the hood of a different embodiment of the apparatus for removing sediment / suspended material in water and on the surface according to the present invention. (B) The side view of the hood of a different embodiment. (A) Partial sectional view of a hood of different embodiments of the apparatus for removing sediments / floats of water and water according to the present invention. (B) Partial sectional view of a hood of a different embodiment. (A) A cross-sectional view of a hood of a device for removing sediment / floating substances in water and on the surface according to the present invention, in which a flow path assembly is provided inside. (B) Sectional drawing of a different embodiment which provided the flow path assembly in the inside of the hood of the sediment / floating matter removal apparatus of water and the surface of water. (A) The figure which represents typically about the installation example of the sediment / floating matter removal apparatus of the underwater and the water surface concerning the present invention. (B) The figure which represents typically about the different installation example of the sediment / floating matter removal apparatus of water and the surface of water. (C) The figure which represents typically about the different installation example of the sediment / floating matter removal apparatus of water and the surface of water. (A) A diagram schematically showing an installation example of the apparatus for removing sediment / floating matter in water and on the surface according to the present invention, in which a plurality of hoods are arranged one above the other. (B) The figure which represents typically what installed the several food | hoods up and down in the different installation example of the sediment / floating matter removal apparatus of water and the surface of water. The figure which represents typically what installed the several food | hoods up and down in the different installation example of the sediment / floating matter removal apparatus of water and the surface concerning this invention. FIG. 3 is a diagram schematically showing an installation example of the apparatus for removing sediment / floating matter on water and on the surface according to the present invention, in which a downward hood and an upward hood are provided so as to face each other with a predetermined gap. (B) A diagram schematically showing different installation examples of the apparatus for removing sediment / suspended material in water and on the water surface, in which a downward facing hood and an upward facing hood are provided so as to face each other with a predetermined gap. (A) A diagram schematically showing an installation example of the apparatus for removing sediment / floating matter in water and on the surface according to the present invention, which is installed so that the top wall of the hood is parallel to the flow of water. (B) A diagram schematically showing an example of installation of a sediment / floating matter removing device in water and on the water surface, which is installed so that the top wall of the hood faces the flow of water. FIG. 3 is a diagram schematically showing an installation example of the apparatus for removing sediments / floats of water and the surface of water according to the present invention, in which a plurality of hoods are provided one above the other. FIG. 3 is a diagram schematically showing an installation example of the apparatus for removing sediments / floats of water and the surface of water according to the present invention, in which a plurality of hoods are provided one above the other.

  Hereinafter, embodiments of the apparatus for removing sediments / floats of water and water according to the present invention will be specifically described with reference to the drawings. The present invention is not limited to these embodiments.

  The apparatus for removing sediments / floats of water and the surface of water according to the present invention is installed in the water of a sedimentation basin, has a space for accommodating water therein, and is open downward, and at least a part of its inner wall surface. Is provided with a hood having a ceiling wall formed so as to incline toward the lower side, and a drain pipe for draining the water taken into the hood is provided at or near the top of the hood. Hereinafter, the structure of the apparatus for removing sediments / floats of water and water according to the present invention will be described in detail.

  FIG. 1 (a) is a perspective view of an apparatus for removing sediment / floating matter in water and on the surface of the water according to the present invention, and FIG. 1 (b) is a sectional view of the same. The hood 1 which constitutes the underwater and water surface floating material removal apparatus according to the present invention has a space 101 for accommodating water inside, the lower side is open, and the inner wall surface 114 faces downward from the top to the bottom. The ceiling wall 11 is formed so as to be inclined. The top wall 11 has a discharge hole 111 formed at the top thereof, and an intake port 112 having an opening area larger than that of the discharge hole 111 is formed below the discharge hole 111, and a peripheral edge 113 of the intake port 112 extends to the discharge hole 111. Stretching while converging. Further, the drainage pipe 2 is connected to the discharge hole 111 so as to extend upward. The drain pipe 2 communicates with the space 101 in the hood 1, and drains water and suspended matter in the space 101 to the outside of the sedimentation basin via the drain pipe 2.

  In the hood 1 of the present embodiment, the outer shape of the ceiling wall 11 is formed into a substantially truncated cone shape, but a part or all of the inner wall surface 114 of the ceiling wall 11 is formed so as to face downward and incline. However, the outer shape is not limited to this, and may be, for example, a truncated pyramid shape as shown in FIG. 3A or a dome shape as shown in FIG. 3B. In this way, the inner wall surface 114 of the hood 1 is formed so as to be inclined toward the lower side and converges from the peripheral edge 113 of the intake port 112 to the discharge hole 111 side, so that it is taken into the space 101 from the intake port 112. The suspended matter having a small specific gravity is sucked toward the discharge hole 111 in the upper center of the ceiling wall 11 and effectively guided into the drainage pipe 2. Furthermore, by making the ceiling wall 11 into a truncated cone shape, a truncated pyramid shape, or a dome shape, the upper surface of the ceiling wall 11 serves as an inclined plate, and it is possible to promote the sedimentation of floating substances such as flocs. The inclination angle of the ceiling wall 11 is not particularly limited, and even if the inclination is 1 degree with respect to the horizontal, the effect is obtained.

  1 to 3, the top wall 11 continuously converges from the peripheral edge 113 to the connection portion with the drainage pipe 2, but the shape of the top wall 11 is not limited to this and, for example, FIG. As in (a), the periphery of the connecting portion with the drainage pipe 2 may be a top surface 18 extending in the horizontal direction, or may be formed so as to converge from the peripheral edge 113 to the edge of the top surface 18. . Further, as another shape of the ceiling wall 11, as shown in FIG. 4B, a vertical surface 19 which is not inclined may be formed on a part of the ceiling wall 11. By providing such a vertical surface 19, even in the case where a plurality of hoods 1 are vertically stacked, the drainage pipe 2 is easily accessible from the vertical surface 19 side without being obstructed by the hood 1. The installation and maintenance work of the device underwater becomes easy. Further, as shown in FIG. 4 (c), a part of the top wall 11 also includes a part that is inclined backward so that the inner wall surface 114 faces upward instead of downward.

  The drainage pipe 2 that is connected to the discharge hole 111 and rises in the vertical direction branches in the middle into a drainage pipe 21 that extends in the horizontal direction and an air vent pipe 24 that rises in the vertical direction as it is. A drain valve 22 is provided in front of the exhaust port 23 at the end of the drain pipe 21, and an air vent valve 25 is provided in front of the exhaust port 26 at the end of the air vent pipe 24. The air vent pipe 24 may be provided as necessary. When the air vent pipe 24 is not provided, only the drain pipe 21 that is continuous from the drain pipe 2 in the lateral direction may be provided. By providing the air vent pipe 24 as in this embodiment, the air that has entered the drain pipe 2 from the hood 1 can be effectively drained, and water can be smoothly drained from the drain pipe 21. Further, a part of the drain pipe 21 may have a bellows structure, and by thus forming the drain pipe 21 with a bellows structure, the position of the hood 1 can be easily adjusted when the water level of the sedimentation basin 3 changes.

  The drain pipe 2 is not limited to one for one hood 1, and a plurality of drain pipes 2 may be provided if necessary. For example, as shown in FIG. 4D, in the case of the hood 1 of a type having a wide frontage 112, it is provided in the middle of the ceiling wall 11 in addition to the drain pipe 2 connected to the discharge hole 111 at the top of the hood 1. The drainage pipe 2 ′ connected to the discharge hole 111 ′ may be separately provided. In FIG. 4 (d), two such drain pipes 2'are separately added, but the number is not limited to this. Further, the drain pipe 2'may be provided with an air vent pipe 24 'if necessary.

  The space 101 in the hood 1 may be a complete cavity as shown in FIG. 1 (b), but if necessary, the flow passage assemblies 14 a, 14 b shown in FIGS. 2 (a) and 2 (b) may be provided. It may be provided. The flow path assemblies 14a and 14b divide the space 101 in the hood 1 in the horizontal direction, the upper opening 141 thereof is toward the discharge hole 111 side of the hood 1, and the lower opening 142 thereof is the intake port of the hood 1. The hood 1 is provided so as to extend in the vertical direction so as to face the 112 side.

  The flow channel assembly 14a of FIG. 2A is formed by bundling a plurality of thin tubes. Each of these thin tubes is formed so that the diameter thereof becomes smaller from the lower end to the upper end, and in the central portion of the hood 1, the vertical direction is increased, and as it approaches the ceiling wall 11, the ceiling wall 11 is inclined. Each is bundled at an appropriate angle so as to follow. As a result, the entire shape of the bundled thin tubes becomes a substantially truncated cone shape similar to the shape of the space 101 formed by the top wall 11 of the hood 1. The upper opening 141 of the flow path assembly 14a is located below the discharge hole 111 of the hood 1, and the lower opening 142 is provided to be located at the intake port 112 of the hood 1. It is not limited to this. The flow channel assembly 14a is attached to the hood 1 by fixing the peripheral wall of the thin tube located on the outermost peripheral side to the inner wall surface 114 of the hood 1.

  2B, the individual thin tubes are formed to have the same diameter from the upper end to the lower end, and all are bundled so as to extend in the vertical direction. The length of the thin tube is formed so as to extend along the slope of the wall 11 on the center side and decrease toward the end. As a result, the entire shape of the bundled thin tubes becomes a substantially truncated cone shape similar to the shape of the space 101 formed by the top wall 11 of the hood 1. Further, the flow path assembly 14b is provided slightly lower than the top wall 11 so as to form the gap 102 between the flow path assembly 14b and the inner wall surface 114 of the hood 1. The flow channel assembly 14b is attached by fixing the peripheral wall of the outermost thin tube and the inner wall surface 114 of the hood 1 with the fixing member 143.

  As shown by the arrows in the figure, the flow passage assemblies 14a and 14b both take in water and suspended matter from the lower opening 142 of the thin tube and discharge them into the hood 1 through the upper opening 141. In the case of 14b, the material once discharged into the gap 102 moves directly to the discharge hole 111 along the ceiling wall 11 and is finally discharged to the drainage pipe 2. By providing such a flow path assembly 14 inside, the horizontal cross section of the space 101 in the hood 1 is subdivided by a plurality of thin tubes, and the individual opening areas are reduced, so that the wicking effect of the hood 1 is maximized. Can be demonstrated. Further, the flow of water in the hood 1 is arranged so as to be directed upward, and unnecessary convection such as a lateral flow does not occur, so that suspended matter can be effectively sucked up.

  The flow channel assemblies 14a and 14b are formed by bundling a plurality of cylindrical thin tubes as shown in FIG. 5A, but the cross-sectional shape of each individual thin tube is not limited to a circular shape. A thin tube having a square or rectangular cross section, a so-called honeycomb structure in which regular hexagonal thin tubes as shown in FIG. 5B are bundled, or another cross section may be used. The thin tubes forming the flow channel assemblies 14a and 14b can be formed to have an arbitrary thickness, but in order to maximize the above-mentioned effects, the inner diameter thereof should be formed within a range of 0.1 mm to 50 mm. preferable. The inner diameters of the individual capillaries do not have to be the same, and may differ depending on the location. Further, a gap may not be provided between the adjacent thin tubes, and when the gap is provided, the gap is not particularly limited. Furthermore, as long as the horizontal cross-section can be subdivided in the space 101 of the hood 1, the assembly is not limited to a bundle of thin tubes, and as shown in FIGS. You may form and partition. Alternatively, as shown in FIG. 5E, a block-shaped member 145 may be formed by penetrating a plurality of vertical holes 146 that serve as flow paths.

  When the flow path assembly 14 is formed by bundling a plurality of cylindrical thin tubes, the diameter of the thin tubes becomes narrower from the lower part to the upper part, or the same diameter is formed from the upper part to the lower part. There is no limitation, and as shown in FIG. 2C, the capillaries may be formed so that the diameter becomes smaller from the upper part to the lower part. As a result, the flow velocity on the side of the lower opening 142 having a smaller diameter is increased, and the suction effect can be improved. In addition, since the diameter of the upper opening 141 side is large, it is possible to obtain an effect that it is difficult for clogging of suspended matter and the like. 2C, the individual thin tubes are fixed to each other by a rod-shaped fixing member 143 that does not hinder the flow of water, and also fixed to the inner wall surface 114 of the hood 1. Has been done.

  Further, as shown in FIG. 2D, a plurality of vertical hole portions 146 are formed by penetrating the block-shaped member 145 as the flow path assembly 14d, and each vertical hole portion 146 goes from the upper portion to the lower portion. The diameter may be reduced accordingly. This one also has the same effect as the embodiment of FIG.

  Further, a side wall 12 may be provided below the top wall 11 of the hood 1 as needed, as shown in FIG. The side wall 12 is continuously provided below the lower end of the ceiling wall 11, and in the present embodiment, it is hung from the ceiling wall 11, and its outer shape is formed into a square pole shape. However, as shown in FIG. When 1 is a truncated cone, it may be a column that hangs from the ceiling wall 11. Further, the side wall 12 is not limited to the one that hangs down in the vertical direction, and may be formed so as to be inclined and extend while spreading outward downward. In this way, by providing the side wall 12 below the ceiling wall 11, the capacity of the internal space 101 increases, and the amount of water and the amount of suspended matter that can be taken into the hood 1 can be increased. The side wall 12 can be formed with an arbitrary inclination angle, but it is preferable to provide the side wall 12 so as to be inclined or vertical with respect to the horizontal in the range of 45 to 90 degrees.

  Even when the side wall 12 is provided, the flow path assembly 14 may be provided in the hood 1 if necessary. As shown in FIGS. 6 (c) and 6 (d), the inside of the ceiling wall 11 has the same configuration as that of FIGS. 2 (a) and 2 (b), and the side wall 12 has a thin tube formed from the upper part to the lower part with the same diameter. May be bundled so as to extend in the vertical direction, and the whole bundled shape may be similar to the shape of the internal space of the side wall 12. The flow channel assembly 14d shown in FIG. 6D can be attached to the hood 1 by fixing the peripheral wall of the outermost thin tube to the inner wall of the side wall 12. The flow passage assemblies 14c and 14d may be provided not only on the hood 1 and the side wall 12 but also inside the hood 1 or only inside the side wall 12. Further, when it is provided in the side wall 12, it may be provided only in a part of the height thereof. Further, it goes without saying that the flow path assembly 14 includes one in which a plurality of small chambers are partitioned and formed by the partition plate 144, and one in which a plurality of vertical hole portions 146 are perforated in the block-shaped member 145.

  Further, fins protruding in the lateral direction may be separately provided inside the flow path assembly 14. In the embodiment shown in FIGS. 7A and 7B, the flow path assembly 14 in the side wall 12 is partitioned and formed by a plurality of partition plates 147, and the fins 148 are attached to the partition plates 147 and the fins 148 are attached to the side walls 12. The fins 149 are provided so as to project in the horizontal direction. The fins 148 are provided so as to project in the direction of the left and right side walls 12 from the partition plate 147 standing upright in the center, whereas the fins 149 extend from the left and right side walls 12 in the direction of the center partition plate 147. It is provided so as to project. As shown in FIG. 7A, the middle three fins 148 and 149 project alternately at different heights, and the uppermost and lowermost fins 148 and 149 face each other at the same height. A gap 103 is formed between the protrusions, through which water passes.

  In the embodiment shown in FIGS. 7C and 7D, the fins 148 are provided so as to project toward the left and right side walls 12 with respect to the partition plate 147 provided upright in the center. Further, fins 149 are provided on the left and right side walls 12 so as to project toward the central partition plate 147. The fins 148 and 149 project at the same height so as to face each other, and a gap 103 through which water passes is formed between them. In addition, it is preferable that the vertical or lateral distance between these fins is 5 cm or less.

  As described above, by providing the fins 148 and 149 inside the flow channel assembly 14, a swirl region is generated mainly below the fins 148 and 149, and separation of suspended solids is promoted. The fins 148 and 149 may be provided not only on the partition plate 147 and the side wall 12 but also on the ceiling wall 11. Further, the fins are not limited to those protruding in the horizontal direction as shown in FIG. 7, and may be inclined so that the tip side faces downward as shown in FIG. 8 (a). Although the inclination angle is not particularly limited, it is preferably in the range of 0 to 60 degrees with respect to the horizontal. Further, the opening 104 may be provided between the fins 148 and 149 and the partition plate 147 and the side wall 12. Since the air escapes upward from the opening 104, it is possible to prevent the air from accumulating at the connecting portion between the fins 148, 149 and the partition plate 147 or the side wall 12. The shape and size of the opening 104 are not limited, and may be formed in a plurality of holes, for example.

  Further, as shown in FIGS. 9A and 9B, a blade portion 13 may be provided on the lower portion of the side wall 12 if necessary. The blade 13 is formed so as to extend from the lower end of the side wall 12 to the outside of the hood 1 while being inclined. In this way, by providing the vane portion 13 that inclines downward and outward in the lower portion of the side wall 12, it is possible to promote the sedimentation of floating substances such as flocs, and further, when water flows from the lower portion to the upper portion. The floating matter can also be effectively taken into the hood 1 by hitting the blade portions 13. Also in the case where the vane portion 13 is provided, the flow passage assembly 14 in which a plurality of thin tubes are formed in a bundle may be provided in the space 101 in the hood 1 if necessary. In this embodiment, the pair of blades 13 is provided on the opposing side walls 12, but it may be provided on only one of the side walls 12, or on all the front, rear, left, and right side walls 12. Alternatively, only a part of the blade 13 may be provided for one side wall 12.

  Further, as shown in FIG. 9C, folding pieces 131 folded back from the blade portion 13 may be provided on the left and right side portions and the lower side portion of the blade portion 13 which are not connected to the side wall 12. By providing the folding piece 131, the suspended matter that has entered the lower side of the blade portion 13 can be effectively taken into the hood 1 without escaping from the left or right of the blade portion 13 or the lower portion thereof.

  Alternatively, the hood 1 may be configured by assembling a plurality of divided parts to form one hood 1. For example, as shown in FIG. 10 (a), three parts including hoods 10a, 10b, and 10c may be provided, and these parts may be assembled to form one hood 1 (FIG. 10b). In the hood 1 of FIG. 10, a space 101 is formed by hollowing out the inside of the block body, a drainage channel 103 is formed so as to communicate with the space 101, and the drainage pipe 2 is connected to the outlet of the drainage channel 103. There is. The flow channel assemblies 14 provided in the hoods 10a, 10b, and 10c are fixed to the side wall 12, but the fixing method to the hood 1 is not limited to this. Further, the hood 1 of FIG. 10 shows a mode in which the hood 1 is installed so that the intake port 112 side faces upward, but the orientation of the hood 1 is not limited to this.

  FIG. 11 schematically shows an installation example of the apparatus for removing sediments / floats of water and water according to the present invention. In the figure, the arrows indicate the flow of water. In the present embodiment, in the process of water flowing from the right to the left in the settling basin 3, water is taken into the hood 1 provided midway, A part of the water is drained from the drain pipe 2 to the outside of the settling basin 3 via the drain pipe 21. At this time, suspended matter in the water is also effectively collected by the hood 1 and discharged from the discharge port 23. As shown in FIG. 11 (a), the drainage pipe 21 is provided so that the discharge port 23 is exposed to the outside of the sedimentation basin 3, and in particular, the position where the discharge port 23 is lower than the water surface W in the sedimentation basin 3. It is arranged so that. The drainage pipe 21 is arranged so that not only the drainage port 23 but also the entire drainage pipe 2 including the drainage valve 22 is lower than the water surface W.

  In this way, by making the discharge port 23 lower than the water surface W, the water in the sedimentation basin 3 is sucked into the drain pipe 2 from the space 101 in the hood 1 by the atmospheric pressure applied to the water surface W, and the drain pipe 21 Finally, the water is drained from the discharge port 23 through. The amount of water taken in from the hood 1 can be appropriately adjusted by the drain valve 22.

  FIG. 11 (b) schematically shows a sediment / floating matter removing device that drains water from the hood 1 to the drainage trough 4 provided in the sedimentation basin 3. The drainage trough 4 is formed in a trough shape capable of storing a predetermined amount of water therein, but the drainage trough 4 does not flow directly into the settling tank 3 beyond the upper part of the peripheral wall thereof, so that the water flows into the settling tank 3 inside. is set up. As shown in the drawing, the drainage pipe 2 stands up from the connection portion with the hood 1 and is connected to the bottom surface of the drainage trough 4, and the discharge port 23 thereof is provided so as to be exposed in the drainage trough 4. As described above, since the drainage pipe 2 of the present embodiment is formed by the straight pipe, the air in the drainage pipe 2 is easily released without providing the air vent pipe 24, and the drainage can be smoothly performed.

  The water in the drainage trough 4 is drained to the outside of the sedimentation basin 3 by a drain pipe or the like (not shown), and the water surface W2 in the drainage trough 4 is always kept lower than the water surface W1 in the sedimentation basin 3. . Then, since the atmospheric pressures on the water surface W1 and the water surface W2 are equal, the water in the settling basin 3 having a high water level is sucked into the hood 1 through the drain pipe 2 in an attempt to balance the water surface W1 and the water surface W2. The water is collected into the drainage trough 4, and then drained to the outside of the settling basin 3 by a drain pipe or the like leading to the outside.

  In the embodiment of FIGS. 11 (a) and 11 (b) described above, water is sucked from the hood 1 by utilizing the difference in water level, but the water absorbing means is not limited to this and is shown in FIG. 11 (c). As described above, the water absorption means by the pump 5 may be provided in the middle of the drainage pipe 21, and in this case, the discharge port 23 and the drainage pipe 21 may be higher than the water surface W of the sedimentation basin 3. As the pump 5, a general pump such as a vacuum pump or a water absorption pump can be used. Further, the water absorbing means is not limited to this, and the water absorbing means by the pump 5 and the water absorbing means utilizing the water level difference may be combined.

  The underwater and water surface sediment / floating matter removing apparatus of the present invention may be provided with a plurality of hoods 1, and as an example thereof, a plurality of hoods 1 may be vertically stacked. When stacking a plurality of hoods 1 on the upper and lower sides, as shown in FIG. 12, the uppermost hood 1a can be connected to the hood 1b arranged below it by a drain pipe 27a. The drain pipe 27a is provided so as to hang down from the discharge hole 111a of the hood 1a on the upper side, and is connected to the discharge hole 111b of the hood 1b from above. Similarly, the hood 1b is connected to the hood 1c arranged therebelow by a drain pipe 27b. The drain pipes 27a, 27b have a plurality of slit-shaped openings 271a, 27b formed in the hoods 1a, 10b in the vicinity of the discharge holes 111a, 11b, respectively, and drain water and suspended matter from the openings 271a, 27b. It can be taken into the tubes 27a, b. In the present embodiment, the openings 271a, b are formed in the shape of slits extending in the circumferential direction of the drain pipes 27a, b, but they may be formed in the shape of slits extending in the axial direction. Other shapes such as a circular shape other than the above may be used. Further, the opening diameters of the opening portions 271a and 271a are not limited, and the opening diameters may be different from each other. That is, when the hood 1 and the drainage pipe 2 are closer to each other, the flow velocity in the hood 1 is also faster. The openings 271a and b near the drainage pipe 2 have a smaller opening diameter. On the contrary, by increasing the opening diameter of the opening farther from the connecting portion, the amount of water taken in can be made constant regardless of the position of the opening.

  In this embodiment, the water and suspended matter taken into the lowermost hood 1c flow into the drain pipe 27b connected to the upper portion as it is from the discharge hole 111, but taken into the hoods 1a and 1b. Are sucked into the drainage pipes 27a, b through the slit-shaped openings 271a, b of the drainage pipes 27a, b provided in the hoods 1a, 1b, move to the drainage pipes 2 together, and finally It is discharged from the discharge port 23. Although the three hoods 1a, 1b, and 1c are vertically stacked in this embodiment, the number of hoods 1 is not limited to this, and may be increased or decreased as necessary.

  Regarding the installation method of the apparatus for removing sediments / floats of water and the surface of the water according to the present invention, the intake port 112 of the hood 1 is usually installed so as to face downward. It may be installed so as to face upward, and further, as shown in FIG. 13, a downward hood 1a and an upward hood 1b may be provided so as to face each other with a predetermined gap. By installing in this way, among the suspended matter passing between the upper and lower hoods 1a and b, those having a low specific gravity are installed in the hood 1a installed above, and those having a large specific gravity are installed below. It is effectively taken into the hood 1b. When the downward facing hood 1a and the upward facing hood 1b are installed to face each other, they are basically arranged at the same position in the horizontal direction so that the centers of the hoods 1a and b are aligned with each other. It may be installed by shifting its position to the front, rear, left and right. Further, the angles of the hoods 1a and 1b are basically arranged such that the intake ports 112 are parallel to each other, but the angle is not limited to this, and for example, with respect to the intake port 112 of the hood 1a. It may be installed at an angle so that the intake port 112 of the hood 1b is inclined. In the embodiment of FIG. 13, the upward hood 1b is installed so as to face the downward hood 1a, but the effect of the present invention can be obtained even if the upward hood 1b is installed alone.

  Further, regarding the installation method of the apparatus for removing sediment / floating material in water and on the surface according to the present invention, a plurality of hoods 1 may be installed continuously in the front-back direction with respect to the flow of water. Further, the plurality of hoods 1 may be installed in a grid pattern that is continuous in the vertical direction, the horizontal direction, and the diagonal direction in a plan view. In these cases, a gap may be provided or may not be provided between the adjacent hoods 1. For example, in FIG. 14 (a), three sets of a downward facing hood 1a and an upward facing hood 1b which are provided so as to face each other with a predetermined gap therebetween are continuously provided. In this way, when the front and rear are continuously installed, the hood 1a and the hood 1b located at the forefront with respect to the flow of water, the middle, and the hood 1a and the hood 1b located at the rearmost are sequentially arranged. The water moves, but the bypass generated in the hood 1 at that time allows the precipitate to be effectively separated and discharged from the upper and lower drain pipes 2. In particular, as in the present embodiment, the side wall 12a of the hood 1a located on the most upstream side with respect to the flow of water is made longer, the side wall 12b of the hood 1b is made shorter, and conversely, the side wall 12a of the hood 1a behind it is made longer. The lengths of the side walls 12a and 12b may be staggered in the front and rear such that the side wall 12b of the hood 1b is shortened and the side wall 12b of the hood 1b is lengthened, whereby the water meanders up and down to further enhance the bypass effect. . In addition, in this embodiment, three sets of the hood 1a and the hood 1b are continuously installed at the front and the rear, but the number of the hood 1a and the hood 1b continuously connected is not limited to this, and may be appropriately increased or decreased.

  Further, regarding the installation method of the apparatus for removing sediment / floating matter in water and on the surface according to the present invention, as shown in FIG. 15, an air diffuser 6 may be appropriately provided below the hood 1. By providing the air diffuser 6 below the hood 1 to blow air, suspended matter as well as air bubbles rise and can be efficiently fed into the hood 1. Furthermore, by increasing the amount of air diffused by the air diffuser on the downstream side of the water flow, air bubbles play a role of a kind of air curtain, and it becomes difficult for suspended solids to reach the downstream side of the hood 1, and the hood 1 is more efficient. It becomes possible to take in. From the air diffuser 6, in addition to air bubbles (nano bubbles, micro bubbles, normal bubbles), water, viscous bubbles (foam such as beer, shampoo, etc.), or a mixture thereof is used. It may be generated. Note that the nanobubbles and microbubbles have weak buoyancy and may be washed away with water before being taken into the hood. Therefore, a plurality of air diffusers may be provided and nanobubbles, microbubbles, ordinary bubbles, liquids (water, etc.) may be used together or in combination.

  The installation of the air diffuser 6 is not limited to below the hood 1, and may be provided inside the hood 1b, for example, as shown in FIG. When the flow passage assembly 14 is provided inside the hood 1, it is preferable to provide the air diffuser 6 between the discharge hole 111 and the flow passage assembly 14 as shown in FIG.

  In addition, FIG. 16 shows an example of an installation method of the apparatus for removing sediment / float matter in water and on the surface of the water according to the present invention, in which a plurality of hoods 1 are vertically stacked. In FIG. 16 (a), two sets of three hoods 1a, 1b, and 1c are placed side by side in the front-back direction with respect to the flow of water. These two sets of water and surface sediment / floating matter removing devices are connected in a drain pipe 21, and water and floating matter taken in from any of the hoods 1 are finally discharged from the same outlet 23. . Further, like the uppermost hood 1a in FIG. 16B, the hoods 1 may be arranged without a gap between the adjacent hoods 1. In this embodiment, only the uppermost hood 1a is provided without a gap, but the hood 1 without a gap is not limited to the uppermost one.

  In the installation method of the apparatus for removing sediment / floating matter on water and on the water surface according to the present invention in which a plurality of hoods 1 are vertically stacked, the orientations of the hoods 1 do not necessarily have to be the same. ), Among the three hoods 1a, 1b, 1c, only the middle hood 1b may be installed upward. In this case, the hood 1a and the hood 1b are connected to each other by the drain pipe 27, but as shown in FIG. 17 (b), the drain pipe 27 is provided near the discharge holes 111a, b in the hoods 1a, 1b. A plurality of slit-shaped openings 271a, 271b are formed respectively. Further, as in the embodiment of FIG. 17A, a hood 1d facing downward may be provided below the hood 1c provided downward so as to face the hood 1d.

  Further, FIG. 18 shows a different installation method of the apparatus for removing sediment / float matter on the water surface and the water surface according to the present invention in which a plurality of hoods 1 are vertically stacked. In this embodiment, two sets of three hoods 1a, 1b, 1c are stacked side by side in the front-back direction with respect to the flow of water, but before and after the two sets of hoods 1a, 1b, 1c, A barrier 7 is provided for each. The barrier 7 has a gap with the bottom surface of the sedimentation basin 3 on the upstream side of the hoods 1a, 1b, 1c, and has a gap with the water surface W on the downstream side of the hoods 1a, 1b, 1c. Is formed. In this way, by arranging the barrier 7 with a gap between the bottom surface or the water surface W before and after the two sets of hoods 1a, 1b, 1c, the flow of water is made to flow downwards of the hoods 1a, 1b, 1c. Can be regulated upwards from above, and the suspended matter can be effectively taken into and removed from the hood 1.

  Regarding the apparatus for removing sediments / floats of water and the surface of the water according to the present invention, in which the flow path assembly 14 is provided in the hood 1, when a plurality of the hoods 1 are installed according to FIGS. A specific example of will be described. In these embodiments, the individual thin tubes forming the flow passage assembly 14 in each hood 1 are aligned such that the upper opening 141 on the discharge hole 111 side of the hood 1 has a substantially horizontal height. However, the embodiment is not limited to this.

  In FIG. 19A, a downward hood 1a and an upward hood 1b are provided so as to face each other, and between the downward hood 1a and the upward hood 1b, that is, the lower opening 142a of the flow path assembly 14a. A water flow path is formed between the pipe assembly 14b and the lower opening 142b. An air diffuser 6 may be provided in this flow path, and air bubbles generated by the air diffuser 6 raise floating substances contained in the water flowing through the flow path between the hood 1a and the hood 1b, thereby increasing the flow path aggregate. It can be efficiently fed into 14a. The air diffuser 6 may be provided in the same manner as in FIGS. 19B to 19D.

  In the case of FIG. 19B, a barrier 8 having a cross-sectional shape in which a substantially V-shape is laid is provided between the downward hood 1a and the upward hood 1b. By this barrier 8, the water flowing between the hood 1a and the hood 1b bypasses up and down, and the suspended matter can be efficiently sent into the flow path assemblies 14a and 14b. In this embodiment, the shape of the barrier 8 is substantially V-shaped, but the shape is not limited to this and may be a flat plate having a substantially I-shaped cross section. Further, the air diffuser 6 of FIG. 19A and the barrier 8 of FIG. 19B may be installed in combination. Specifically, as shown in FIG. 31B, which will be described later, by arranging the barrier 8 and the air diffuser 6 in combination, separation of suspended matter becomes easier and effective. The number, size, and shape of the air diffuser 6 and the barrier 8 are not particularly limited, and the combination method thereof is not limited. As an example, by changing the height (position) at which the barrier 8 is provided on the upstream side and the downstream side, the water flow can be detoured vertically.

  In the case of FIG. 19C, the length of the thin tube forming the flow path assembly 14a of the downward hood 1a is formed so as to be gradually reduced from the side wall 12a side toward the center side of the hood 1a ( No thin tube is provided in the central portion), so that the lower opening 142a side is entirely concave. On the other hand, the length of the capillaries constituting the upward flow passage assembly 14b of the hood 1b is gradually increased from the side wall 12b side toward the center side of the hood 1a, whereby the lower opening 142b is formed. The entire side is convex. As a result, the water flow path between the opposing hoods 1a and 1b has an inverted V shape in which the side wall 12 side is low and the central portion is high, forming a flow path meandering in the height direction. The water flowing through the flow path meanders up and down to promote the bypass, and the suspended matter can be efficiently fed into the flow path assemblies 14a and 14b.

  In the case of FIG. 19 (d), the length of the thin tube forming the flow passage assembly 14a of the downward hood 1a is formed so as to be corrugated from one side wall 12a side to the other side wall 121a side. The lower opening 142a side is uneven. On the other hand, the capillaries forming the flow path assembly 14b of the upward hood 1b are also formed to have a wavy length, so that the lower opening 142b side is uneven. Since the lower opening 142a and the lower opening 142b are out of phase with each other so that the irregularities are opposite to each other, a flow path meandering in the height direction is formed between the opposing hoods 1a and 1b. As a result, the water meanders up and down to promote the bypass, and the suspended matter can be efficiently fed into the flow path assemblies 14a and 14b.

  In FIG. 20 (a), four hoods 1a, b, c, d are vertically stacked, but they are connected to each other by a drain pipe 27. Specifically, the drainage pipe 27a that connects the hood 1a and the hood 1b is provided along the narrow pipe at approximately the center of the thin pipes that configure the flow passage aggregate 14a and the flow passage aggregate 14b. It is fixed to the flow passage assembly 14a and the flow passage assembly 14b, respectively. The drain pipe 27a is formed such that the upper end and the lower end thereof are aligned with the flow path aggregate 14a and the upper openings 141a and 141b of the flow passage aggregate 14b. Further, the hood 1c and the hood 1d below the hood 1c are similarly connected by a drain pipe 27c. Further, the hood 1b and the hood 1c are connected to each other by a drain pipe 27b connected to the discharge hole 111.

  Further, in the flow path assembly 14a of the hood 1a of FIG. 20 (a), the lower opening 142a is formed so that the length of the thin tube becomes gradually shorter from the side wall 12a side toward the drain pipe 27a side at the center of the hood 1a. It is formed obliquely, so that the lower opening 142a side is entirely concave. On the other hand, in the flow path assembly 14b of the hood 1b, the lower opening 142b is formed obliquely so that the length of the thin tube becomes gradually longer from the side wall 12b side toward the center side of the hood 1b. The opening 142b side is entirely convex. By doing so, the flow path of water between the opposing hoods 1a and 1b has an inverted V shape in which the side wall 12 side is low and the central portion of the hoods 1a, b is high, so that the water meanders vertically and detours. The flow is promoted, and the suspended matter can be efficiently fed into the flow path assembly 14. The flow channel assemblies 14c and 14d of the hood 1c and the hood 1d have the same configuration.

  The flow of water and suspended matter in the hoods 1a to d and the drain pipes 27a to 27c in FIG. 20 (a) can be adjusted by a drain valve (not shown) provided in the drain pipe 2. That is, when only the drain valve of the drain pipe 2 connected to the hood 1a is opened, the water flows upward. Further, if only the drain valve of the drain pipe 2 connected to the hood 1d is opened, water flows downward. When both the upper and lower drainage valves are opened, both flow up and down, but more drainage flows. In addition to the amount of drainage, there are some that flow upward or downward against the flow due to the magnitude of the specific gravity. That is, those having a small specific gravity are taken into the upper hoods 1a and c, and those having a large specific gravity that sinks against the upward flow are taken into the lower hoods 1b and d.

  20 (b) is one in which four hoods 1a, b, c, d are stacked, but the point that they are connected to each other by drainage pipes 27a, b, c is the aspect of FIG. 20 (a). Is the same as. However, in this embodiment, the thin tubes forming the flow path assemblies 14a to 14d are formed to have the same length, and all of them are formed to be flat in the upper openings 141a to d and the lower openings 142a to 142d. The difference is.

  Further, the hood 1b and the hood 1c of FIG. 20 (b) are provided with a pair of partitions 16b so as to connect the side walls 12b and 12c. The partitions 16b are preferably provided as a pair on the opposing surfaces of the side walls 12b and 12c, and although a pair is provided on the left and right sides in this drawing, they may be provided on the front and rear sides. As described above, by providing the partition 16b between the side wall 12b and the side wall 12c, the flow of water in this portion is prevented and concentrated in the flow path between the hood 1a and the hood 1b or between the hood 1c and the hood 1d. be able to. Further, the hood 1a and the hood 1d may be provided with side walls 12a and partitions 16a and 16d so as to extend from the side wall 12d to the drain pipe 2 side, if necessary. These partitions 16a and 16d can also obtain the same effect as the partition 16b.

  Instead of providing these partitions 16, as shown in FIG. 20D, the interior 101 having an inner wall surface 114 that hollows out the inside of a cylindrical or prismatic block-shaped member 17 and converges to the discharge hole 111. You may form the space provided with the flow path aggregate 14. In this aspect, the portions corresponding to the top wall 11 and the side wall 12 are integrally formed, and the two hoods 1 are joined at the upper surface portion of the block-shaped member 17 as shown in the figure, so that The outer side surface plays the same role as the partition 16, and the water flow between the hoods 1 can be effectively prevented.

  Further, in FIG. 20 (c), four hoods 1a, b, c, d are stacked, but the drain pipe 27a connecting the hood 1a and the hood 1b to each other is the same as the flow passage assembly 14a. The thin tubes forming the flow channel assembly 14b are provided at substantially the center along the thin tubes, and the upper part and a part of the center are fixed to the flow channel group 14a and the flow channel group 14b, respectively. The drain pipe 27a is formed such that the upper end thereof is aligned with the upper opening 141a, and a part of the lower side extends so as to project further downward from the pipe assembly 14b, and the vicinity of the lower end thereof serves as the hood 1b. It is inserted into the drainage pipe 27b that connects the hood 1c.

  Further, the drain pipe 27c connecting the hood 1c and the hood 1d in series is provided along the thin tubes forming the flow path assembly 14c and the flow path assembly 14d at approximately the center thereof, and a part of the center thereof. And the lower part are fixed to the flow path assembly 14c and the flow path assembly 14d, respectively. The drainage pipe 27c is formed such that its lower end is aligned with the upper opening 141d, and a part of the upper side extends so as to project further upward from the flow path assembly 14c, and its upper end side extends to the hood 1b and the hood. It is inserted into the drain pipe 27b which is connected to 1c.

  20A to 20C, four hoods 1a, b, c, d are all vertically stacked, but not limited to the vertical direction, and the entire hood is inclined depending on the angle of the pipe. You may arrange so that it may be made. The number of hoods 1 in FIGS. 19 and 20 is two or four, but the number is not limited to these numbers.

  In addition, when a plurality of hoods 1 are vertically stacked, as shown in FIG. 21A, drain pipes 2a, 2b, 2c that are directly connected to the hoods 1a, 1b, 1c may be provided individually. Good. That is, the drain pipe 2a is directly connected to the hood 1a, the drain pipe 2b is directly connected to the hood 1b, the drain pipe 2c is directly connected to the hood 1c, the drain pipe 2b penetrates the hood 1a, and the drain pipe 2c is connected to the hood. It is provided so as to penetrate through 1a and 1b. With this configuration, it is possible to individually adjust the drainage amount of each hood 1a, b, c. FIG. 21B is an example in which six hoods 1a to f are placed one above the other, and in this embodiment, the hood 1a has a drain pipe 2a, the hood 1b has a drain pipe 2b, and the hood 1c has drain water. A drain pipe 2d is directly connected to the pipe 2c and the hood 1d, a drain pipe 2e is connected to the hood 1e, and a drain pipe 2f is directly connected to the hood 1f. The bundle of drainage pipes 2 outside the hood 1 may be stored together in one thick pipe, as shown in FIG. At this time, the gap between the pipes 2a, 2b, 2c may be appropriately closed if necessary.

  Further, when a plurality of hoods 1 are arranged one above the other, a net portion 9 may be provided so as to close the gap between the two hoods 1 as shown in FIG. By providing the net portion 9 between the upper and lower hoods 1, it is possible to prevent large dust and the like from entering the hood 1 when water passes between the hoods 1.

  FIG. 22 schematically shows the internal structure of a further different embodiment of the hood 1 according to the present invention. The hood 1 of the present embodiment is characterized in that the water collecting portion 29 is provided in the internal space portion 101. The water collecting portion 229 is formed in a cylindrical shape with its upper and lower ends open, and a plurality of openings 291 are provided on its wall surface. The water collecting portion 29 is connected to the inner pipe portion 292 at the upper end thereof. The inner pipe portion 292 is provided in the drain pipe 2 so as to extend to the front of a drain valve (not shown). As shown in FIG. 22B, the inner pipe portion 292 is fixed to the inner peripheral wall of the drain pipe 2 by four plate-shaped connecting portions 293 protruding from the outer peripheral surface thereof.

  With such a configuration, among the suspended matter taken into the space 101 of the hood 1, the suspended matter of a size that can pass through the opening 291 of the water collecting section 29 is further sucked into the water collecting section 29 and the inner pipe It is effectively discharged to the outside through the portion 292. Further, a suspended matter having a size that cannot pass through the opening 291 is also discharged to the outside through the gap between the drainage pipe 2 and the inner pipe 292.

  Further, as shown in FIG. 22C, a partition plate 119 that vertically partitions the space 101 inside the water collection tank 1 may be provided. In this case, as shown in FIG. 22C, the partition plate 119 is provided. The water collecting portion 29 may be formed in a cylindrical shape that is branched into a plurality of pieces above and extends in each of the partitioned spaces.

  Further, as shown in FIG. 22D, when the partition plate 119 is not provided, a substantially box-shaped water collecting part 29 matching the shape of the hood 1 may be provided in a nested manner. As shown in the figure, the water collecting section 29 has an opening 291 formed in a slit shape on the front wall surface thereof. Further, the bottom portion 294 is formed to be open.

  23 to 34 show further different embodiments of the apparatus for removing sediments / suspended matter from water and water according to the present invention. The underwater and surface floating material removal apparatus of the present embodiment is installed in the water of a sedimentation basin, and has a pair of ceiling walls that are continuously provided at the upper side so as to extend toward the lower side while being separated from each other. A hood having side walls formed to a predetermined height from the continuous portion and left and right side portions of the ceiling wall, and extending along the continuous portion, an opening is formed in a peripheral wall thereof. At the same time, a drain pipe is provided whose both ends penetrate the side wall and project outside the hood. The structure will be described below in detail.

  As shown in FIGS. 23 and 24, in the hood 1 of the present embodiment, a pair of flat walls 11 formed in a flat plate shape are connected to each other at their upper side portions 115, and from the upper side portion 115 to the lower side portion 116. It is formed so as to be spaced apart from each other. Although the top wall 11 is formed in a rectangular shape in the present embodiment, it may be formed in a different shape such as a square or a trapezoid. Further, at least a part of the top wall 11 may be inclined so as to face downward, and for example, as shown in FIG. 4B, one of the pair of top walls 11 is inclined. However, the other top wall 11 may be a vertical surface that is not inclined. Further, as shown in FIG. 4 (c), a part of the top wall 11 also includes a part that is inclined backward so that the inner wall surface 114 faces upward instead of downward.

  A pair of side walls 15 is provided on the left and right side portions 117 of the ceiling wall 11 so as to close both sides of the space 101 inside the ceiling wall 11 from a continuous portion of the upper side portion 115 to a predetermined height. The side wall 15 can be provided up to an arbitrary height from the continuous portion of the upper side portion 115 of the ceiling wall 11, and is formed at the minimum necessary height in FIG. 23. Thus, the lower wall portion 116 of the ceiling wall 11, that is, both sides of the space 101 of the ceiling wall 11 may be provided so as to be completely closed. Further, the shape of the side wall 15 is not limited to the triangle as shown in FIG. 23 (b) or FIG. 25 (a), and an inverted V-shape in which the central portion of the bottom side 151 is cut up as shown in FIG. The shape may be.

  The drain pipe 2 is provided in the space 101 in the ceiling wall 11. The drainage pipe 2 extends laterally along the continuous portion of the upper side portion 115 of the top wall 11, and both end sides thereof are provided so as to project from the side wall 15 to the outside of the hood 1.

  The drainage pipe 2 has a plurality of slit-shaped openings 201 formed in a peripheral wall portion of a portion extending in the space 101 of the ceiling wall 11, and water and suspended matter are taken into the drainage pipe 2 through the openings 201. You can In addition, in the present embodiment, the opening 201 is formed in a slit shape extending in the circumferential direction of the drainage pipe 2, but it may be a slit shape extending in the axial direction, or a circular shape other than the slit, or the like. Other shapes may be used. Further, a removable cap portion 202 for closing the opening may be provided at the opening at the tip of the drainage pipe 2 if necessary.

  The drainage pipe 2 is provided with a drainage port 23 at the end opposite to the end where the cap 202 is attached, and a drainage valve 22 is provided in front of the drainage port 23. Further, if necessary, an air vent pipe 24 that branches from the middle of the drain pipe 2 and rises in the vertical direction may be provided. In the present embodiment, the air vent tube 24 projects outside the hood 1 through an opening 118 provided at the top of the hood 1. An exhaust port 26 is provided at the end of the air vent pipe 24, and an air vent valve 25 is provided in front of it. By providing the air vent pipe 24 in this way, the air that has entered the drain pipe 2 from the hood 1 can be effectively vented, and water can be smoothly drained from the drain pipe 2. Further, a part of the drainage pipe 2 may have a bellows structure, and the bellows structure can be easily adjusted when the water level in the sedimentation basin 3 changes.

  In addition, in this embodiment, the cap 202 is attached only to one end side of the drainage pipe 2, but it may be attached to both ends of the drainage pipe 2, and in that case, instead of the air vent pipe 24, the drainage pipe 2 is attached. A drainage pipe that branches off from the middle of and rises in the vertical direction may be separately provided. Furthermore, without attaching the caps 202 to both ends of the drainage pipe 2, the exhaust port 23 may be provided at one end and the air vent pipe 24 reaching the exhaust port 26 may be provided at the other end. Good. If it is not necessary to provide the air vent pipe 24 or the drain pipe that branches from the middle of the drain pipe 2 and rises in the vertical direction, the top of the hood 1 does not have the opening 118 as shown in FIG. The shape may be completely closed.

  Although the hood 1 of the present embodiment is formed in a substantially triangular shape in a side view, the shape is not limited to a triangular shape, and as shown in FIG. It may be formed so as to have a shape or an R-plane shape having no corner as shown in FIG. In this way, the top wall 11 of the hood 1 is inclined from the continuous portion to the lower side portion so as to be separated from each other, and the inner wall surface 114 thereof is formed so as to spread out from the top to the bottom, so that it exists in the space 101. The suspended matter having a small specific gravity is collected in the drainage pipe 2 provided near the upper connection portion, and can be efficiently taken into the drainage pipe 2 through the opening 201. Furthermore, the upper surface of the ceiling wall 11 plays the role of an inclined plate, which can promote the sedimentation of floating substances such as flocs. The inclination angle of the ceiling wall 11 is not limited, and the effect can be obtained even if the inclination is 1 degree with respect to the horizontal.

  The space 101 in the hood 1 may be a complete cavity as shown in FIG. 23, but may be provided with a flow path assembly 14 as shown in FIG. 27, if necessary. The flow passage assembly 14 divides the space in the hood 1 in the horizontal direction, and the upper opening 141 thereof is vertically oriented so that the lower opening 142 thereof faces the open side of the hood. Stretch.

  As shown in FIG. 27A, the flow path assembly 14e is formed by bundling a plurality of thin tubes. The individual thin tubes constituting the flow passage assembly 14e are formed so that the diameter thereof becomes smaller from the lower end portion to the upper end portion, and in the central portion of the hood 1, the thin pipes are provided in the substantially vertical direction and on the ceiling wall 11. As they approach, they are bundled at appropriate angles so as to follow the inclination of the ceiling wall 11. As a result, the entire shape of the bundled thin tubes becomes similar to the shape of the space 101 formed by the top wall 11 of the hood 1. Although the upper opening 141 of the flow path assembly 14e is located below the drainage pipe 2 and the lower opening 142 is located at the lower end of the hood 1, these positions are not limited thereto. . The flow passage assembly 14e is attached to the hood 1 by fixing the outer peripheral wall of the thin tube located inside the ceiling wall 11 of the hood 1.

  In the flow channel assembly 14f of the embodiment shown in FIG. 27 (b), the thin tubes are formed to have the same diameter from the upper end portion to the lower end portion and are bundled so as to extend in the vertical direction. The length of each thin tube is formed so as to follow the inclination of the ceiling wall 11. As a result, the entire shape of the bundled thin tubes becomes similar to the shape of the space 101 formed by the top wall 11 of the hood 1. Further, the flow path assembly 14f is provided lower than the ceiling wall 11 so as to form a gap 102 between the channel aggregate 14f and the ceiling wall 11 of the hood 1. The flow passage assembly 14f can be attached by fixing the peripheral walls of the thin tubes located on the left and right ends on the inside of the side wall 15 of the hood 1.

  Each of the flow passage assemblies 14e and 14f takes in water and suspended matter from the lower opening 142 of the capillary and discharges it from the upper opening 141 to the drain pipe 2 side. What is discharged into the gap 102 with the ceiling wall 11 moves as it is to the lower side of the drain pipe 2 along the ceiling wall 11 and is finally taken into the drain pipe 2. By providing the flow passage assembly 14 inside, the horizontal cross section of the hood 1 is subdivided by a plurality of thin tubes, and the individual opening areas are reduced, so that the suction effect by the hood 1 can be maximized. . Further, the flow of water in the hood 1 is arranged so as to be directed upward, and unnecessary convection such as a lateral flow does not occur, so that suspended matter can be effectively sucked up.

  The flow channel assemblies 14e and 14f of the present embodiment are formed by bundling a plurality of cylindrical thin tubes, but the cross-sectional shape of each thin tube is not limited to a cylinder, and is shown in FIG. Such a thin tube having a square or rectangular cross section, a so-called honeycomb structure in which regular hexagonal thin tubes are bundled, or other cross section may be used. The capillaries constituting the flow passage assemblies 14e and 14f can be formed to have an arbitrary thickness, but in order to maximize the above effects, the capillaries should be formed in a range of 0.1 mm to 50 mm. Is preferred. The inner diameters of the individual capillaries do not have to be the same, and may differ depending on the location. Further, a gap may not be provided between the adjacent thin tubes, and when the gap is provided, the gap is not particularly limited. Further, as long as the horizontal cross section can be subdivided in the space 101 of the hood 1, the flow channel assembly 14 is not limited to a group of thin tubes, and may be a plurality of flow channels partitioned by partition plates or a block-shaped member. It also includes a plurality of vertical holes that are to be channels.

  The flow channel assembly 14 described above can be provided in the hood 1 of any mode, but when the drainage pipe 27 for connection is provided in the hood 1 as shown in FIG. The flow channel assembly 14 can be provided in the other portion while avoiding the drain pipe 27 portion.

  FIG. 28 schematically shows an installation example of the apparatus for removing sediments / floats of water and the surface of water according to the present invention. As shown in FIG. 28 (a), the drain pipe 2 is provided such that the side where the cap portion 202 is not attached extends so that the discharge port 23 is exposed to the outside of the settling basin 3. In particular, the discharge port 23 is It is arranged at a position lower than the water surface W in the settling basin 3. The drainage pipe 2 is arranged so that not only the drainage port 23 but also the entire drainage pipe 2 including the drainage valve 22 is located at a position lower than the water surface W.

  In this way, by making the outlet 23 lower than the water surface W, the water in the sedimentation basin 3 is sucked into the drain pipe 2 from the space 101 in the hood 1 by the atmospheric pressure applied to the water surface W, and the drain pipe 2 Finally, the water is drained from the discharge port 23 through. The amount of water taken in from the hood 1 can be appropriately adjusted by the drain valve 22.

  FIG. 28 (b) schematically shows a suspended matter removing device that drains water from the hood 1 to the drainage trough 4 provided in the sedimentation basin 3. The drainage trough 4 is formed in a trough shape capable of storing a predetermined amount of water therein, but the drainage trough 4 does not flow directly into the settling tank 3 beyond the upper part of the peripheral wall thereof, so that the water flows into the settling tank 3 inside. is set up. As shown in the figure, the drain pipe 2 is provided with a cap portion 202 at both ends thereof, and a drain pipe 27 that branches up from the middle thereof and rises up. The drain pipe 27 penetrates the bottom surface of the drain trough 4 as it is, and the drain port 23 provided at the end thereof is provided so as to be exposed in the drain trough 4. As described above, in the drainage pipe 2 of the present embodiment, water is drained directly above by the drainage pipe 27 formed of a straight pipe, so that the air in the drainage pipe 2 can be easily released without providing a separate air vent pipe 24. Can be done smoothly.

  The water in the drainage trough 4 is drained to the outside of the sedimentation basin 3 by a drain pipe or the like (not shown), and the water surface W2 in the drainage trough 4 is always kept lower than the water surface W1 in the sedimentation basin 3. . Since the atmospheric pressures on the water surface W1 and the water surface W2 are equal, the water in the settling basin 3 having a high water level is sucked into the drain pipe 2 of the hood 1 to try to balance the water surface W1 and the water surface W2, and the drain pipe 27 Water is collected into the drainage trough 4 through the pipe, and then drained to the outside of the settling basin 3 by a drain pipe or the like leading to the outside.

  In the embodiment of FIGS. 28 (a) and 28 (b) described above, water is sucked from the hood 1 by utilizing the difference in water level, but the water absorbing means is not limited to this and is shown in FIG. 28 (c). As described above, a water absorbing means by the pump 5 may be provided in the middle of the drain pipe 28. In the present embodiment, the drain pipe 2 is provided with the cap portions 202 at both ends thereof, and the drain pipe 27 which is branched and rises from the middle thereof is provided. Further, in the middle of the drainage pipe 27, an air vent pipe 24 extending vertically as it is and a drainage pipe 28 extending horizontally are branched. When the pump 5 is used as in this embodiment, the discharge port 23 and the drain pipe 28 may be higher than the water surface W of the settling basin 3. As the pump 5, a general pump such as a vacuum pump or a water absorption pump can be used. Further, the water absorbing means is not limited to this, and the water absorbing means by the pump 5 and the water absorbing means utilizing the water level difference may be combined.

  The underwater and water surface sediment / floating matter removing apparatus of the present embodiment may include a plurality of hoods 1, and as an example thereof, a plurality of hoods 1 may be vertically stacked. In the embodiment of FIG. 29 (a), the drain pipe 2a of the upper hood 1a and the drain pipe 2b of the hood 1b arranged below the drain pipe 2a are both closed by the cap portions 202a and 202b. And are mutually connected by the drain pipe 27b. The drain pipe 27b rises vertically from the lower drain pipe 2b and is connected to the upper drain pipe 2a, whereby the drain pipe 2a and the drain pipe 2b can communicate with each other. Further, the drain pipe 2a of the upper hood 1a is provided with a drain pipe 27a that branches and rises from the middle thereof, and an air vent pipe 24 that extends vertically in the middle of the drain pipe 27a and a drain pipe 28 that extends horizontally. Branches.

  With this configuration, the water and suspended matter taken into the lower hood 1b are taken from the opening 201 of the drain pipe 2b and flow into the drain pipe 27b connected to the upper portion as they are. Further, the water and the suspended matter taken into the upper hood 1a are taken in through the opening 201 of the drainage pipe 2a, merged with the water and the suspended matter taken in from the drainage pipe 2b and passing through the drainage pipe 27b. Then, both move to the drain pipe 27a. Then, it is finally discharged from the discharge port 23 via the drain pipe 28. In addition, although the two hoods 1a and 1b are vertically stacked in the present embodiment, the number of the hoods 1 is not limited to this, and may be appropriately increased or decreased as necessary. Further, the opening 201 of the drainage pipe 2a and the opening 201 of the drainage pipe 2b are not limited in terms of their opening diameters, and may have different opening diameters.

  In FIG. 29 (b), two hoods 1a, 1b are vertically stacked as in FIG. 29 (a), but the arrangement of drain pipes and air vent pipes is different. In this embodiment, the upper hood 1a and the lower hood 1b are not connected to each other by a drain pipe, but are independent systems. That is, while the upper hood 1a has the same configuration as that of FIG. 28 (a), the lower hood 1b is an air vent pipe that stands upright in the vertical direction on the end side opposite to the outlet 23 of the drainage pipe 2. 24 is connected, the exhaust port 26b and the air vent valve 25b are provided in the end part. Although the outlet 23a and the drain valve 22a of the hood 1a are provided independently of the outlet 23b and the drain valve 22b of the hood 1b, by connecting the drain pipe 2a and the drain pipe 2b to one. The discharge ports 23a and 23b and the drain valves 22a and 22b may be integrated.

  Further, FIG. 30 shows an embodiment in which three hoods 1a, b, c are vertically stacked. In this embodiment, the drain pipe 2a of the uppermost hood 1a, the drain pipe 2b of the hood 1b arranged in the middle, and the drain pipe 2c of the lowermost hood 1c are cap portions at both ends thereof. It is of a type closed by 202, and is connected to each other by drainage pipes 27b and 27c so that they can communicate with each other. Further, the drain pipe 2a of the upper hood 1a is provided with a drain pipe 27a that branches and rises from the middle thereof, and an air vent pipe 24 that extends vertically in the middle of the drain pipe 27a and a drain pipe 28 that extends horizontally. Branches.

  In addition, when a plurality of hoods 1 are vertically stacked, as shown in FIG. 30, when the central portion of the side wall 15 is formed in an inverted V-shape, the upper portion of the hood 1 arranged below is placed above. Since it can be inserted into the cut-out portion of the side wall 15 of the hood 1, the space between the upper and lower hoods 1 can be arranged more narrowly.

  Regarding the installation method of the apparatus for removing sediments / floats of water according to the present invention, usually, the hood 1 is installed so that the space 101 faces downward, but this is turned upside down so that the space 101 faces upward. 31A, and as shown in FIG. 31A, the downward hood 1a and the upward hood 1b may be provided so as to face each other with a predetermined gap. By installing in this way, as shown by the arrow in the figure, among the suspended matter passing between the upper and lower hoods 1, those having a lower specific gravity are placed in the hood 1a installed above, and Heavy items are effectively taken into the hoods 1b installed below. In the mode of FIG. 31, the upward hood 1b is installed so as to face the downward hood 1a, but the effect of the present invention can be obtained even if the upward hood 1b is installed alone.

  Further, when the downward facing hood 1a and the upward facing hood 1b are provided so as to face each other with a predetermined gap, as shown in FIG. 31 (b), between the downward facing hood 1a and the upward facing hood 1b. May be provided with a barrier 8 and an air diffuser 6. Although the barrier 8 of the present embodiment has a plate shape extending in the vertical direction, the shape of the barrier 8 is not limited to this, and a substantially V-shaped one as shown in FIG. . As described above, by arranging the barrier 8 and the air diffusing tube 6 in combination, the suspended matter can be more easily separated, which is effective. The number, size, and shape of the air diffuser 6 and the barrier 8 are not particularly limited, and the combination method thereof is not limited. As an example, by changing the height (position) at which the barrier 8 is provided on the upstream side and the downstream side, the water flow can be detoured vertically.

  Further, regarding the installation method of the apparatus for removing sediment / floating matter in water and on the surface according to the present invention, the case where the ceiling wall 11 of the hood 1 is parallel to the flow of water as shown in FIG. There are two methods for facing each other as shown in 32 (b). In the figure, arrows indicate the flow of water. As shown in FIG. 32 (a), when the ceiling wall 11 is parallel to the flow of water, water enters the space 101 from the lower part of the side wall 15 on the upstream side of the hood 1 and enters the space 101 from the lower part of the side wall 15 on the downstream side. Go out. Further, as shown in FIG. 32 (b), when the ceiling wall 11 faces the flow of water, the water goes around the lower side portion 116 on the upstream side of the ceiling wall 11 and enters the space 101, and the lower side of the downstream side. It goes around the part 116 and goes out of the hood 1.

  Further, regarding the installation method of the apparatus for removing sediment / floating matter in water and on the surface according to the present invention, as shown in FIG. 32 (b), an air diffuser 6 may be appropriately provided below the hood 1. By providing the air diffuser 6 below the hood 1 to blow air, suspended matter as well as air bubbles rise and can be efficiently fed into the hood 1. Furthermore, by increasing the amount of air diffused by the air diffuser on the downstream side of the water flow, air bubbles play a role of a kind of air curtain, and it becomes difficult for suspended solids to reach the downstream side of the hood 1, and the hood 1 is more efficient. It becomes possible to take in. From the air diffuser 6, in addition to air bubbles (nano bubbles, micro bubbles, ordinary bubbles), water or viscous foam (foam like beer, foam like shampoo, etc.) or a mixture thereof. May be generated. The installation of the air diffuser 6 is not limited to below the hood 1, and may be provided inside the hood 1. Note that the nanobubbles and microbubbles have weak buoyancy and may be washed away with water before being taken into the hood. Therefore, a plurality of air diffusers may be provided and nanobubbles, microbubbles, ordinary bubbles, liquids (water, etc.) may be used together or in combination.

  33 and 34 show an example of an installation method of the apparatus for removing sediment / floating matter in water and on the surface of the water according to the present invention, in which a plurality of hoods 1 are vertically stacked. In the embodiment shown in FIG. 33, two sets of three hoods 1a, 1b, 1c are placed side by side in the front-back direction with respect to the flow of water. These two sets of water and surface sediment / floating matter removing devices are connected by a drain pipe 28, and water and floating matter taken from any of the hoods 1 are finally discharged from the same outlet 23. . 33, the hoods 1 adjacent to each other may be arranged without a gap. For example, as shown in FIG. 16B, the uppermost hood 1a may be provided without a gap, but the hood 1 without a gap is not limited to the uppermost one.

  In addition, in the embodiment shown in FIG. 34, two sets of three hoods 1a, 1b, 1c are provided side by side in the front-back direction with respect to the flow of water, but these two sets of hoods 1a, 1b, Barriers 7 are provided before and after 1c, respectively. The barrier 7 has a gap with the bottom surface of the sedimentation basin 3 on the upstream side of the hoods 1a, 1b, 1c, and has a gap with the water surface W on the downstream side of the hoods 1a, 1b, 1c. Is formed. In this way, by arranging the barrier 7 with a gap between the bottom surface or the water surface W before and after the two sets of hoods 1a, 1b, 1c, the flow of water is made to flow downwards of the hoods 1a, 1b, 1c. Can be regulated upwards from above, and the suspended matter can be effectively taken into and removed from the hood 1.

  Furthermore, when a plurality of hoods 1 are provided, they may be installed in a grid pattern that is continuous in the vertical direction, the horizontal direction, and the diagonal direction in a plan view. In these cases, a gap may be provided or may not be provided between the adjacent hoods 1.

  The hood 1 according to the present invention described above can be formed of a material having a certain strength and rigidity including a resin such as hard vinyl chloride or acrylic, metal, glass, pottery, carbon fiber, etc., and if necessary. It is preferable that the structure is reinforced by a skeleton or the like so that the structure can withstand water pressure.

1, 1a, 1b, 1c, 1d ... Hood 2, 2a, 2b, 2c, 2 '... Drainage pipe 3 ... Sedimentation basin 4 ... Drainage trough 5 ... Pump 6 ... Diffuser pipe 7 ... Barrier 8 ... Barrier 9 ... ... Net 11 ... ... Top wall 12, 12a, 12b, 12c, 12d ... Side wall 13 ... Blade part 14, 14a, 14b, 14c, 14d, 14e, 14f
... Channel assembly 15, 15a, 15b, 15c ... Side wall 16, 16a, 16b, 16c, 16d ... Partition 17 ... Block member 18 ... Top surface 19 ... Vertical surface 21, 21 '... Drain pipes 22, 22a, 22b ... Drain valves 23, 23a, 23b ... Exhaust ports 24, 24a, 24b, 24 '... Air vent pipes 25, 25a, 25b ... Air vent valves 26, 26a, 26b ... Exhaust ports 27, 27a, 27b, 27c ... Drain pipe 28 ... Drain pipe 29 ... Water collecting part 101 ... Space 102 ... Gap 103 ... Gap 104 ... Opening 111, 111 '... Drain hole 112 ... Intake port 113 ... peripheral edge 114 ... inner wall surface 115 ... upper side part 116 ... lower side part 117 ... left and right side part 118 ... ... opening part 119 ... Partition plates 141, 141a, 141b, 141c, 141d ... ... Upper openings 142, 142a, 142b, 142c, 142d ... Lower openings 143 ... Fixing members 144 ... Partition plates 145 ... Block-shaped members 146 ... Vertical holes 147 ... Partition plate 148 ... Fins 149 ... Fins 151 ... Bottom 201 ... Openings 202, 202a, 202b, 202c ... Caps 271a, 271b ... Openings 291 ... Opening 292 ... Inner pipe part 293 ... Connection part 294 ... Bottom part
W, W1, W2 ……… Water surface

Claims (17)

  A hood that is installed in the water of the sedimentation basin, has a space that accommodates water inside and is open downward, and at least a part of its inner wall faces downward and is inclined An apparatus for removing sediment / floats of water and water, comprising a drain pipe for draining water taken into the hood at or near the top of the hood.   The hood is provided with a discharge hole at the top thereof, a taking-in port opened downward at the lower part thereof, and a ceiling wall extending from the peripheral edge of the taking-in port while converging to the discharging hole. The drainage pipe connected to the discharge hole so as to communicate with the space of claim 1, wherein the apparatus for removing sediment / float matter in water and on the water surface according to claim 1.   The apparatus for removing sediments / floats of water and water according to claim 1 or 2, wherein a side wall is continuously provided below a lower end of the ceiling wall.   The water / water surface sediment / float removal apparatus according to claim 3, wherein blades extending from the lower end of the side wall to the outside of the hood are continuously provided.   The hood has a pair of ceiling walls that are continuously provided on the upper side so as to extend toward the lower side while being separated from each other. A drain pipe that has a side wall formed to a height, extends along the connecting portion, has an opening formed in its peripheral wall, and has both end portions penetrating the side wall and protruding to the outside of the hood. The apparatus for removing sediment / floating matter in water and on the surface according to claim 1.   The apparatus for removing sediment / float matter in water and water according to claim 5, wherein one or both ends of the drainage pipe are provided with a cap portion for closing the opening.   7. The underwater and water surface according to claim 1, wherein a plurality of the hoods are provided one above the other, and the upper hood is connected to the hood disposed below the hood by a drainage pipe. Sediment / float removal device.   The drainage pipe connecting the upper and lower hoods is formed with an opening, and the apparatus for removing sediment / float matter in water and on the water surface according to claim 7.   A submerged space in the hood is provided in the hood, and a flow path assembly extending in the vertical direction is provided in the hood, and the submerged water and the surface of the water settle down according to any one of claims 1 to 7. Object / float removal device.   10. The flow path assembly is a plurality of flow paths divided by partition plates, and fins projecting laterally are provided on the partition plates and side walls of the hood. Device for removing sediment and suspended matter in and from the water.   An aeration pipe is provided below or inside the hood, and the apparatus for removing sediment / float matter in water and on the water surface according to any one of claims 1 to 10.   12. The hood downward and the hood upward are provided so as to be opposed to each other with a predetermined space therebetween, to remove sediments / floats from the water and the water surface according to any one of claims 1 to 11. apparatus.   13. The downward hood and the upward hood are provided with a flow passage assembly, and the water flow passage between the facing hood and the hood is formed to meander in the height direction. The apparatus for removing sediments / floats in water and on the surface according to 1.   The downward hood and the upward hood include a flow passage assembly, and the upper and lower portions of the downward hood and the upward hood are connected to each other by a drain pipe that is fixed. 13. The apparatus for removing sediment / float matter in water and on the water surface according to claim 12.   The space inside the hood is provided with a water collecting portion having a plurality of openings, and the water collecting portion is connected at its upper end portion to an inner pipe portion provided so as to extend in the drain pipe. The apparatus for removing sediments / floats of water and water according to any one of claims 1 to 4, which is characterized.   16. The apparatus for removing sediments / floats of water and water according to any one of claims 1 to 15, wherein a plurality of the hoods are continuously installed in the front-rear direction with respect to the flow of water.   The sediments / floats are removed from the water and the water surface according to any one of claims 1 to 16, wherein a plurality of the hoods are installed in a grid shape that is continuous in a longitudinal direction, a lateral direction, and an oblique direction in a plan view. apparatus.

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