JP6514837B1 - Water and sediment surface sediment removal equipment - Google Patents

Abstract

A hood which is disposed in the water of a sedimentation tank and which is open at the bottom and has a space for containing water inside, and at least a part of the inner wall is formed to be inclined and facing the bottom side The floating material removal apparatus for the water and the surface of the water provided with a drain pipe for draining water taken into the hood near the top or the top of the hood effectively removes suspended matter that can not be completely settled in the sedimentation basin. Provide a sediment / float removal device that can be removed.

Description

  The present invention relates to an apparatus for effectively removing water and sediments and floats on water surfaces in a water purification treatment facility.

  In the conventional water purification process, in many sedimentation basins, suspended matter and the like are sedimented, and a structure is adopted in which supernatant water is carried to a filtration basin by a water collection trough (Patent Documents 1 and 2).

  However, suspended solids that do not settle exist due to various factors such as aggregation failure and flow velocity. When those floats are transported to the filter pond by the catchment trough, a load is generated on the filter pond.

  In addition, although there are devices such as inclined plates that promote sedimentation of suspended matter (Patent Documents 3 and 4), suspended matter with small specific gravity is difficult to precipitate, and it is difficult to completely precipitate suspended matter by these devices Met.

  Furthermore, conventionally, it has been necessary to periodically throw in an underwater robot or the like in a large storage tank or elevated water tank, etc. to remove the sediment on the bottom.

JP 2009-61407 Japanese Patent Application Publication No. 2007-69181 Japanese Patent Application Publication No. 11-347316 Patent document 1: JP-A-2005-13892

  Therefore, the present invention overcomes such drawbacks of the conventional water purification equipment, and provides a water and water surface sediment / floating material removal apparatus capable of effectively removing suspended matter that has not completely settled in the sedimentation basin. As its task.

  The present invention solves the above-mentioned problems, and it is installed in the water of a sedimentation tank, the lower part is opened and there is a space for containing water inside, and at least a part of the inner wall surface is the lower side. Water and water surface sediment / floating material removal apparatus provided with a hood formed to be inclined to face, provided with a drainage pipe for draining water taken into the hood near the top or the top of the hood It is.

  Further, according to the present invention, the hood has a discharge hole at its top and an intake port which opens downward at the lower portion, and has a top wall extending while converging from the peripheral edge of the intake port to the discharge hole. It is a sediment / floating material removing device for water and water including a drain pipe connected upward from the discharge hole so as to communicate with a space in the hood.

  Further, according to the present invention, the hood has a pair of ceiling walls provided at the upper side so as to extend toward the lower side while being separated from each other, the left and right sides of the upper wall being arranged continuously The side wall is formed from a portion to a predetermined height, extends along the connection portion, an opening is formed in the peripheral wall, and both ends thereof pass through the side wall and protrude outside the hood It is a sediment and float removal device of water and water surface equipped with a pipe.

  The apparatus for removing sediment and float on water and water according to the present invention is a float having a small specific gravity by a hood having a top wall formed so that at least a part of the inner wall faces downward and inclines. The water gathers in the direction of the top of the ceiling wall, and can be efficiently induced into a drainage pipe provided near the top or near the top to effectively remove water and water floats that do not settle. Furthermore, the upper surface of the ceiling wall plays the role of an inclined plate, which can promote sedimentation of flocs and the like.

(A) A perspective view of the water and sediment / floating material removal apparatus according to the present invention. (B) The same sectional view. (A) Sectional drawing of what provided the flow-path aggregate | assembly in the inside of the water of the water which concerns on this invention, and a sediment / floating substance removal apparatus of water surface. (B) Sectional drawing of the different embodiment which provided the flow-path aggregate | assembly inside the food | hood. (C) Sectional drawing of the different embodiment which provided the flow-path aggregate | assembly inside the food | hood. (D) Sectional drawing of the different embodiment which provided the flow-path aggregate | assembly inside the food | hood. (A) A perspective view of the hood of another embodiment of the water and water surface sediment and float removal device according to the present invention. (B) Perspective view of a hood of a different embodiment. (A) Cross section of the hood of another embodiment of the water and water surface sediment and float removal apparatus according to the present invention. (B) Cross section of a hood of a different embodiment. (C) Cross section of a hood of a different embodiment. (D) Cross section of a hood of a different embodiment. (A) A horizontal sectional view of a channel assembly of the water and the sediment / floating material removal apparatus according to the present invention. (B) Horizontal sectional view of the flow channel assembly of different embodiments. (C) Horizontal sectional view of the flow channel assembly of different embodiments. (D) Horizontal sectional view of the flow channel assembly of different embodiments. (E) Horizontal sectional view of the flow channel assembly of different embodiments. (A) The perspective view of what provided the side wall in the hood of the sediment / float thing removal apparatus of the water which concerns on this invention, and a water surface. (B) The same sectional view. (C) Sectional drawing which provided the flow-path aggregate | assembly inside the same food | hood. (D) Sectional drawing which provided the flow-path aggregate | assembly of a different embodiment inside the same food | hood. (A) A-A 'cross section of the flow channel assembly of the water / water surface sediment / floating material removal device according to the present invention provided with fins, (b) B-B' cross section, (c) AA 'sectional drawing of a different embodiment which provided the fin in the flow-path aggregate | assembly of the sediment and floating material removal apparatus of the water which concerns on this invention, and a water surface, (d) said BB' sectional drawing. (A) Sectional drawing of the fin provided in the side wall of the sediment * float thing removal apparatus of the water which concerns on this invention, and a water surface. (B) The same top view. (A) The perspective view of what provided the wing | feather part in the food | hood of the sediment / float thing removal apparatus of the water which concerns on this invention, and a water surface. (B) The same sectional view. (C) Sectional drawing of the different embodiment of the same blade part. (A) Sectional drawing of the division | segmentation state of what comprises one hood by assembling the parts divided | segmented into plurality of the sediment / float thing removal apparatus of the water which concerns on this invention, and a water surface. (B) Sectional drawing of the assembly state of the hood. (A) The figure which represents typically about the installation example of the sediment and floating material removal apparatus of the water which concerns on this invention, and a water surface. (B) Diagrams schematically showing different installation examples of the water and the sediment / floating material removal device on the water surface. (C) A diagram schematically showing an example of installation of water and water surface sediment / floating material removal apparatus. Sectional drawing of what installed the several hood in piles up and down by the example of installation of the sediment / floating substance removal apparatus of the water which concerns on this invention, and a water surface. The installation example of the sediment / floating matter removal apparatus of water and the water surface concerning this invention, the figure which represents typically what provided the downward hood and the upward hood so that it might mutually be spaced apart by predetermined spacing. (A) In the installation example of the sediment / floating material removal apparatus for water and water surface according to the present invention, a diagram schematically showing a plurality of hoods 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 diffusion pipe inside. The installation example of the sediment and floating material removal apparatus of water and water surface concerning this invention, The figure which represented typically what provided the aeration tube below the food | hood. (A) The figure which represents typically what installed the some food | hood in piles up and down in the example of installation of the sediment and floating material removal apparatus of the water concerning this invention, and a water surface. (B) The figure which represents typically the thing of the different embodiment which provided several food | hoods piled up and down. (A) The figure which represents typically what installed the some food | hood in piles up and down in the example of installation of the sediment and floating material removal apparatus of the water concerning this invention, and a water surface. (B) Sectional drawing showing the aspect of the food | hood of FIG. 17 (a), and a drain pipe. The installation example of the sediment / floating substance removal apparatus of water and the water surface concerning this invention, the figure which represents typically what provided with several hoods piled up and down. (A) In the installation example of the sediment / floating material removal apparatus of water and water surface according to the present invention, a downward hood and an upward hood are schematically shown ones facing each other at a predetermined distance. Figure. (B) The figure which represents typically the thing of the different embodiment which provided the downward hood and the upward hood so as to mutually oppose. (C) Diagram schematically showing different embodiments in which the downward hood and the upward hood are provided to face each other. (D) The figure which represents typically the thing of the different embodiment which provided the downward hood and the upward hood so as to mutually oppose. (A) The figure which represents typically what provided several food | hoods piled up and down. (B) The figure which represents typically the thing of the different embodiment which provided several food | hoods piled up and down. (C) The figure which represents typically the thing of the different embodiment which provided several food | hoods piled up and down. (D) The figure which represents typically the thing of the different embodiment which provided several food | hoods piled up and down. (A) The figure which represents typically what provided several food | hoods piled up and down. (B) The figure which represents typically the thing of the different embodiment which provided several food | hoods piled up and down. (C) Cross section of drain. (A) Sectional drawing of what provided the water collection part inside the food | hood. (B) AA sectional drawing of the drain pipe. (C) Sectional drawing of the different embodiment of what provided the water collection part inside the food | hood. (D) Sectional drawing of different embodiment of what provided the water collection part inside the food | hood. (A) Front view of the hood of water and water surface sediment / float removal apparatus according to different embodiments of the present invention. (B) The same side view. (C) Same side central longitudinal longitudinal sectional view. (D) Same front central longitudinal sectional view. (A) A perspective view of the hood of the water and water surface sediment and float removal device according to the embodiment of FIG. (B) Perspective view of a hood of a different embodiment. (A) Side view of the hood of a different embodiment of the water and water surface sediment and float removal apparatus according to the present invention. (B) Side view of the hood of a different embodiment. (A) A partial cross-sectional view of the hood of another embodiment of the water and water surface sediment and float removal apparatus according to the present invention. (B) A partial cross-sectional view of a hood of a different embodiment. (A) Sectional drawing of what provided the flow-path aggregate | assembly inside with the food | hood of the sediment * float thing removal apparatus of the water which concerns on this invention, and a water surface. (B) Cross-sectional views of different embodiments in which a channel assembly is provided inside the water and the hood of the sediment / floating material removal device on the water surface. (A) The figure which represents typically about the installation example of the sediment and floating material removal apparatus of the water which concerns on this invention, and a water surface. (B) Diagrams schematically showing different installation examples of the water and the sediment / floating material removal device on the water surface. (C) A diagram schematically showing an example of installation of water and water surface sediment / floating material removal apparatus. (A) The figure which represents typically what installed the some food | hood in piles up and down by the example of installation of the sediment and floating substance removal apparatus of the water concerning this invention, and a water surface. (B) The figure which represents typically what installed the several hood in piles up and down by the example of installation which differs in the sediment and floating material removal apparatus of water and a water surface. The figure which represents typically what arrange | positioned several food | hoods piled up and down by the example of installation of the sediment / float thing removal apparatus of the water which concerns on this invention, and a water surface different. The installation example of the sediment / floating matter removal apparatus of water and the water surface concerning this invention, the figure which represents typically what provided the downward hood and the upward hood so that it might mutually be spaced apart by predetermined spacing. (B) The figure which represents typically what provided the downward hood and the upward hood so that it might mutually be spaced apart by predetermined spacing in the installation example which differs in the sediment and floating material removal apparatus of water and a water surface. (A) The figure which represents typically what was installed so that the ceiling wall of a hood might be parallel with respect to the flow of water by the installation example of the sediment and floating substance removal apparatus of water and water surface concerning this invention. (B) The figure which represents typically what was installed so that the ceiling wall of a food | hood might face the flow of water by the example of installation of the sediment * float thing removal apparatus of water and a water surface. The installation example of the sediment / floating substance removal apparatus of water and the water surface concerning this invention, the figure which represents typically what provided with several hoods piled up and down. The installation example of the sediment / floating substance removal apparatus of water and the water surface concerning this invention, the figure which represents typically what provided with several hoods piled up and down.

  Hereinafter, an embodiment of the sediment / floating material removal apparatus of water and water surface of the present invention will be specifically described based on the drawings. The present invention is not limited to these embodiments.

  The apparatus for removing sediments and floats of water and water according to the present invention is installed in the water of a sedimentation tank, has a space for containing water inside, is open at the bottom, and at least a part of the inner wall surface thereof Is provided with a hood having a ceiling wall formed to be inclined downward facing the lower side, and a drain pipe for draining water taken into the hood is provided at the top or the vicinity of the top. Hereinafter, the structure of the sediment / floating material removal apparatus for water and water according to the present invention will be described in detail.

  FIG. 1 (a) is a perspective view of a water / water surface sediment / floating material removing apparatus according to the present invention, and FIG. 1 (b) is a sectional view of the same. The hood 1 constituting the floating material removing apparatus for water and water according to the present invention has a space 101 for containing water therein, and the lower side is open, and the inner wall surface 114 faces the lower side from the top to the lower side. And the ceiling wall 11 formed to be inclined. A discharge hole 111 is formed at the top of the top wall 11, and an intake port 112 having an opening area larger than that of the discharge hole 111 is formed below the top wall 11. From the peripheral edge 113 of the intake port 112 to the discharge hole 111 Stretch while converging. Further, a drain pipe 2 is connected to the discharge hole 111 so as to extend upward. The drain pipe 2 is in communication with the space 101 in the hood 1 and drains water and suspended matter in the space 101 out of the settling basin through the drain pipe 2.

  In the hood 1 of the present embodiment, although the outer shape of the top wall 11 is formed in a substantially truncated cone shape, it is formed so that a part or all of the inner wall surface 114 of the top wall 11 faces downward and inclines. The outer shape is not limited to this, and it may be, for example, a truncated pyramid shape as shown in FIG. 3 (a) or a dome shape as shown in FIG. 3 (b). As described above, the inner wall surface 114 of the hood 1 is formed to be inclined downward and formed so as to converge from the peripheral edge 113 of the intake port 112 to the discharge hole 111 side, thereby being taken into the space 101 from the intake port 112 The float having a small specific gravity is drawn toward the discharge hole 111 at the upper center of the ceiling wall 11 and effectively guided into the drain pipe 2. Furthermore, by making the top wall 11 into a truncated cone shape, a truncated pyramid shape, or a dome shape, the upper surface of the top wall 11 plays the role of an inclined plate, and sedimentation of floating substances such as floc can be promoted. In addition, the inclination angle of the top wall 11 is not specifically limited, Even if it inclines 1 degree with respect to horizontal, it has the effect.

  Further, in the embodiment of FIGS. 1 to 3, the top wall 11 converges continuously from the peripheral edge 113 to the connecting portion with the drain pipe 2, but the shape of the top wall 11 is not limited thereto. As in (a), the periphery of the junction with the drain pipe 2 may be the top surface 18 extending in the horizontal direction, or may be formed to converge from the peripheral edge 113 to the edge of the top surface 18 . Furthermore, as another shape of the ceiling wall 11, as shown in FIG. 4B, a vertical surface 19 which is not inclined may be formed in a part of the ceiling wall 11. By providing the vertical surface 19, the hood 1 is not disturbed by the hood 1 from the side of the vertical surface 19 and the drainage pipe 2 can easily reach the drainage pipe 2 even in the case where the plurality of hoods 1 are vertically stacked. , Installation of the device in water and maintenance work become easy. Furthermore, as shown in FIG. 4C, a portion of the ceiling wall 11 includes one that is inclined in the opposite direction such that the inner wall surface 114 faces upward, not downward.

  The drainage pipe 2 connected to the drainage hole 111 and rising up in the longitudinal direction is branched midway along the drainage pipe 21 extending in the lateral direction and the air drainage pipe 24 standing up in the longitudinal direction as it is. A drain valve 22 is provided in front of the outlet 23 at the end of the drain pipe 21, and an air vent valve 25 is provided in front of the outlet 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 which is continuous in the lateral direction from the drain pipe 2 may be provided. By providing the air vent pipe 24 as in this embodiment, the air which 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. Furthermore, part of the drainage pipe 21 may be a bellows structure, and by setting the drainage pipe 21 to a bellows structure in this way, the position of the hood 1 can be easily adjusted when the water level of the sedimentation tank 3 changes.

  In addition, the number of the drain pipes 2 is not limited to one with respect to one food | hood 1, You may provide with two or more as needed. For example, as shown in FIG. 4 (d), in the case of a hood 1 of a type having a wide opening of the intake port 112, it is provided in the middle of the ceiling wall 11 besides the drainage pipe 2 connected to the discharge hole 111 at the top of the hood 1. A drainage pipe 2 'connected to the drainage hole 111' may be separately provided. Although two such drain pipes 2 'are additionally added in FIG. 4 (d), the number is not limited to this. In addition, an air vent pipe 24 'may be provided in the drain pipe 2' as required.

  The space 101 in the hood 1 may be a complete cavity as shown in FIG. 1 (b), but if necessary, the flow channel aggregates 14a, b as shown in FIG. 2 (a), (b) may be used. You may provide. The flow channel assembly 14 a, b divides the space 101 in the hood 1 in the horizontal direction, and its upper opening 141 faces the discharge hole 111 of the hood 1 and its lower opening 142 is the intake port of the hood 1 It is extended in the up-down direction in the hood 1 so as to face the side 112.

  The flow channel assembly 14a of FIG. 2A is formed as a bundle of a plurality of thin tubes. These individual thin tubes are formed such that the diameter decreases from the lower end to the upper end, in the substantially vertical direction in the central portion of the hood 1 and in the inclination of the top wall 11 as they approach the top wall 11. Each is bundled at an appropriate angle along the line. As a result, when the thin tubes are bundled, the overall shape becomes a substantially frustum 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 channel assembly 14 a is located below the discharge hole 111 of the hood 1, and the lower opening 142 is provided so as to be located at the intake port 112 of the hood 1. It is not limited to this. The flow channel assembly 14 a is attached to the hood 1 by fixing the peripheral wall of the narrow tube located on the outermost side to the inner wall surface 114 of the hood 1.

  Further, in the flow channel assembly 14 b of FIG. 2 (b), individual thin tubes are formed so as to have the same diameter from the upper end to the lower end, and are all bundled together so as to extend in the vertical direction. Along the inclination of the wall 11, the length of the capillary is formed longer at the center side and shorter toward the end. As a result, when the thin tubes are bundled, the overall shape becomes a substantially frustum shape similar to the shape of the space 101 formed by the top wall 11 of the hood 1. Furthermore, the flow channel assembly 14 b is provided slightly lower than the top wall 11 so as to form a gap 102 with the inner wall surface 114 of the hood 1. The flow channel assembly 14 b is attached by fixing the peripheral wall of the thin tube located on the outermost side and the inner wall surface 114 of the hood 1 by the fixing member 143.

  The flow channel assemblies 14a and 14b both take in water and suspended matter from the lower opening 142 of the capillary and discharge it from the upper opening 141 into the hood 1 as shown by the arrows in the figure, but the tube assembly In the case of 14 b, what is once discharged into the gap 102 moves along the top wall 11 toward the discharge hole 111 as it is and is finally discharged to the drain pipe 2. By providing such a channel assembly 14 inside, the horizontal cross section of the space 101 in the hood 1 is subdivided by a plurality of capillaries, and the individual opening areas are reduced, so the suction effect by the hood 1 is maximized It can be demonstrated. Furthermore, the flow of water in the hood 1 is arranged in an upward direction, and unnecessary convection such as lateral flow does not occur, and the floating 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 thin tube is not limited to a circle. A so-called honeycomb structure in which thin tubes having a square or rectangular cross-sectional shape or regular hexagonal thin tubes as shown in FIG. 5B are bundled may be used, or other cross-sectional shapes. The thin tubes constituting the flow path aggregates 14a and 14b can be formed to any thickness, but in order to maximize the above effects, the inner diameter may be formed in a range of 0.1 mm to 50 mm. preferable. The inner diameters of the individual capillaries may not be identical to each other, and may be different depending on places. Further, adjacent thin tubes may be provided without providing a gap, and in the case of providing a gap, the distance 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 capillary tubes, and as shown in FIGS. 5 (c) and 5 (d) It may be sectioned by Alternatively, as shown in FIG. 5E, the block-shaped member 145 may be provided with a plurality of longitudinal holes 146 serving as a flow passage.

  In the case where the flow channel assembly 14 is formed by bundling a plurality of cylindrical thin tubes, the narrowing of the diameter from the lower portion to the upper portion, or the formation of the same diameter from the upper portion to the lower portion Without limitation, as shown in FIG. 2 (c), the capillary may be formed to have a smaller diameter as it goes from the top to the bottom. As a result, the flow velocity on the side of the lower opening 142 with a smaller diameter is increased, and the suction effect can be improved. In addition, since the diameter of the upper opening 141 is large, an effect that floating material and the like are not easily clogged can be obtained. The channel aggregate 14c in FIG. 2C is fixed to the inner wall surface 114 of the hood 1 while the individual thin tubes are fixed to each other by a rod-like fixing member 143 which does not inhibit the flow of water. It is done.

  Furthermore, as shown in FIG. 2D, a plurality of vertical holes 146 are formed by penetrating the block-shaped member 145 as the flow channel assembly 14d, and each vertical hole 146 goes from the top to the bottom. It may be formed to become smaller in diameter as it goes. This also has the same effect as the embodiment of FIG. 2 (c).

  Further, as shown in FIG. 6, a side wall 12 may be provided on the lower part of the top wall 11 of the hood 1 as needed. The side wall 12 is continuously provided below the lower end of the top wall 11 and hangs down from the top wall 11 in the present embodiment, and its outer shape is formed in a quadrangular prism shape, as shown in FIG. When 1 is in the shape of a truncated cone, it may be in the shape of a column depending from the ceiling wall 11. Furthermore, the side wall 12 is not limited to one that hangs down in the vertical direction, and may be formed so as to be inclined and extended while spreading downward and outward. Thus, by providing the side wall 12 in the lower part of the ceiling wall 11, the volume of the internal space 101 can be increased, 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 at any inclination angle, but is preferably provided so as to be inclined or perpendicular in the range of 45 degrees to 90 degrees with respect to the horizontal.

  Also in the case where the side wall 12 is provided, the flow passage aggregate 14 may be provided in the hood 1 as required. As shown in FIGS. 6 (c) and 6 (d), the inside of the top wall 11 has the same structure as in FIGS. 2 (a) and 2 (b), and in the side wall 12, a capillary formed from the top to the bottom with the same diameter May be bundled so as to extend in the vertical direction, and the overall shape of the bundled may be provided so as to be similar to the shape of the internal space of the side wall 12. The flow channel assembly 14 d of FIG. 6 (d) 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 channel assemblies 14 c and d may be provided not only in the hood 1 and the side wall 12 but also in the hood 1 or only in the side wall 12. Moreover, when providing in the side wall 12, you may provide only a part of the height. Further, it is needless to say that the flow channel assembly 14 includes one in which a plurality of small chambers are partitioned by the partition plate 144, and one in which a plurality of longitudinal holes 146 are pierced in a block-like member 145.

  In addition, fins that protrude in the lateral direction may be separately provided inside the flow channel assembly 14. In the embodiment of FIGS. 7A and 7B, the flow channel assembly 14 in the side wall 12 is partitioned by a plurality of partition plates 147, the fins 148 for the partition plates 147, and the side walls 12 for the partition plates 147. Fins 149 are provided 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 erected at the center, whereas the fins 149 extend from the left and right side walls 12 toward the center partition plate 147. It is provided projecting. As shown in FIG. 7 (a), the middle three-tiered fins 148, 149 protrude alternately at different heights, and the uppermost and lowermost fins 148, 149 face each other at the same height. While protruding, a gap 103 through which water passes is formed between them.

  In the embodiment of FIGS. 7C and 7D, fins 148 are provided to project in the direction of the left and right side walls 12 with respect to the partition plate 147 erected at the center. In addition, fins 149 are provided protruding toward the center partition plate 147 with respect to the left and right side walls 12. The fins 148, 149 project at the same height and face each other, and a gap 103 through which water passes is formed between them. In addition, it is preferable that the space | interval of the vertical direction of these fins or the horizontal direction shall be 5 cm or less.

  As such, by providing the fins 148 and 149 inside the flow channel assembly 14, a swirling basin is mainly generated at the lower part of the fins 148 and 149, and the separation of the floating matter 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. Also, the fins are not limited to those projecting horizontally as shown in FIG. 7, but as shown in FIG. 8A, the fins may be inclined so that the tip end faces downward. The inclination angle is not particularly limited, but a range of 0 to 60 degrees with respect to the horizontal is preferable. Furthermore, an opening 104 may be provided between the fins 148 and 149 and the partition plate 147 and the side wall 12. Since the air is discharged upward from the opening 104, the air can be prevented from being accumulated at the connection point between the fins 148 and 149 and the partition plate 147 or the side wall 12. In addition, the shape and dimension of the opening part 104 are not limited, For example, you may form in several hole shape.

  Furthermore, as shown in FIGS. 9A and 9B, a wing portion 13 may be provided on the lower portion of the side wall 12 as necessary. The wing portion 13 is formed to extend obliquely from the lower end of the side wall 12 to the outside of the hood 1. Thus, by providing the wing portion 13 inclined downward and outward to the lower part of the side wall 12, sedimentation of floating matter such as flock can be promoted, and further, when water flows from the lower part to the upper part, it soars The floating matter can also be effectively taken into the hood 1 by hitting the wing portion 13. In addition, also in the case where the blade 13 is provided, the flow channel aggregate 14 in which a plurality of thin tubes are formed in a bundle may be provided in the space 101 in the hood 1 as necessary. In the present embodiment, although the pair of vanes 13 is provided on the opposite side wall 12, it may be provided on only one of the side walls 12 or on all the side walls 12 in the front, rear, left, and right. Furthermore, only a part of the wing portion 13 may be provided on one side wall 12.

  Furthermore, as shown in FIG. 9C, folded pieces 131 folded back downward from the wing portion 13 may be provided on the left and right sides and the lower side of the wing portion 13 not connected to the side wall 12. By providing the folded-back piece 131, the floating matter entering the lower side of the wing portion 13 can be effectively taken into the hood 1 without escaping from the left and right or the lower side of the wing portion 13.

  Further, the hood 1 may be configured by assembling parts divided into a plurality into one hood 1. For example, as shown to Fig.10 (a), three parts which consist of hoods 10a, 10b, and 10c may be provided, these parts may be assembled, and one hood 1 may be comprised (FIG. 10b). In the hood 1 of FIG. 10, the inside of the block is hollowed out to form a space 101, a drainage channel 103 is formed to communicate with the space 101, and a drainage pipe 2 is connected to the outlet of the drainage channel 103. There is. Although all the flow path assemblies 14 provided in the hoods 10a, 10b and 10c are fixed to the side wall 12, the fixing method to the hood 1 is not limited to this. Moreover, although the food | hood 1 of FIG. 10 has shown the aspect at the time of installing so that the inlet 112 side may face up, the direction of the food | hood 1 is not limited to this.

  FIG. 11 schematically shows an installation example of the underwater / water surface sediment / floating material removal apparatus according to the present invention. In the figure, arrows indicate the flow of water, and in the present embodiment, in the process of flowing water from right to left in the sedimentation basin 3, water is taken into the hood 1 provided in the middle, A part of the inside is drained from the drainage pipe 2 through the drainage pipe 21 to the outside of the settling basin 3. At this time, floating substances in water are also effectively accumulated by the hood 1 and discharged from the discharge port 23. As shown in FIG. 11 (a), the drain pipe 21 is provided such that the outlet 23 is exposed to the outside of the sedimentation tank 3, and in particular, the position where the outlet 23 is lower than the water surface W in the sedimentation tank 3. It is arranged to be. The drainage pipe 21 is disposed so that not only the drainage port 23 but also the entire drainage pipe 2 including the drainage valve 22 is at a position lower than the water surface W.

  Thus, by making the outlet 23 lower than the water surface W, water in the sedimentation tank 3 is sucked from the space 101 in the hood 1 into the drainage pipe 2 by the atmospheric pressure applied to the water surface W, and the drainage pipe 21 Finally, the water is drained from the outlet 23. The amount of water taken in from the hood 1 can be appropriately adjusted by the drainage valve 22.

  FIG. 11 (b) schematically shows a sediment / floating material removing device for draining water from the hood 1 to the drainage trough 4 provided in the sedimentation tank 3. The drainage trough 4 is formed in a bowl shape capable of storing a predetermined amount of water in its interior, but within the sedimentation basin 3 at a depth of water where the water in the sedimentation basin 3 does not directly flow into the interior beyond the upper part of its peripheral wall. is set up. As shown in the figure, the drainage pipe 2 rises from the connecting portion with the hood 1 as it is and is connected to the bottom surface of the drainage trough 4, and the outlet 23 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 of a straight pipe, the air in the drainage pipe 2 can easily escape even without the air vent pipe 24 and drainage can be smoothly performed.

  The water in the drainage trough 4 is drained out of the sedimentation basin 3 by a drainage pipe or the like (not shown), and the water surface W2 in the drainage trough 4 is kept always lower than the water surface W1 of the sedimentation basin 3 . Then, since the atmospheric pressure applied to the water surface W1 and the water surface W2 is equal, the water in the sedimentation tank 3 having a high water level is sucked into the hood 1 through the drainage pipe 2 in order to balance the water surface W1 and the water surface W2. The water is collected into the drainage trough 4 and then drained out of the settling basin 3 by a drainage 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 using the difference in water level, but the means for absorbing water is not limited to this, and is shown in FIG. Thus, the water absorption means by the pump 5 may be provided in the middle of the drain pipe 21, and in this case, the outlet 23 and the drain pipe 21 may be higher than the water surface W of the settling basin 3. The pump 5 can use a general pump such as a vacuum pump or a water absorption pump. Further, the water absorption means is not limited to this, and the water absorption means by the pump 5 and the water absorption means utilizing the water level difference may be combined.

  The apparatus for removing sediments and floats of water and water according to the present invention may include a plurality of hoods 1, and as an example, the plurality of hoods 1 may be provided one on top of the other. When a plurality of hoods 1 are piled up and down, as shown in FIG. 12, the hood 1a at the top can be connected to the hood 1b disposed below the hood 1b by a drainage pipe 27a. The drain pipe 27a is provided so as to hang down from the discharge hole 111a of the hood 1a at the top, and is connected to the discharge hole 111b of the hood 1b from above. Similarly, the hood 1b is connected to the hood 1c disposed below the hood 1b by a drain pipe 27b. In the drain pipes 27a, b, a plurality of slit-shaped openings 271a, b are formed respectively near the discharge holes 111a, b in the hoods 1a, b, and water and suspended matter are drained from the openings 271a, b. It can be taken into the tubes 27a, b. In the present embodiment, the openings 271a and 27b are formed in the shape of slits extending in the circumferential direction of the drain pipes 27a and 27b. However, the openings 271a and b may be in the shape of slits extending in the axial direction. Other shapes such as a circular shape may be used. Furthermore, the openings 271a and 271b are not limited to the diameter of the opening, and may be different from each other. That is, the flow velocity in the hood 1 is increased if it is closer to the connection between the hood 1 and the drain pipe 2. The openings near the junction with the drain pipe 2 at the openings 271 a and b have smaller opening diameters. On the other hand, by increasing the diameter of the opening far from the connecting part, the amount of water drawn in can be made constant regardless of the position of the opening.

  In this embodiment, water and suspended matter taken into the lowermost hood 1c flow from the discharge hole 111 directly into the drainage pipe 27b connected to the upper part, but are taken into the hoods 1a and 1b. Are sucked into the respective drain pipes 27a, b through the slit-like openings 271a, b of the drain pipes 27a, b provided in the hoods 1a, 1b, and both are moved to the drain pipe 2 and finally Are discharged from the discharge port 23. Although 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 appropriately increased or decreased as needed.

  In addition, regarding the installation method of the sediment and floating matter removal apparatus of the water according to the present invention and the water surface, the intake port 112 of the hood 1 is usually installed so that the intake port 112 faces downward. It may be installed so as to face upward, and furthermore, as shown in FIG. 13, the downward hood 1a and the upward hood 1b may be provided to face each other at a predetermined interval. By installing in this way, among floats passing between the upper and lower hoods 1a and b, those with a lower specific gravity are installed in the upper installed hood 1a and those with a higher specific gravity are installed below. Each of them is effectively taken into the food 1b. When the downward hood 1a and the upward hood 1b are installed opposite to each other, they are basically disposed at the same position in the horizontal direction so that the centers of the hoods 1a and 1b coincide with each other. The position may be shifted to the front, rear, left, and right. Moreover, although the intake ports 112 are basically arranged to be parallel to each other with respect to the angles of the hoods 1a and b, the angle is not limited to this, for example, with respect to the intake port 112 of the hood 1a. The intake port 112 of the hood 1 b may be installed at an angle so as to be inclined. Although the hood 1b facing upward is installed facing the hood 1a facing downward in the embodiment of FIG. 13, the effect of the present invention can be obtained even if the hood 1b facing upward is installed alone.

  Moreover, regarding the installation method of the sediment / floating substance removal apparatus of water and water surface concerning this invention, you may install several hood 1 continuously in the front-back direction with respect to the flow of water. Furthermore, the plurality of hoods 1 may be installed in a grid shape continuous in the longitudinal direction, the lateral direction, and the diagonal direction in plan view. In these cases, a gap may or may not be provided between adjacent hoods 1. For example, in FIG. 14 (a), three pairs of the hood 1a facing downward and the hood 1b facing upward are provided so as to face each other at a predetermined interval, and are provided continuously in front and back. In this way, when installed continuously back and forth, from the hood 1a and the hood 1b located at the front with respect to the flow of water, to the hood 1a and the hood 1b located at the middle and the rear in order, Water moves, but due to the bypassing that occurs in the hood 1 at that time, the precipitate can be effectively separated and drained from the upper and lower drainage 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 long and the side wall 12b of the hood 1b is short, and conversely, the side wall 12a of the hood 1a behind it is The lengths of the side walls 12a and 12b may be alternated back and forth so that the side wall 12b of the hood 1b is made short and the water can meander up and down, thereby further enhancing the effect of the bypass flow. . In the present embodiment, three sets of the hood 1a and the hood 1b are continuously installed at the front and back. However, the number of the hoods 1a and the hood 1b connected continuously is not limited to this.

  Moreover, regarding the installation method of the sediment and floating matter removal apparatus of water and water surface concerning this invention, as shown in FIG. 15, you may provide the air diffusion pipe 6 below the food | hood 1 suitably. By providing the air diffuser 6 below the hood 1 and performing air blow, the suspended matter ascends with the air bubbles and can be efficiently fed into the hood 1. Furthermore, by increasing the amount of aeration of the aeration tube on the downstream side of the water flow, the air bubbles play a role of a kind of air curtain, and the suspended matter is less likely to go downstream than the hood 1. It becomes possible to take in inside. In addition to air bubbles (nano bubbles, micro bubbles, ordinary bubbles), a mixture of water, viscous foam (foam like beer, foam like shampoo, etc.) or a mixture thereof is used from the air diffuser 6 It may be generated. Note that nanobubbles and microbubbles have weak buoyancy and may be flushed with water before being taken into the hood. Therefore, a plurality of air diffusers may be provided, and nano bubbles, micro bubbles, normal bubbles, liquids (water and the like) may be used in combination or in combination.

  The installation of the air diffusion tube 6 is not limited to the lower side of the hood 1, and may be provided inside the hood 1b, for example, as shown in FIG. 14 (a). When the channel assembly 14 is provided inside the hood 1, it is preferable to provide the air diffuser 6 between the discharge hole 111 and the channel assembly 14, as shown in FIG. 14 (b).

  Moreover, FIG. 16 shows an example of the installation method of the sediment / floating substance removal apparatus of the water which concerns on this invention which piled up and provided the several food | hood 1 up and down, and which concerns on this invention. In FIG. 16A, two sets of three hoods 1a, 1b and 1c stacked are juxtaposed in the front-rear direction with respect to the flow of water. These two sets of water and water surface sediment and float removal devices are connected at the drain pipe 21, and the water and floats taken in from any hood 1 are finally drained from the same outlet 23. . Moreover, you may arrange | position, without providing a clearance gap between the adjacent food | hoods 1 like the food | hood 1a of the uppermost part in FIG.16 (b). In the present embodiment, only the top hood 1a is provided without a gap, but the hood 1 having no gap is not limited to the top hood.

  In the method of installing a plurality of hoods 1 stacked one on top of the other according to the present invention, the orientation of the hoods 1 may not necessarily be the same, for example, as shown in FIG. Of the three hoods 1a, 1b, 1c stacked as shown in Fig. 2B, 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 drainage pipe 27, but as shown in FIG. 17 (b), the drainage pipe 27 is near the drainage holes 111a and 111b in the hoods 1a and 1b. A plurality of slit-shaped openings 271a, b are formed respectively. Furthermore, as shown in the embodiment of FIG. 17A, a hood 1d facing upward may be provided below the hood 1c provided facing downward so as to face the hood 1c.

  Further, FIG. 18 shows a different method of installing the water / water surface sediment / floating material removing apparatus according to the present invention in which a plurality of hoods 1 are provided one on top of the other. In the present embodiment, two sets of three hoods 1a, 1b and 1c stacked are juxtaposed in the back and forth direction with respect to the flow of water, but before and after these two sets of hoods 1a, 1b and 1c, Each barrier 7 is provided. The barrier 7 has a gap between the hood 1a, 1b and 1c on the upstream side and the bottom surface of the settling basin 3 and has a gap on the downstream side of the hood 1a, 1b and 1c and the water surface W It is formed as. Thus, 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 and 1c, the flow of water is made below the hoods 1a, 1b and 1c. The floats can be effectively taken into the hood 1 and removed.

  The apparatus for removing sediments and suspended solids on the water and the water surface according to the present invention, in which the flow channel assembly 14 is provided in the hood 1, and a plurality of the hoods 1 are installed according to FIGS. 19 (a) to 19 (d). A concrete example of will be described. In these embodiments, the individual thin tubes constituting the flow path aggregate 14 in each hood 1 are aligned such that the upper openings 141 on the side of the discharge holes 111 of the hood 1 have a substantially horizontal height. However, it is not limited to this aspect.

  In FIG. 19 (a), the downward hood 1a and the upward hood 1b are provided opposite to each other, and between the downward hood 1a and the upward hood 1b, that is, the lower opening 142a of the flow channel assembly 14a Between the lower opening 142b of the tube assembly 14b and the lower opening 142b is a flow path through which water flows. The air diffusion pipe 6 may be provided in this flow path, and the air bubbles generated by the air diffusion pipe 6 cause the suspended matter contained in the water flowing in the flow path between the hood 1a and the hood 1b to rise. It can be efficiently delivered into 14a. Such an air diffusing pipe 6 may be provided similarly to those in FIGS. 19 (b) to 19 (d).

  The thing of FIG.19 (b) has provided the barrier 8 which has the cross-sectional shape which made the substantially V-shape horizontal between the downward hood 1a and the upward hood 1b. The barrier 8 allows water flowing between the hood 1a and the hood 1b to flow up and down, efficiently feeding the suspended matter into the flow path aggregate 14a, b. In the present 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. Furthermore, the aeration pipe 6 of FIG. 19 (a) and the barrier 8 of FIG. 19 (b) may be combined and installed. Specifically, as shown in FIG. 31 (b) described later, by arranging the barrier 8 and the aeration pipe 6 in combination, the floating 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, the water flow can be diverted up and down by changing the height (position) at which the barrier 8 is provided between the upstream side and the downstream side.

  In FIG. 19 (c), the length of the narrow tube constituting the flow path aggregate 14a of the hood 1a facing downward is formed so as to be gradually shortened as it goes from the side wall 12a side to the center side of the hood 1a A thin tube is not provided in the central portion), whereby the lower opening 142a side is entirely concave. On the other hand, the length of the narrow ridges constituting the flow path assembly 14b of the hood 1b upward is formed to be gradually longer from the side wall 12b to the center side of the hood 1a, whereby the lower opening 142b is formed. The side is generally convex. As a result, the water flow path between the opposing hood 1a and the hood 1b is low on the side wall 12 side and high in the inverted V shape at the central portion, and a flow path meandering in the height direction is formed. The water flowing through the flow path meanders up and down to promote the bypass flow, and the floating matter can be efficiently sent into the flow path aggregate 14a, b.

  In FIG. 19 (d), the length of the narrow tube constituting the flow channel assembly 14a of the hood 1a facing downward is formed in a wave shape from the side wall 12a side to the other side wall 121a side, The lower opening 142a side is uneven. On the other hand, the length of the thin ribs forming the flow path aggregate 14b of the hood 1b facing upward is also formed to be wavy, whereby the lower opening 142b side is uneven. And since the lower opening 142a and the lower opening 142b are out of phase so that the unevenness is opposite to each other, a flow path meandering in the height direction is formed between the opposing hood 1a and the hood 1b. As a result, the water meanders up and down to promote the bypass flow, and the floating matter can be efficiently sent into the flow path aggregates 14a, b.

  In FIG. 20 (a), four hoods 1a, b, c, d are vertically stacked, but they are connected to each other by a drainage pipe 27. Specifically, the drainage pipe 27a connecting the hood 1a and the hood 1b is provided along the thin tube substantially at the center of the thin tube forming the flow path assembly 14a and the flow path assembly 14b, and the upper and lower portions thereof are It fixes with respect to the flow-path aggregate | assembly 14a and the flow-path aggregate | assembly 14b, respectively. The upper end and the lower end of the drain pipe 27a are formed in a length that aligns with the flow path assembly 14a and the upper openings 141a and 141b of the flow path assembly 14b. Also, the hood 1c and the hood 1d below the hood 1c are similarly connected by the drain pipe 27c. Further, the hood 1 b and the hood 1 c are connected to each other by a drain pipe 27 b connected to the drain hole 111.

  Further, the flow channel aggregate 14a of the hood 1a in FIG. 20 (a) has the lower opening 142a so that the length of the capillary gradually shortens from the side wall 12a to the central drain pipe 27a of the hood 1a. It forms diagonally and, thereby, the lower opening 142a side is entirely concave. On the other hand, the channel assembly 14b of the hood 1b has the lower opening 142b formed obliquely so that the length of the narrow ridge gradually increases from the side wall 12b to the center side of the hood 1b. The opening 142 b side is entirely convex. By doing this, the water flow path between the opposing hood 1a and hood 1b is low on the side wall 12 side and the central part of the hoods 1a and b is high V-shaped, so the water meanders up and down The flow is promoted, and the floating material can be efficiently fed into the flow channel assembly 14. The same configuration is also applied to the flow path assemblies 14c, d of the hood 1c and the hood 1d.

  The flow of water and suspended solids in the hoods 1a to d and the drain pipes 27a to 27c in FIG. 20A 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, when only the drain valve of the drain pipe 2 connected to the hood 1d is opened, the water flows downward. When both the upper and lower drainage valves are opened, the fluid flows both upward and downward, but more to the larger displacement. In addition, there are also those which flow upward or downward against the flow depending on the magnitude of specific gravity separately from the amount of drainage. That is, the one with a small specific gravity is taken into the upper hood 1a, c, and the one with a high specific gravity sinking against the upper flow is taken into the lower hood 1b, d.

  Although the thing of FIG.20 (b) piles up four food | hood 1a, b, c, d, the point mutually connected by drain pipe 27a, b, c is the aspect of FIG. 20 (a) Is the same as However, in the present embodiment, the thin tubes constituting the flow channel aggregates 14a to 14d are formed to have the same length, and all are formed to be flat in the upper openings 141a to 141d and the lower openings 142a to 142d. Are different.

  Furthermore, 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 wall 12b and the side wall 12c. The partitions 16b are preferably provided in pairs on opposite surfaces of the side walls 12b and c. In the drawing, a pair of the partitions 16b is provided on the left and right, but it may be a pair on the front and back. Thus, by providing the partition 16b between the side wall 12b and the side wall 12c, the water flow of this portion is prevented to concentrate in the flow path between the hood 1a and the hood 1b or between the hood 1c and the hood 1d. be able to. Furthermore, the hood 1a and the hood 1d may be provided with partitions 16a and 16d so as to extend from the side wall 12a and the side wall 12d toward the drain pipe 2 as necessary. These partitions 16a and 16d can also obtain the same effect as the partition 16b.

  Here, instead of providing these partitions 16, as shown in FIG. 20 (d), the inside 101 of the cylindrical or prismatic block-like member 17 is hollowed out and the inner wall surface 114 converges to the discharge hole 111. And a channel assembly 14 may be formed. In this embodiment, a portion corresponding to the top wall 11 and the side wall 12 is integrally formed, and the two hoods 1 are joined at the upper surface portion of the block-like member 17 as shown in the figure. The outer surface plays the same role as the partition 16 and can effectively prevent water flow between the hoods 1.

  Furthermore, although the thing of FIG.20 (c) piles up four food | hood 1a, b, c, d, the drainage pipe 27a which carries out the connection connection of the food | hood 1a and the food | hood 1b is the flow-path aggregate 14a. It is provided along the thin tubes at approximately the center of the thin tubes constituting the flow path assembly 14b, and the upper part and a part of the center thereof are respectively fixed to the flow path assembly 14a and the flow path assembly 14b. The drain pipe 27a is formed such that the upper end thereof is aligned with the upper opening 141a, and a part on the lower side extends so as to project further downward than the pipe assembly 14b, and the lower end portion thereof is in the vicinity of the hood 1b The hood 1c is inserted into a drain pipe 27b connected to the hood 1c.

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

  20 (a) to 20 (c) are four hoods 1a, b, c and d stacked vertically, but not limited to the vertical direction, and depending on the angle of piping, the whole may be inclined. It may be arranged as Moreover, although the number of the food | hood 1 of FIG. 19, FIG. 20 is two or four, it is not limited to these numbers.

  When a plurality of hoods 1 are vertically stacked, as shown in FIG. 21 (a), the drainage pipes 2a, b, c directly connected to the respective hoods 1a, b, c may be individually provided. Good. That is, while the drain pipe 2a is directly connected to the hood 1a, the drain pipe 2b is directly connected to the hood 1b, and 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 It is provided penetrating 1a and 1b. With this configuration, the amount of drainage of each of the hoods 1a, b, c can be adjusted individually. FIG. 21 (b) shows an example in which six hoods 1a to f are stacked vertically and installed. In this embodiment, the hood 1a is a drainage pipe 2a, the hood 1b is a drainage pipe 2b, and the hood 1c is drainage A drain pipe 2d is 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 connected directly to the hood 1f. The bundle of drainage pipes 2 outside the hood 1 may be housed together in a single thick pipe as shown in FIG. 21 (c). At this time, the gaps between the pipes 2a, 2b, and 2c may be closed as appropriate.

  Furthermore, in the case where the plurality of hoods 1 are vertically stacked, as shown in FIG. 21 (b), the mesh portion 9 may be provided so as to close the gap between the two hoods 1. By providing the mesh 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 still another 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 space portion 101 inside. The water collecting portion 229 is formed in a cylindrical shape in which the upper and lower ends are open, and a plurality of openings 291 are provided on the wall surface. And this water collection part 29 is connected with the inner pipe part 292 in the upper end part. The inner pipe portion 292 is provided in the drainage pipe 2 so as to extend to the front of the drainage valve (not shown). As shown in FIG. 22 (b), the inner pipe portion 292 is fixed to the inner peripheral wall of the drainage pipe 2 by four plate-like connecting portions 293 protruding from the outer peripheral surface thereof.

  With this configuration, among floating substances taken into the space portion 101 of the hood 1, floating substances having a size that can pass through the opening 291 of the water collecting portion 29 are further sucked into the water collecting portion 29, and the inner pipe Through the part 292, it is effectively discharged to the outside. In addition, suspended matter of a size that can not pass through the opening 291 is also discharged to the outside through the gap between the drain pipe 2 and the inner pipe portion 292.

  Furthermore, as shown in FIG. 22 (c), a partition plate 119 may be provided to vertically partition the space 101 inside the water collection tank 1. In this case, as shown in FIG. 22 (c), the partition plate 119. The water collection portion 29 may be formed in a cylindrical shape which is branched into a plurality of lines at the upper side and extends in the partitioned space.

  Furthermore, as shown in FIG. 22 (d), when there is no partition plate 119, a substantially box-like water collecting portion 29 fitted to the shape of the hood 1 may be provided in a nested manner. In the water collecting portion 29, as shown in the figure, an opening 291 formed in a slit shape is formed on the wall surface on the front side. Also, the bottom 294 is formed open.

  Figures 23 to 34 are further different embodiments of the water and water surface sediment and float removal apparatus of the present invention. The floating material removal apparatus for water and water according to this embodiment has a pair of ceiling walls disposed in the water of the sedimentation tank and continuously provided at the upper side so as to extend away from each other toward the lower side. The hood has a side wall formed to a predetermined height from the connection portion on both left and right sides of the ceiling wall, and extends along the connection portion, and an opening is formed in the peripheral wall And a drain pipe projecting from the hood through the side wall. The structure will be described in detail below.

  As shown in FIGS. 23 and 24, in the hood 1 of this embodiment, a pair of flat top walls 11 are connected to each other at their upper side portions 115, and from the upper side portions 115 to the lower side portions 116. They are formed to be inclined so as to be separated from each other. In the present embodiment, the top wall 11 is formed in a rectangular shape, but may have a different shape such as a square or a trapezoid. Furthermore, at least a part of the ceiling wall 11 may be inclined to face the lower side, for example, as shown in FIG. 4B, one ceiling wall 11 of the pair of ceiling walls 11 is inclined. The other top wall 11 may be a non-inclined vertical surface. Furthermore, as shown in FIG. 4C, a portion of the ceiling wall 11 includes one that is inclined in the opposite direction such that the inner wall surface 114 faces upward, not downward.

  The left and right side portions 117 of the top wall 11 are provided with a pair of side walls 15 so as to close both sides of the space 101 inside the top wall 11 from the connecting portion of the upper side portion 115 to a predetermined height. The side wall 15 can be provided from the connection portion of the upper side portion 115 of the top wall 11 to an arbitrary height, and in FIG. 23, the side wall 15 is formed to have a minimum necessary height. Thus, the lower wall 116 of the ceiling wall 11 may be provided so as to completely block both sides of the space 101 of the ceiling wall 11. Furthermore, the shape of the side wall 15 is not limited to a triangle as shown in FIG. 23 (b) or FIG. 25 (a), but it may be inverted V-shaped as shown in FIG. 25 (b). It may be in the form of

  A drainage pipe 2 is provided in a space 101 in the ceiling wall 11. The drainage pipe 2 extends in the lateral direction along the connection portion of the upper side portion 115 of the ceiling wall 11, and both end sides thereof are provided to project from the side wall 15 to the outside of the hood 1.

  A plurality of slit-like openings 201 are formed in the peripheral wall of a portion of the drain pipe 2 extending in the space 101 of the ceiling wall 11, and water and suspended matter are taken into the drain 2 from the opening 201. Can. In the present embodiment, the opening 201 is formed in the shape of a slit extending in the circumferential direction of the drainage pipe 2. However, the opening 201 may be in the shape of a slit extending in the axial direction. Other shapes are also possible. Moreover, you may provide the detachable cap part 202 for obstruct | occluding opening at the opening part of the front-end | tip of the drainage pipe 2 as needed.

  A drain 23 is provided at an end opposite to the end where the cap portion 202 is attached, and a drain valve 22 is provided in front of the drain 23. Furthermore, if necessary, an air vent pipe 24 may be provided which branches off halfway through the drain pipe 2 and rises in the longitudinal direction. In the present embodiment, the air vent pipe 24 projects out of the hood 1 from 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 manner, the air entering the drain pipe 2 from the hood 1 can be effectively drained, and water can be smoothly drained from the drain pipe 2. Furthermore, a part of the drainage pipe 2 may be a bellows structure, and the bellows structure can be easily adjusted when the water level of the sedimentation tank 3 changes.

  In this embodiment, the cap 202 is attached only to one end side of the drainage pipe 2. However, the cap 202 may be attached to both ends of the drainage pipe 2. In this case, the drainage pipe 2 is used instead of the air vent pipe 24. A draining pipe may be separately provided which branches off in the middle and rises in the vertical direction. Furthermore, the cap 202 is not attached to both ends of the drain pipe 2, and while the outlet 23 is provided at one end, an air vent pipe 24 leading to the outlet 26 is provided at the other end. Good. When it is not necessary to provide an air vent pipe 24 or a drain pipe which is branched 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. It may be completely closed.

  The hood 1 of the present embodiment is formed in a substantially triangular shape in a side view, but the shape is not limited to a triangle, and the upper end portion is flat in the connecting portion of the ceiling wall 11 as shown in FIG. It may be formed to have a shape or an R-shaped surface having no corner as shown in FIG. As described above, the ceiling wall 11 of the hood 1 is inclined to be separated from the connection portion to the lower side portion, and the inner wall surface 114 is formed to be flared from the top to the lower portion, thereby existing in the space 101 The float having a small specific gravity gathers in the drain pipe 2 provided near the upper connection portion and can be efficiently taken into the drain pipe 2 from the opening 201. Furthermore, the upper surface of the ceiling wall 11 plays the role of an inclined plate, which can promote the settling of floats such as floc. In addition, the inclination angle of the top wall 11 is not limited, Even if it inclines 1 degree with respect to horizontal, it has the effect.

  The space 101 in the hood 1 may be a complete cavity as shown in FIG. 23, but if necessary, a channel aggregate 14 as shown in FIG. 27 may be provided. The flow channel assembly 14 divides the space in the hood 1 in the horizontal direction, and the upper opening 141 thereof is directed to the drain pipe 2 side, and the lower opening 142 thereof is directed vertically to the open side of the hood. Stretch.

  As shown to Fig.27 (a), the flow-path aggregate | assembly 14e is formed as bundle | flux shape of the several thin tube. The individual thin ribs forming the flow channel assembly 14 e are formed so that the diameter becomes smaller from the lower end to the upper end, and in the central portion of the hood 1 in the substantially vertical direction and on the ceiling wall 11. As it approaches, it is bundled at an appropriate angle so as to follow the inclination of the top wall 11. As a result, the overall shape when bundling the thin strands becomes 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 channel assembly 14e is located below the drainage pipe 2 and the lower opening 142 is located at the lower end of the hood 1, but these positions are not limited thereto. . The flow channel assembly 14 e is attached to the hood 1 by fixing the peripheral wall of the narrow ridge located on the outermost side to the inside of the top wall 11 of the hood 1.

  Further, the channel aggregate 14f of the embodiment shown in FIG. 27 (b) is bundled so that the narrow ridges are formed to have the same diameter from the upper end to the lower end and all extend in the vertical direction, and the hood 1 The lengths of the individual strips are formed along the inclination of the top wall 11 of the. As a result, the overall shape when bundling the thin strands becomes similar to the shape of the space 101 formed by the top wall 11 of the hood 1. Furthermore, the flow path aggregate 14 f is provided lower than the top wall 11 so as to form a gap 102 with the top wall 11 of the hood 1. The channel aggregate 14 f can be attached by fixing the peripheral walls of the narrow ridges located on the left and right end sides to the inside of the side wall 15 of the hood 1.

  The flow channel assemblies 14e and 14f both take in water and suspended matter from the thin lower opening 142 and discharge them from the upper opening 141 to the drain pipe 2 side, but in the case of the flow channel assembly 14f, once The one discharged into the gap 102 with the top wall 11 moves as it is along the top wall 11 to the lower side of the drain pipe 2 and is finally taken into the drain pipe 2. By providing the flow channel assembly 14 inside, the horizontal cross section of the hood 1 is subdivided by a plurality of fine lines, and the individual opening areas are reduced, so that the suction effect by the hood 1 can be maximized. . Furthermore, the flow of water in the hood 1 is arranged in an upward direction, and unnecessary convection such as lateral flow does not occur, and the floating matter can be effectively sucked up.

  The channel assemblies 14e and 14f of this 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. It may be a thin tube having a square or rectangular cross-sectional shape, or a so-called honeycomb structure or other cross-sectional shape in which regular hexagonal thin tubes are bundled. The fine ribs constituting the flow path aggregates 14e and 14f can be formed to any thickness, but in order to maximize the above effects, the inner diameter should be formed in the range of 0.1 mm to 50 mm. Is preferred. The inner diameters of the individual capillaries may not be identical to each other, and may be different depending on places. In addition, gaps may not be provided between adjacent thin tubes, and when the gaps are provided, the interval is not particularly limited. Furthermore, 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 an assembly of thin fibers, but a plurality of flow channels are partitioned by partition plates or block members. It includes those in which a plurality of longitudinal holes serving as flow paths are pierced.

  The flow channel assembly 14 described above can be provided in the hood 1 of any aspect, but as shown in FIG. 29A, when the drainage pipe 27 for connection is provided in the hood 1, The flow channel assembly 14 can be provided in other parts by avoiding the drain pipe 27 part.

  An installation example of the apparatus for removing sediments and suspended solids from water and water according to the present invention is schematically shown in FIG. As shown in FIG. 28 (a), the drain pipe 2 is provided so that the side where the cap portion 202 is not attached is extended and the outlet 23 is exposed to the outside of the sedimentation tank 3, and in particular, the outlet 23 is It is arrange | positioned so that it may become a position lower than the water surface W in the sedimentation basin 3. As shown in FIG. The drainage pipe 2 is disposed so that the entire drainage pipe 2 including the drainage valve 22 as well as the drainage port 23 is at a position lower than the water surface W.

  Thus, by making the outlet 23 lower than the water surface W, the water in the sedimentation tank 3 is sucked from the space 101 in the hood 1 into the drainage pipe 2 by the atmospheric pressure applied to the water surface W, and the drainage pipe 2 Finally, the water is drained from the outlet 23. The amount of water taken in from the hood 1 can be appropriately adjusted by the drainage valve 22.

  FIG. 28 (b) schematically shows a suspended matter removing device for draining water from the hood 1 to the drainage trough 4 provided in the sedimentation basin 3. The drainage trough 4 is formed in a bowl shape capable of storing a predetermined amount of water in its interior, but within the sedimentation basin 3 at a depth of water where the water in the sedimentation basin 3 does not directly flow into the interior beyond the upper part of its peripheral wall. is set up. As shown in the drawing, the drain pipe 2 is provided with cap portions 202 at both ends thereof, and a drain pipe 27 which is branched and rises from the middle thereof is provided. The drainage pipe 27 penetrates the bottom of the drainage trough 4 as it is, and the drainage port 23 provided at its end is provided so as to be exposed in the drainage trough 4. As described above, since the drainage pipe 2 of the present embodiment drains water right above by the drainage pipe 27 formed of a straight pipe, the air in the drainage pipe 2 is easily drained even without providing the air vent pipe 24 separately. Can be done smoothly.

  The water in the drainage trough 4 is drained out of the sedimentation basin 3 by a drainage pipe or the like (not shown), and the water surface W2 in the drainage trough 4 is kept always lower than the water surface W1 of the sedimentation basin 3 . Then, since the atmospheric pressure applied to the water surface W1 and the water surface W2 is equal, the water in the sedimentation tank 3 having a high water level is sucked into the drainage pipe 2 of the hood 1 to try to balance the water surface W1 and the water surface W2. The water is collected into the drainage trough 4 and then drained out of the settling basin 3 by a drainage 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 using the difference in water level, but the means for absorbing water is not limited to this, and is shown in FIG. 28 (c). Thus, the water absorption 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 portion 202 at its both end portions, and the drain pipe 27 which is branched and rises from the middle thereof is provided. Further, in the middle of the drain pipe 27, an air vent pipe 24 extending in the longitudinal direction as it is and a drain pipe 28 extending in the lateral direction branch off. When the pump 5 is used as in the present embodiment, the outlet 23 and the drain 28 may be higher than the water surface W of the settling basin 3. Moreover, the pump 5 can utilize general pumps, such as a vacuum pump and a water absorption pump. Further, the water absorption means is not limited to this, and the water absorption means by the pump 5 and the water absorption means utilizing the water level difference may be combined.

  The apparatus for removing sediments and suspended solids from water and water according to this embodiment may include a plurality of hoods 1, and as an example, the hoods 1 may be stacked one on top of the other. In the embodiment shown in FIG. 29 (a), both the drain pipe 2a of the hood 1a at the top and the drain pipe 2b of the hood 1b disposed therebelow are both closed at their both ends by the cap portions 202a, b. And are mutually connected by the drain pipe 27b. The drainage pipe 27b is vertically erected from the lower drainage pipe 2b and is connected to the upper drainage pipe 2a, whereby the drainage pipe 2a and the drainage pipe 2b can be communicated. Further, the drainage pipe 2a of the hood 1a at the upper part is provided with a drainage pipe 27a which is branched and rises from the middle thereof, and an air drainage pipe 24 extending longitudinally as it is along the drainage pipe 27a and a drainage pipe 28 extending in the lateral direction Branches.

  With this configuration, the water and the suspended matter taken into the lower hood 1b are taken in from the opening 201 of the drain pipe 2b and flow into the drain pipe 27b connected to the upper part as it is. Further, water and suspended matter taken into the hood 1a at the upper part are taken in from the opening 201 of the drain pipe 2a, joined from the drain pipe 2b and flown through the drain pipe 27b and merge with water and suspended matter And both move to the drainage pipe 27a. Then, the water is finally discharged from the discharge port 23 through the drain pipe 28. In the present embodiment, two hoods 1a and 1b are vertically stacked, but the number of hoods 1 is not limited to this and may be appropriately increased or decreased as needed. Furthermore, the opening 201 of the drainage pipe 2a and the opening 201 of the drainage pipe 2b are not limited with respect to their opening diameters, and may be opening diameters different from each other.

  In FIG. 29 (b), the two hoods 1a and 1b are vertically stacked as in FIG. 29 (a), but the arrangement of the drainage pipe and the air vent pipe is different. In the present embodiment, the upper hood 1a and the lower hood 1b are not connected to each other by a drain pipe, and are independent systems. That is, the hood 1a on the upper side takes the same mode as that of FIG. 28 (a), while the hood 1b on the lower side is an air vent pipe standing upright on the end side opposite to the outlet 23 of the drainage pipe 2 as it is. An exhaust port 26b and an air vent valve 25b are provided at the end of the connecting portion 24. The outlet 23a of the hood 1a and the drain valve 22a are provided independently of the outlet 23b of the hood 1b and the drain valve 22b, but by connecting the drain pipe 2a and the drain pipe 2b into one. The outlet 23a, b and the drain valve 22a, b may be integrated.

  Further, FIG. 30 shows an embodiment in which three hoods 1a, b and c are vertically stacked. In this embodiment, the drainage pipe 2a of the hood 1a at the top, the drainage pipe 2b of the hood 1b disposed in the middle, and the drainage pipe 2c of the hood 1c at the bottom are both capped at both ends. It is a closed type by 202, and is mutually connected so that communication is possible by drain pipes 27b and 27c. Further, the drainage pipe 2a of the hood 1a at the upper part is provided with a drainage pipe 27a which is branched and rises from the middle thereof, and an air drainage pipe 24 extending longitudinally as it is along the drainage pipe 27a and a drainage pipe 28 extending in the lateral direction Branches.

  When a plurality of hoods 1 are stacked vertically, as shown in FIG. 30, the one formed in the inverted V shape in which the central portion of the side wall 15 is cut up is the upper portion of the hood 1 disposed below. The space between the upper and lower hoods 1 can be arranged narrower than the other, because it can be inserted into the cut-up portion of the side wall 15 of the hood 1.

  In the method of installing the apparatus for removing sediments and floats of water and water according to the present invention, usually, the space 101 of the hood 1 is installed facing downward, but this is upside down so that the space 101 faces up. Further, as shown in FIG. 31A, the downward hood 1a and the upward hood 1b may be provided to face each other at a predetermined interval. By installing in this manner, as shown by the arrows in the figure, among floating substances passing between the upper and lower hoods 1, those floating in the lower specific gravity are transferred to the hood 1a installed at the upper side. The heavy ones are effectively taken into the hoods 1b installed below. Although the hood 1b facing upward is installed facing the hood 1a facing downward in the embodiment of FIG. 31, the effect of the present invention can be obtained even if the hood 1b facing upward is installed alone.

  Further, when the downward hood 1a and the upward hood 1b are provided to face each other at a predetermined interval, as shown in FIG. 31 (b), between the downward hood 1a and the upward hood 1b. May be provided with a barrier 8 and an air diffuser 6. In addition, although the barrier 8 of this embodiment is a plate shape extended | stretched to a vertical direction, the shape of the barrier 8 is not limited to this, What made the substantially V character as shown in FIG.19 (b) horizontal may be sufficient. . Thus, by arranging the barrier 8 and the air diffuser 6 in combination, the floating material can be separated more easily and effectively. 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, the water flow can be diverted up and down by changing the height (position) at which the barrier 8 is provided between the upstream side and the downstream side.

  In addition, regarding the installation method of the sediment / floating material removal apparatus of water and water surface according to the present invention, the case where the top wall 11 of the hood 1 is parallel to the flow of water as shown in FIG. As shown in 32 (b), there are two ways to face the case. Arrows in the figure represent the flow of water. As shown in FIG. 32A, when the ceiling wall 11 is parallel to the flow of water, the water enters the space 101 from the lower part of the upstream side wall 15 of the hood 1 and the hood 1 from the lower side of the downstream side wall 15 Go outside. 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 portion 101, and the lower side on the downstream side Go around the part 116 and go out of the hood 1.

  Moreover, regarding the installation method of the sediment and floating matter removal apparatus of water and water surface concerning this invention, as shown in FIG.32 (b), you may provide the air diffusion pipe 6 below the food | hood 1 suitably. By providing the air diffuser 6 below the hood 1 and performing air blow, the suspended matter ascends with the air bubbles and can be efficiently fed into the hood 1. Furthermore, by increasing the amount of aeration of the aeration tube on the downstream side of the water flow, the air bubbles play a role of a kind of air curtain, and the suspended matter is less likely to go downstream than the hood 1. It becomes possible to take in inside. From the aeration tube 6, in addition to air bubbles (nano bubbles, micro bubbles, ordinary bubbles), water or foam having viscosity (foam like beer, foam like shampoo, etc.), or a mixture thereof May be generated. The installation of the air diffusion pipe 6 is not limited to the lower side of the hood 1 and may be provided inside the hood 1. Note that nanobubbles and microbubbles have weak buoyancy and may be flushed with water before being taken into the hood. Therefore, a plurality of air diffusers may be provided, and nano bubbles, micro bubbles, normal bubbles, liquids (water and the like) may be used in combination or in combination.

  FIGS. 33 and 34 show an example of a method of installing a water / water surface sediment / floating material removal apparatus according to the present invention in which a plurality of hoods 1 are provided one on top of the other. In the embodiment shown in FIG. 33, two sets of three hoods 1a, 1b, 1c stacked are juxtaposed in the front-rear direction with respect to the flow of water. These two sets of water and water surface sediment and float removal devices are connected at a drain pipe 28, and water and floats taken in from any hood 1 are finally drained from the same outlet 23. . In the aspect of FIG. 33, the hoods 1 adjacent to each other may be disposed without providing a gap. For example, as shown in FIG. 16B, the hood 1a at the top may be provided without a gap, but the hood 1 without a gap is not limited to the top.

  Further, in the embodiment shown in FIG. 34, two sets of three hoods 1a, 1b and 1c stacked are juxtaposed in the front-rear direction with respect to the flow of water, but these two sets of hoods 1a, 1b, Before and after 1c, barriers 7 are provided respectively. The barrier 7 has a gap between the hood 1a, 1b and 1c on the upstream side and the bottom surface of the settling basin 3 and has a gap on the downstream side of the hood 1a, 1b and 1c and the water surface W It is formed as. Thus, 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 and 1c, the flow of water is made below the hoods 1a, 1b and 1c. The floats can be effectively taken into the hood 1 and removed.

  Furthermore, in the case where the plurality of hoods 1 are provided, they may be installed in a grid shape continuous in the longitudinal direction, the lateral direction, and the diagonal direction in plan view. In these cases, a gap may or may not be provided between 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 resin such as hard polyvinyl chloride and acrylic, metal, glass, pottery, carbon fiber, etc. It is preferable to use a structure that can be reinforced with a frame or the like to withstand water pressure.

1, 1a, 1b, 1c, 1d ... ... hood 2, 2a, 2b, 2c, 2 '... ... drainage pipe 3 ... ... sedimentation tank 4 ... ... drainage trough 5 ... ... pump 6 ... ... aeration tube 7 ... ... barrier 8 ... ... Barriers 9 ... ... Nets 11 ... ... Heavenly walls 12, 12a, 12b, 12c, 12d ... ... Sidewalls 13 ... ... Wings 14, 14a, 14b, 14c, 14d, 14e, 14f
... ... Flow path 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 pipe 22, 22a, 22b ... ... Drain valve 23, 23a, 23b ... ... Exhaust port 24, 24a, 24b, 24 '... ... Air vent pipe 25, 25a, 25b ... ... Air vent valve 26, 26a, 26b ... ... Exhaust port 27, 27a, 27b, 27c ... ... drainage pipe 28 ... ... drainage pipe 29 ... ... water collecting part 101 ... ... space 102 ... ... clearance 103 ... ... clearance 104 ... ... opening 111, 111 '... ... drainage hole 112 ... ... Intake port 113 ... ... Peripheral edge 114 ... ... Inner wall surface 115 ... ... Upper side 116 ... ... Lower side 117 ... ... Left and right side 118 ... ... Opening 119 ... ... Partition plate 141, 141a, 141b, 141c, 141d ... ... Upper opening 142, 142a, 142b, 142c, 142d ... ... Lower opening 143 ... ... Fixing member 144 ... ... Partition plate 145 ... ... Block shaped member 146 ... ... Longitudinal holes 147: Partition plates 148: Fins 149: Fins 151: Bases 201: Openings 202, 202a, 202b, 202c: Caps 271a, 271b: Openings 291: Openings 292: Openings 292: Openings Inner pipe part 293 ... ... Coupling part 294 ... ... Bottom part
W, W1, W2 ... ... Water surface

Claims (17)

A hood which is disposed in the water of a sedimentation tank and which is open at the bottom and has a space for containing water inside, and at least a part of the inner wall is formed to be inclined and facing the bottom side A water / water surface sediment / floating material removing device provided with a drain pipe for draining water taken into the hood near the top or the top of the hood, wherein the hood is discharged at the top thereof A hole is provided at the lower part thereof with an intake port opened downward, and a ceiling wall extending while converging from the peripheral edge of the intake port to the discharge hole is provided to communicate with the space in the hood And a drainage pipe connected to the hole, wherein the hood is provided with a flow path assembly which divides the space in the hood in the horizontal direction and extends in the vertical direction, and the sedimentation of the water and the water surface Object and floating matter removal device.   The apparatus for removing sediments and suspended solids on water and water according to claim 1, wherein a side wall is continuously provided below the lower end of the ceiling wall. The apparatus for removing sediments and suspended solids from water and water according to claim 1 or 2 , wherein vanes extending obliquely from the lower end of the side wall to the outside of the hood are continuously provided. A hood which is disposed in the water of a sedimentation tank and which is open at the bottom and has a space for containing water inside, and at least a part of the inner wall is formed to be inclined and facing the bottom side A water / water surface sediment / floating material removal apparatus comprising a drain pipe for draining water taken into the hood near the top or the top of the hood , wherein the hood is directed to the lower side It has a pair of ceiling walls provided in a row at the upper side so as to extend apart from each other, and on both left and right sides of the ceiling, side walls formed to a predetermined height from the connection portion, Sediment and floating of water and water surface having a drain pipe extending along the connecting portion and having an opening formed in the peripheral wall and the both ends thereof penetrating the side wall and protruding out of the hood Object removal device. 5. The apparatus for removing sediments and floats of water and water according to claim 4 , wherein a cap for closing the opening is provided at one or both ends of the drain pipe. The water and water surface according to any one of claims 1 to 5 , wherein a plurality of the hoods are provided one on top of the other, and the hood at the upper part is connected by a hood and a drain pipe disposed below the hood. Sediment and float removal equipment. A hood which is disposed in the water of a sedimentation tank and which is open at the bottom and has a space for containing water inside, and at least a part of the inner wall is formed to be inclined and facing the bottom side A water / water surface sediment / floating material removing apparatus provided with a drain pipe for draining water taken into the hood near the top or the top of the hood, wherein a plurality of the hoods are stacked vertically The upper hood is connected to the hood disposed below the hood by a plurality of drainage pipes, and the plurality of drainage pipes are respectively directly connected to the hoods to be connected, and the sediments of the water and the water surface・ Float removal device. 7. The apparatus for removing sediments and suspended solids from water and water according to claim 6 , wherein an opening is formed in the drainage pipe connecting the upper and lower hoods. The water and water sedimentation according to any one of claims 4 to 8 , wherein the hood is provided with a channel assembly which divides the space in the hood in the horizontal direction and extends in the vertical direction. Object and floating matter removal device. The channel assembly is a plurality of flow passages divided formed in the partition plate, according to claim 1 or 9, characterized in that fins projecting laterally is provided on the side wall of the partition plate and the hood Water and water surface sediment / float removal device as described in.   11. The apparatus for removing sediments and suspended solids from water and water according to any one of claims 1 to 10, wherein an air diffusion pipe is provided below or inside the hood. A hood which is disposed in the water of a sedimentation tank and which is open at the bottom and has a space for containing water inside, and at least a part of the inner wall is formed to be inclined and facing the bottom side A water / water surface sediment / floating material removing apparatus provided with a drain pipe for draining water taken into the hood near the top or the top of the hood, wherein the hood downward and the hood upward facing An apparatus for removing sediments and floats on water and water, wherein the apparatus is provided to face each other at a predetermined interval.   The downward hood and the upward hood include a channel assembly, and a water channel between the opposing hood and the hood is formed to meander in the height direction. Water and water surface sediment / float removal device as described in. The downward hood and the upward hood are provided with a channel assembly, and are connected to each other by a drainage pipe whose upper and lower parts are fixed to the channel assembly of the downward hood and the upward hood. 14. The apparatus for removing sediment and float from water and water according to claim 12 or 13 , characterized in that: A hood which is disposed in the water of a sedimentation tank and which is open at the bottom and has a space for containing water inside, and at least a part of the inner wall is formed to be inclined and facing the bottom side A water / water surface sediment / floating material removing device provided with a drain pipe for draining water taken into the hood near the top or the top of the hood, wherein a plurality of openings are provided in the space inside the hood Water collecting part having a water collecting part, the water collecting part being connected at its upper end to an inner pipe part provided so as to extend in the drainage pipe; sediment of water and water surface・ Float removal device.   16. The apparatus for removing sediments and suspended solids from water and water according to any one of claims 1 to 15, wherein a plurality of said hoods are installed continuously in the longitudinal direction with respect to the flow of water. The sediment / floating material removal of water and water surface according to any one of claims 1 to 16, wherein a plurality of the hoods are installed in a grid shape continuous in a longitudinal direction, a lateral direction, and an oblique direction in plan view. apparatus.

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