JP2016026872A - Scum removal device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a scum removal device capable of making a flow rate of scum-contamination water flowing in a channel formed by a trough at a proper flow rate.SOLUTION: A scum removal device 10 comprises: a trough 12 extending outward of a sedimentation basin 1, and forming a channel 124 in which scum-contamination water including scum flows; a dam 11 whose upper end part 11a sinks under the water level; and an inflow port 125 disposed on the trough 12 so as to occlude freely, where the scum-contamination water after passing the upper end part 11a of the dam 11 passes when flowing in the channel 124. The inflow port 125 regulates a flow rate of the scum-contamination water flowing in the channel 124 to equal to or less than a pump flow rate of a pump 161.SELECTED DRAWING: Figure 3

Description

  The present invention relates to a scum removing device that removes scum floating on the water surface of a settling basin.

  Scum may float on the water surface in the sedimentation basin provided in the sewage treatment facility. If the scum floats on the surface of the water, the purification process is hindered, so a scum removing device for removing the scum may be provided in the sedimentation basin. As this scum removing device, a weir whose upper end part floats on the water surface, a mechanism for submerging the upper end part of the weir at a predetermined timing, and scum mixed water beyond the weir where the upper end part is submerged are directed to the outside of the settling basin. And a trough that forms a flow path. As such a scum removing device, for example, those described in Patent Document 1 and Patent Document 2 are known. The scum-mixed water that has flowed out of the sedimentation basin through the flow path is pumped up by a pump, and a predetermined process for removing the scum is performed.

JP 7-305325 A JP-A-9-131589

  The scum removing devices described in Patent Document 1 and Patent Document 2 determine the flow rate of scum-mixed water flowing into the flow path according to the distance from the water surface to the upper end portion when the upper end portion of the weir is submerged. is there. However, in the scum removing devices described in Patent Document 1 and Patent Document 2, the weir whose upper end portion floats on the water surface is lowered into the water by a mechanism at a predetermined timing, and the upper end portion of the weir is submerged. For this reason, there is a problem that the distance from the upper end portion of the weir where the upper end portion is submerged to the water surface changes due to the operation accuracy of the mechanism, deterioration due to wear, and the like. In particular, the scum removing device described in Patent Document 2 is provided with a mechanism for submerging the upper end portion of the weir in the water. For this reason, the operation of the mechanism is hindered by the underwater dirt, and the submergence operation of the weir may become unstable. Furthermore, in the scum removing device described in Patent Document 1 or Patent Document 2, the relationship between the flow rate of scum-mixed water flowing into the flow path and the pumping flow rate of the pump that pumps up the scum-mixed water is not considered. For this reason, the scum mixed water exceeding the pumping flow rate of the pump may flow into the flow path, and the scum mixed water may overflow from the flow path and be unable to remove the scum from the sedimentation basin. Further, the scum-mixed water that has flowed into the flow path may be discharged out of the scum removing device by natural flow without using a pump. In this case as well, if scum-mixed water that exceeds the flow rate discharged to the outside of the scum removal device due to natural flow flows into the flow path, the scum-mixed water may overflow from the flow path and the scum cannot be removed from the sedimentation basin. There is.

  An object of this invention is to provide the scum removal apparatus provided with the scum removal apparatus which can make the scum mixing water which flows into the flow path formed of the trough into an appropriate flow volume in view of the said situation.

The scum removing device of the present invention that solves the above-mentioned object is as follows.
In the scum removing device for flowing scum mixed water mixed with scum floating on the water surface of the settling basin toward the outside of the settling basin,
A trough extending toward the outside of the settling basin and forming a flow path into which scum-mixed water flows,
A weir whose upper end is submerged from the water surface;
A connecting member for connecting the trough and the weir;
The connection member has a seal member and a hinge made of a sheet material having flexibility,
The weir is rotated by the hinge, and maintains an upper end portion at a position immersed in water for a predetermined distance from the water surface even if the water level of the settling pond changes.

  In the scum removing device of the present invention, the seal member may include a bottom surface portion and a pair of side surface portions provided at both ends in the width direction of the bottom surface portion.

  According to the scum removing device of the present invention, the scum mixed water flowing into the flow path formed by the trough can be set to an appropriate flow rate.

It is a top view which shows an example of the sedimentation basin 1 in which the scum removal apparatus 10 which is one Embodiment of this invention was installed. It is AA sectional drawing of FIG. It is the B section enlarged view which expanded and showed the B section of FIG. FIG. 4 is a schematic perspective view of a weir, a trough, a connection member, and a lid shown in FIG. 3. It is the side view which looked at the trough and the cover body from the left side in FIG. It is sectional drawing which shows a scum pit. It is sectional drawing which shows the scum pit in the scum removal apparatus of other embodiment.

  Embodiments of the present invention will be described below with reference to the drawings.

  FIG. 1 is a plan view showing an example of a sedimentation basin 1 in which a scum removing device 10 according to an embodiment of the present invention is installed. FIG. 2 is a cross-sectional view taken along the line AA in FIG. In FIG. 1, the sludge scraper 30 shown in FIG. 2 is omitted. 1 and 2, the opening / closing mechanism 15 shown in FIG. 3 is omitted.

  As shown in FIG. 1, the sedimentation basin 1 is a pond having a substantially rectangular shape in plan view, surrounded by a pair of side walls 1a, an upstream wall 1b, and a downstream wall 1c. This sedimentation basin 1 is for removing sludge and scum contained in water flowing into the sedimentation basin 1 from the left side in FIG. The water from which the sludge and scum have been removed flows into a drainage channel (not shown) through a drainage basin 40 disposed on the right side in FIG. Hereinafter, the left direction in FIG. 1 may be referred to as an upstream direction, and the right direction in FIG. 1 may be referred to as a downstream direction. Also, the vertical direction in FIG. 1 may be referred to as the width direction.

  As shown in FIG. 2, the sedimentation basin 1 is provided with a scum removing device 10, a sludge scraper 30, a drainage basin 40, and a sludge pit 50. The sludge scraper 30 is provided at both ends of the sedimentation basin 1 in the width direction, and a pair of chains 31 that circulate in the sedimentation basin 1 and a plurality of flight plates 32 spanned between the pair of chains 31. And four sprockets 33 arranged for each chain 31. One of the sprockets 33 is driven to rotate clockwise in FIG. 2 by a motor (not shown). The chain 31 rotates clockwise in FIG. 2 as the sprocket 33 rotates. The flight plate 32 also rotates in the clockwise direction in FIG. The sludge that has settled at the bottom of the sedimentation basin 1 is scraped to the sludge pit 50 by the flight plate 32 that moves in the upstream direction of the sedimentation basin 1 near the bottom of the sedimentation basin 1. The sludge scraped to the sludge pit 50 is discharged to the outside of the sedimentation basin 1 by a sludge pump (not shown). Further, the flight plate 32 moving in the downstream direction of the sedimentation basin 1 near the water surface W of the sedimentation basin 1 has an upper end protruding from the water surface and a lower end immersed in the water. The scum floating on the water surface W of the settling basin 1 is transferred toward the weir 11 described later by the flight plate 32 in the vicinity of the water surface W of the settling basin 1.

  FIG. 3 is an enlarged view of a portion B showing the portion B of FIG. 2 in an enlarged manner. FIG. 4 is a schematic perspective view of the weir 11, the trough 12, the connecting member 13, and the lid body 14 shown in FIG. FIG. 5 is a side view of the trough 12 and the lid body 14 as viewed from the left side in FIG.

  As shown in FIG. 3, the scum removing device 10 includes a weir 11, a trough 12, a connection member 13 that connects the weir 11 and the trough 12, a lid 14, and an opening / closing mechanism 15 that opens and closes the lid 14. And a scum pit 16.

  As shown in FIGS. 3 and 4, the connection member 13 includes a fixed plate 131, a side plate 132, a seal member 133, and a weir hinge 134. The fixed plate 131 includes a plate bottom portion 131a and a pair of side plate portions 131b provided at both ends in the width direction of the plate bottom portion 131a. Moreover, the sealing member 133 is comprised from the bottom face part 133a and a pair of side face part 133b provided in the width direction both ends of the bottom face part 133a. In FIG. 3, the direction perpendicular to the paper surface is the width direction. The side plates 132 are a pair of metal plates welded to both end surfaces in the width direction of the weir 11. The fixed plate 131 is obtained by bending a metal plate. The downstream end surface of the fixed plate 131 is joined to the trough 12 by welding so that water cannot enter from the joint portion. The end of the seal member 133 in the downstream direction is bonded to the fixing plate 131 so that water cannot enter from the bonded portion. The seal member 133 is made of a rubber sheet material. In addition, the member which comprises the sealing member 133 should just be a sheet material which has flexibility, for example, may be a sheet material made of vinyl resin.

  The weir 11 includes a triangular prism-shaped portion 11b having a space inside, and a protruding surface portion 11c that protrudes downstream from the triangular prism-shaped portion 11b. Further, both end surfaces in the width direction of the weir 11 are covered with a pair of side plates 132, and the weir 11 and each side plate 132 are joined by welding so that water cannot enter the inside of the triangular prism-shaped portion 11b of the weir 11. Yes. The weir 11 and the side plate 132 may be integrally formed, for example, by bending a single metal plate.

  An end portion in the upstream direction of the side surface portion 133b of the seal member 133 is bonded to the side plate 132 so that water cannot enter from the bonded portion. The upstream end of the bottom surface portion 133a of the seal member 133 is bonded to the protruding surface portion 11c of the weir 11 so that water cannot enter from the bonded portion. The protruding surface portion 11 c of the weir 11 is attached to the plate bottom portion 131 a of the fixed plate 131 so as to be rotatable by a weir hinge 134. The weir hinge 134 is fixed to the protruding surface portion 11 c of the weir 11 and the plate bottom portion 131 a of the fixing plate 131 with bolts (not shown) so as to sandwich the bottom surface portion 133 a of the seal member 133. As shown in FIG. 4, the side surface portion 133 b of the seal member 133 is folded in a bellows shape so as not to hinder the rotating operation of the weir 11.

  The weir 11 has buoyancy adjusted so as to be submerged in water for a predetermined distance from the water surface W. Due to the buoyancy of the weir 11, the distance from the water surface W to the upper end portion 11 a of the weir 11 is always kept constant regardless of the water level of the sedimentation basin 1. In the present embodiment, the buoyancy of the weir 11 is adjusted so that the upper end portion 11a is submerged in water at a distance of 25 mm from the water surface W. In the following description, the distance from the water surface W to the upper end portion 11a of the weir 11 is referred to as the water depth. For example, when the position of the water surface W (the water level of the sedimentation basin 1) fluctuates at the position indicated by the two-dot chain line in FIG. 3, the weir 11 moves to the position represented by the two-dot chain line as the water surface W varies. Therefore, the stagnation water depth is always 25 mm.

  The upper surface 11 a downstream of the upper end portion 11 a of the weir 11 and the inner surface of the connecting member 13 form a swallow region 130 in which the water of the settling basin beyond the weir 11 is accumulated. The upper end portion of the side plate portion 131 b of the fixing plate 131, the upper end portion of the side surface portion 133 b of the sealing member 133, and the upper end portion of the side plate 132 protrude above the water surface W, respectively. For this reason, the water in the settling basin 1 does not enter the swallowing region 130 beyond the side plate portion 131b of the fixing plate 131, the side surface portion 133b of the seal member 133, or the side plate 132. In other words, only water that exceeds the upper end portion 11 a of the weir 11 can flow into the swallowing region 130. With this configuration, scum existing in the vicinity of the water surface W of the settling basin 1 can be efficiently allowed to flow into the intrusion region 130.

  The trough 12 includes an upstream side plate 12a, a downstream side plate 12b, and a bottom plate 12c that connects the upstream side plate 12a and the downstream side plate 12b. As shown in FIG. It has a shape. The upstream side plate 12a, the downstream side plate 12b, and the bottom plate 12c are formed by bending a single metal plate, but may be formed separately and joined by welding or the like. The trough 12 extends in the width direction of the sedimentation basin 1, and a flow path 124 for flowing scum-mixed water mixed with scum toward the outside of the sedimentation basin 1 is formed by the inner peripheral surface of the trough 12. . The trough 12 extends to a scum pit 16 (see FIG. 1) provided outside the sedimentation basin 1. The bottom plate 12 c of the trough 12 is inclined slightly downward toward the outside of the sedimentation basin 1. As shown in FIG. 3, the upper portion of the upstream side plate 12a of the trough 12 is an inclined surface inclined about 15 degrees in the downstream direction upward. The inclined surface is provided with an inlet 125 through which scum-mixed water exceeding the upper end portion 11 a of the weir 11 flows when flowing into the flow path 124.

  As shown in FIG. 5, the upstream side plate 12 a of the trough 12 is provided with three inflow ports 125 having a substantially rectangular shape having an R portion at a portion connecting the lower side and the side side, arranged side by side in the width direction. Although the number of inflow ports 125 may be one, each lid body 14 that closes each inflow port 125 can be made smaller by dividing the inflow port 125 into three. When the lid body 14 is large, distortion generated in the lid body 14 tends to increase. By reducing the size of the lid 14 and reducing the distortion generated in the lid 14, the sealing performance of the inlet 125 by the lid 14 can be improved. The upper side of the inflow port 125 is provided at a position above the surface on which the water surface W (water level represented by a solid line in FIG. 5) when the water level of the sedimentation basin 1 is the highest. In addition, the lower side of the inlet 125 is provided at a position below the surface on which the water surface W (the water level represented by a two-dot chain line in FIG. 5) when the water level of the sedimentation basin 1 is the lowest. Yes. Note that the flow rate of water flowing into the settling basin 1 is managed by a management system (not shown), and the fluctuation of the position of the water surface W of the settling basin 1 is about 50 mm at the maximum.

  From the inflow port 125, scum-mixed water having a flow rate that is equal to or higher than the flow rate of the scum-mixed water flowing into the swallow area 130 beyond the upper end portion 11 a of the weir 11 can pass through the flow path 124. That is, the total opening area of the three inlets 125 is set to an area equal to or larger than the area obtained by swallowing the length in the width direction of the weir 11 and multiplying the water depth. By setting it as such an opening area, the mixing rate of the scum of the scum mixing water flowing into the flow path 124 can be increased. This is because when the lid 14 is opened, the scum-mixed water having a flow rate equal to or higher than the flow rate of the scum-mixed water flowing into the swallow region 130 flows out from the swallow region 130 through the inlet 125, This is because the water level of the scum mixed water existing at 130 is lowered. When the water level of the scum mixed water is lowered, the scum floating near the water surface W of the settling basin 1 can be efficiently flowed into the intrusion region 130, and more scum mixed water near the water surface of the intrusion region 130 is obtained. It can flow into the flow path 124 from the inflow port 125.

  The distance h between the upper side and the lower side of the inlet 125 is preferably 1.5 times or more the stagnation water depth (here, 25 mm). By doing in this way, even if it shortens the length of the width direction of the inflow port 125, the flow volume of the scum mixing water which flows into the flow path 124 is securable. When the length in the width direction of the inflow port 125 is shortened, the length in the width direction necessary for the lid body 14 is shortened, and the inflow port 125 is made highly sealed by using the lid body 14 having a small distortion in the width direction. Can be occluded.

  As shown in FIG. 4, a packing 126 is provided in the inflow port 125 so as to surround the side and the lower side. When the inflow port 125 is closed by the lid body 14, the lid body 14 and the packing 126 come into contact with each other, so that the sealing property between the lid body 14 and the inflow port 125 can be improved. The packing 126 is a P packing in which a contact portion with the lid body 14 has a hollow cylindrical shape.

  The three lids 14 that open and close each inflow port 125 are rotatably attached to the upstream side plate 12a by a lid hinge 141 fixed to the upstream side plate 12a of the trough 12 via a mounting height adjustment base 147. It is attached. The lid body 14 has an upper end at a position higher than the water surface W. When the lid 14 closes the inlet 125, the lower end of the lid 14 is at a position lower than the water surface W. The lid body 14 is configured to open the inflow port 125 by rotating a lower portion submerged in water in a state where the inflow port 125 is closed to move upward on the water surface side. With this configuration, the scum-mixed water accumulated in the swallowing region 130 can be caused to flow into the flow path 124 by simply opening the lid 14.

  As shown in FIG. 3, the lid 14 is connected to an opening / closing mechanism 15 that opens and closes the lid 14. One opening / closing mechanism 15 is provided for each of the three lid bodies 14. The opening / closing mechanism 15 includes an electric valve 151, a water storage tank 152, a fulcrum 153, a first link 154, a second link 155, and a third link 156. The third link 156 is rotatably connected to the lid body 14, and each link is rotatably connected to each other. The electric valve 151 is connected to a pipe for sending water treated at the sewage treatment plant. When the electric valve 151 is opened, water is supplied from the pipe to the water storage tank 152. The water storage tank 152 is provided with a small hole (not shown) at the bottom. This small hole is for discharging the water in the water storage tank 152 little by little. When the water in the water storage tank 152 decreases, the rotational moment generated by the weight of the water storage tank 152 decreases, and the first link 154 rotates counterclockwise in FIG. 3, and the opening / closing mechanism 15 and the lid 14 are in FIG. The position indicated by the solid line.

  The motor-operated valve 151 is opened for 3 minutes, for example, at 1-hour intervals in response to a signal from a timer (not shown). By adjusting the timer, this time interval and the opening time can be arbitrarily set. The opening / closing mechanisms 15 connected to the lids 14 automatically operate in response to signals from the same timer, and the three opening / closing mechanisms 15 open and close almost simultaneously. In addition, it is good also as a structure which operates the three cover bodies 14 simultaneously with the one opening-and-closing mechanism 15, without providing the opening-and-closing mechanism 15 in each cover body 14. FIG. When the motorized valve 151 is opened, water flows into the water storage tank 152, and the weight of the water storage tank 152 increases due to the water that has flowed in. When the weight of the water storage tank 152 exceeds a predetermined amount, the first link 154 rotates clockwise around the fulcrum 153 in FIG. 3, and the second link 155 and the third link 156 are lifted upward. Then, the lid body 14 is rotated around the rotation center of the lid hinge 141 to the position indicated by the broken line in FIG. 3, and the inlet 125 is opened. The scum mixed water that has flowed into the flow path 124 from the opened inlet 125 flows into the scum pit 16 shown in FIG.

  FIG. 6 is a cross-sectional view showing the scum pit 16.

  The scum pit 16 includes a pump 161 having a suction port 162 near the bottom surface of the scum pit 16. This pump 161 pumps up the scum mixed water accumulated in the scum pit 16 and discharges it outside the scum removing device. That is, the pump 161 in the present embodiment corresponds to an example of the discharge means of the present invention, and the pump 161 up to the pump 161 is a scum removing device, and the downstream side of the pump 161 corresponds to the outside of the scum removing device. Since the scum is likely to float on the water surface, it is desirable that the water surface of the scum-mixed water comes at a position where the suction port 162 is provided in order to pump up the scum efficiently. In this embodiment, the total flow rate of the scum-mixed water flowing into the flow path 124 from the three inlets 125 is limited to be equal to or lower than the pumping flow rate pumped up by the pump 161. That is, the total opening area of the three inlets 125 is set such that the total flow rate of the scum-mixed water flowing into the flow path 124 is equal to or less than the pumping flow rate pumped by the pump 161. By providing this inflow port 125, the flow rate of the scum mixed water flowing into the flow path 124 can be limited, and the water level of the scum mixed water in the scum pit 16 can be maintained at the position where the suction port 162 is located. Moreover, it is possible to reliably prevent the scum-mixed water from overflowing from the flow path 124 and flowing back to the sedimentation basin 1. As described above, according to the scum removing device 10 of the present embodiment, the scum-mixed water flowing into the flow path 124 formed by the trough 12 can be set to an appropriate flow rate. Further, in the scum removing device 10 of the present embodiment, since the lid body 14 is opened and closed by the water flowing into the water storage tank 152, a new power source such as an actuator for opening and closing the lid body 14 is not required (so-called No power). Moreover, since the stagnation water depth is made constant by the buoyancy of the weir 11, it is possible to allow water from the water surface to a certain depth to flow into the flow path together with the scum at a constant flow rate simply by opening the lid body.

  In the scum removing device of the present embodiment, the scum removing device for flowing scum mixed water mixed with scum floating on the water surface of the settling basin toward a pump outside the settling basin extends toward the outside of the settling basin. And a trough that forms a flow path through which scum-mixed water flows, a weir whose upper end is submerged from the water surface, and a trough that can be closed to the trough, and scum-mixed water that exceeds the upper end of the dam And an inflow port that passes when flowing into the passage, and the inflow port restricts the flow rate of scum-mixed water flowing into the flow path to be equal to or less than the pumping flow rate of the pump. The inventive idea of a removal device can be derived. In the inventive concept, the scum removing device does not necessarily have to include the scum pit 16.

  Next, a scum removing device 10 according to another embodiment will be described. In the following description of the embodiment, the description overlapping the description of the scum removing device 10 of the previous embodiment is omitted.

  FIG. 7 is a cross-sectional view showing the scum pit 16 in the scum removing device 10 of another embodiment.

  In the previous embodiment, the scum mixed water in the scum pit 16 is discharged out of the scum removing device by using the pump 161. In this embodiment, the scum mixed water is discharged by the natural flow from the discharge port 165. It differs in that it is discharged outside. As shown in FIG. 7, the bottom surface of the scum pit 16 is provided with a discharge port 165 corresponding to an example of the discharge means of the present invention. In the scum removing device of this embodiment, the portion up to the discharge port 165 is the scum removing device, and the downstream side of the discharge port 165 corresponds to the outside of the scum removing device. Further, in the present embodiment, the total flow rate of the scum mixed water flowing into the flow path 124 from the three inlets 125 is set to be equal to or lower than the flow rate of the scum mixed water discharged from the discharge port 165 to the outside of the scum removing device. Limited. That is, the total opening area of the three inlets 125 is set to an area that is equal to or smaller than the opening area of the discharge port 165. In the present embodiment, the discharge port 165 is provided on the bottom surface of the scum pit 16, but may be provided on the side surface of the scum pit 16.

  Also in this embodiment, the same effect as the previous embodiment can be obtained. In addition, since the pump 161 is not used, power consumption is reduced.

  The present invention is not limited to the above-described embodiment, and various modifications can be made within the scope described in the claims. For example, in this embodiment, the opening / closing mechanism 15 that opens and closes the lid body 14 by changing the weight of the water storage tank 152 by the water flowing into the water storage tank 152 is provided. However, the lid body 14 is opened and closed by an actuator such as a motor. You may let them. Further, the lid 14 may be opened / closed using the movement of the flight plate 32 when moved to a predetermined position. Moreover, although the example which provides the rotational cover body 14 was demonstrated, it is good also as the slide-type cover body 14 which moves along the plane formed by the inflow port 125. FIG. Furthermore, it is good also as a structure which controls the position of the sliding direction of the slide-type cover body 14 using an actuator. By controlling the position of the sliding lid 14, the flow rate of the scum mixed water flowing into the flow path 124 can be arbitrarily adjusted. For example, the flow rate of the scum mixed water flowing into the flow path 124 may be adjusted by controlling the position of the lid body 14 according to the amount of scum mixed water in the scum pit 16. Further, for example, when the stagnation water depth fluctuates for some reason, the position of the lid 14 may be controlled according to the fluctuating stagnation water depth to adjust the flow rate of the scum mixed water flowing into the flow path 124. . Moreover, in this embodiment, although the water depth swallowed is made constant by the buoyancy of the weir 11, it is good also as a structure which provides the float which floats on the water surface separate from the weir 11, and suspends the weir 11 in the float. In addition, even if it is a structural requirement contained only in each description of each embodiment and modification which were demonstrated above, you may apply the structural requirement to another embodiment and modification.

The scum removing device described so far is a scum removing device that flows scum mixed water mixed with scum floating on the water surface of the settling basin toward the outside of the settling basin,
A trough extending toward the outside of the settling basin and forming a flow path into which scum-mixed water flows,
Discharging means that is provided outside the settling basin and discharges scum-mixed water flowing through the flow path to the outside of the scum removing device,
A weir whose upper end is submerged from the water surface;
An inlet through which the scum mixed water that is provided in the trough so as to be closed and passes over the upper end portion of the weir flows into the flow path;
A lid for closing the inlet,
The weir is to maintain the upper end portion at a position submerged in water for a predetermined distance from the water surface even if the water level of the settling pond changes.
The inflow port is capable of passing scum-mixed water having a flow rate higher than the flow rate of scum-mixed water exceeding the upper end portion.
The lid body is capable of adjusting a flow rate of scum mixed water flowing into the flow path through the inflow port, and the discharge means discharges the flow rate of scum mixed water flowing into the flow path. The flow rate is limited to less than the flow rate.

Furthermore, in the scum removing device for flowing the scum mixed water mixed with the scum floating on the water surface of the settling basin toward the outside of the settling basin,
A trough extending toward the outside of the settling basin and forming a flow path into which scum-mixed water flows,
Discharging means that is provided outside the settling basin and discharges scum-mixed water flowing through the flow path to the outside of the scum removing device,
A weir whose upper end is submerged from the water surface;
The trough is provided so as to be able to be closed, and includes an inlet through which scum-mixed water exceeding the upper end portion of the weir flows when flowing into the flow path,
The inflow port may restrict the flow rate of scum-mixed water flowing into the flow path to be equal to or lower than the flow rate discharged by the discharge unit.

  According to the scum removing device, even if the distance from the water surface to the upper end portion of the weir varies, the flow rate of the scum-mixed water flowing into the flow path is limited by the inflow port. It can prevent overflowing.

In the scum removing device, the weir maintains an upper end portion at a position immersed in water for a predetermined distance from the water surface even if the water level of the settling pond changes.
The inflow port is characterized in that scum-mixed water having a flow rate equal to or higher than the flow rate of scum-mixed water exceeding the upper end portion can pass therethrough.

  By doing so, it is possible to increase the scum mixing rate of the scum-mixed water flowing into the flow path by allowing water from the water surface to a certain depth to flow into the flow path together with the scum regardless of the change in the water level.

  Moreover, the said scum removal apparatus WHEREIN: The said inflow port may be divided | segmented into the some opening along the direction where the said trough is extended.

Furthermore, in the scum removing device, further comprising a lid for closing the inflow port,
It is preferable that the lid body is capable of adjusting a flow rate of scum-mixed water that passes through the inflow port and flows into the flow path.

  By adjusting the flow rate of scum-mixed water flowing into the flow path, even if the distance from the water surface to the upper end of the weir varies for some reason, scum-mixed water flows into the flow path according to the varied distance. An appropriate amount of flow can be achieved.

  Further, when the inlet is divided into a plurality of openings, it is possible to reduce the distortion generated in the lid by reducing the lid, and the sealing of the inlet by the lid can be improved.

DESCRIPTION OF SYMBOLS 1 Sedimentation basin 10 Scum removal apparatus 11 Weir 12 Trough 124 Flow path 125 Inlet 14 Lid 15 Opening / closing mechanism 161 Pump

Claims (2)

In the scum removing device for flowing scum mixed water mixed with scum floating on the water surface of the settling basin toward the outside of the settling basin,
A trough extending toward the outside of the settling basin and forming a flow path into which scum-mixed water flows,
A weir whose upper end is submerged from the water surface;
A connecting member for connecting the trough and the weir;
The connection member has a seal member and a hinge made of a sheet material having flexibility,
The scum removing device is characterized in that the weir is rotated by the hinge and maintains an upper end portion at a position submerged in water for a predetermined distance from the water surface even if the water level of the settling pond changes.   The scum removing device according to claim 1, wherein the seal member includes a bottom surface portion and a pair of side surface portions provided at both widthwise end portions of the bottom surface portion.

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