JP2008086997A5 - - Google Patents

Description

Sand lifting equipment

  The present invention relates to a sand raising device provided in a rainwater settling basin or the like of a sewage treatment facility.

Conventionally, a storm water settling basin of a storm water pumping station in a sewage treatment facility has been provided with a sand raising device comprising a jet pump for transferring sand deposited on the bottom surface of the storm water settling basin to a predetermined location. The suction port of the jet pump in the sand pumping apparatus using this jet pump is provided so as to be located above the pump pit provided at the lowest position on the bottom surface of the rainwater settling basin. Therefore, when the jet pump is driven, the sand in the pump pit is sucked from the suction port and transferred to a predetermined place through the pipe .

  In addition, since the sand pumping apparatus using the jet pump uses high-pressure water as a driving source, the power cost is high. Therefore, there is a sand pumping apparatus using a spiral blade type sand pump with low power cost.

In the sand pumping apparatus using this sand pump, the suction port of the sand pump is provided above the pump pit. Therefore, when the sand pump is driven, the sand in the pump pit is sucked from the suction port and transferred to a predetermined place via the pipe .
nothing special.

However, in the conventional sand raising device, even if sand is present in the pump pit, even if the jet pump or the sand raising pump starts driving, the sand cannot be sufficiently sucked. There was an inconvenience that the sand could not be moved sufficiently.

This is because when the jet pump or the sand pump is started to drive, the suction port is blocked by the sand that has accumulated in the pump pit, and neither water nor sand can be sucked.

Therefore, the present invention has been made to solve the above-described drawbacks, and its purpose is to enable smooth suction without the suction port of the sand pump being blocked by the sand in the pump pit. The object is to provide a sanding device.

This onset Ming, in order to achieve the above object, transferring the sand precipitated settling basin rainwater settling basin or the like, by suction with water in place by Agesuna pump having a spiral blade provided in the pump pit In the sand raising device, the sand raising pump is provided in the pump pit so that the spiral blades are horizontally rotated, and a nozzle for injecting pressure water to the sand settled near the suction port of the sand raising pump to disturb it. The pump pit is provided substantially horizontally toward the suction port .
Another feature of the present invention is that the injection direction of the nozzle is directed toward the vortex outside the center of rotation of the spiral blade of the sand pump.

In the sand raising apparatus according to the present invention, the sand pump is provided in the pump pit so that the spiral blades are horizontally rotated, so that a vortex is generated in the vicinity of the suction port of the working sand pump, and a sediment is formed near the suction port. Since the nozzle which jets pressure water to the sand thus disturbed is provided substantially horizontally toward the suction port on the pump pit side, the disturbed sand rides on the vortex and is smoothly sucked into the suction port. Therefore, the sand pump can exhibit high suction capability without the suction port being blocked by the sand in the pump pit .
Further, when the nozzle injection direction is directed toward the vortex flow outside the rotation center of the swirl vane of the sand pump, the effect of promoting the vortex suction can be obtained.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings. FIG. 1 shows the sand pumping apparatus of the present invention applied to a rainwater settling basin (hereinafter referred to as “sedimentation basin”) of a sewage treatment facility. FIG. 1 (a) is a sectional view thereof, and FIG. FIG. 2A is a partial plan view of FIG. 1A, FIG. 2 is a cross-sectional view taken along line II of FIG. 1B, and FIG. 1A corresponds to the cross-sectional view of FIG. Yes.

  The settling basin 1 is configured such that rainwater flows from one of the settling basins 1 and the rainwater that has settled and separated from the sand flows out from the other settling basin 1 in the same manner as the known settling basins. Further explanation will be given using the plan view of FIG. 1 (b). If rainwater flows in from the upper side of FIG. 1 (b), the rainwater settled and separated from the sand flows out from the lower side of FIG. 1 (b). It will be.

The form of the bottom surface 1a of the sand basin 1 is to collect sand (not shown) on the bottom surface 1a in a pump pit 2 having a flat bottom that is lower than the bottom surface 1a provided at a substantially central position of the bottom surface 1a. It is formed to be able to. That is, the bottom surface 1a is inclined so that the center line in the rainwater inflow direction is the lowest, as shown in FIG. Further, as shown in FIG. 2 of the cross section taken along the line E in FIG. 1B, the pump pit 2 is inclined so as to be the lowest. Therefore, when water flows out from a nozzle (not shown) on the bottom surface 1a, the sand on the bottom surface 1a is collected in the pump pit 2 as indicated by an arrow in FIG. 1 (b).

The sand pump 10 is a known submersible pump having spiral blades, and a pump that has been used as a submersible sludge pump in a sewage treatment facility can be used. The sand pump 10 has a suction port 11 facing downward, that is, the suction port 11 is directed toward the bottom surface of the pump pit 2 and at a predetermined distance from the bottom surface, and the sand is pumped through the discharge pipe 12 and the support 13. It is provided in the pond 1.

The nozzles 20a and 20b do not obstruct the flow of sand flowing into the pump pit from the central trough described later between the suction port 11 of the sand pump 10 and the bottom 2a of the pump pit 2 on opposite sides of the suction port 11. (See (b) of FIG. 1). The nozzles 20 a and 20 b are provided substantially horizontally toward the suction port 11 of the sand raising pump 10, and their injection directions are substantially parallel to each other on the opposite sides of the rotation axis 3 of the spiral blade of the sand raising pump 10. In the opposite direction and directed toward the vortex outside the center of rotation of the spiral blade of the sand pump 10 . Since the nozzles 20a and 20b are provided substantially horizontally toward the suction port 11 of the sand raising pump 10, and the injection direction is directed to the vortex flow outside the rotation center of the spiral blade of the sand raising pump 10, the sand raising is performed. The sand in the vicinity of the suction port 11 of the pump 10 can flow into the vortex to promote suction.

  Next, the control operation of the sand pump 10 and the nozzles 20a and 20b will be described using the flowchart of FIG. Although not shown, a pump (not shown) for supplying pressure water to the sand pump 10, nozzles 20a and 20b, valves provided in supply pipes 21a and 21b for supplying pressure water to the nozzles 20a and 20b, etc. Is configured to be driven and controlled by a controller (not shown) formed around a programmable controller that controls the sand basin 1 in an integrated manner.

  Assume that the inflow of rainwater into the sand basin 1 is stopped and a process of discharging sediment deposited on the bottom surface of the sand basin 1 has arrived (Yes in step 100. Hereinafter, step is referred to as “S”). Valves (not shown) provided in the supply pipes 21a and 21b are opened, pressure water is ejected from the nozzles 20a and 20b, and counting of a first timer T1 (not shown) is started (S102). After the first timer T1 expires, the sand pump 10 is driven and the second timer T2 starts counting (Yes in S104, S106).

When pressure water is ejected from the nozzles 20 a and 20 b, sand accumulated near the suction port 11 of the sand pump 10 is disturbed, and the disturbance gradually spreads throughout the pump pit 2. Therefore, the sand is efficiently sucked from the suction port 11 by being accompanied by water and transferred to a predetermined place via the discharge pipe 12.

  After the second timer T2 expires, for example, one minute after the second timer T2 starts, the valves of the nozzles 20a and 20b are closed (Yes in S108, S110). Even if the nozzles 20a and 20b are closed and the water ejected from the nozzles 20a and 20b disappears, the sand is entrained by the sucked water because the vicinity of the suction port 11 is fluidized by driving the sand pump 10. Are effectively discharged.

  As described above, the injection of the pressure water from the nozzles 20a and 20b only needs to destroy and disturb the accumulated sand in the vicinity of the suction port 11 of the sand pump 10, so that before the operation of the sand pump 10 starts. A short time is sufficient. Therefore, it is not always necessary to continue the operation of the sand pump 10 and the operation cost can be reduced.

When the discharge of the sand from the pump pit 2 is completed (Yes in S108), that is, when a water level gauge (not shown) provided in the pump pit 2 detects a predetermined lower limit water level, the sand pump 10 is stopped. (S110). The sand pump 10 restarts driving at the upper limit of the water level meter and stops driving at the lower limit of the water level meter until the driving is stopped (S110) after starting driving (S106). Be controlled.

In the above example, Roh nozzle is set to two, it may be one or three or more.

  In the above example, the nozzles 20a and 20b are provided with two timers T1 and T2 and driven before and after the sand pump 10 is driven. You may make it drive for the predetermined time before. However, as described above, when the nozzles 20a and 20b are driven before and after the sand pump 10 is driven, the fluidization by the sand pump 10 and the fluidization by the nozzles 20a and 20b are more effective. Disturbing action can be enhanced.

In the following be further described in detail with reference to FIG. 5 is a plan view of FIG. 4 and rainwater settling basin is a schematic cross-sectional view of a rainwater settling basin and pump well. The pump well 30 connected to the settling basin 1 is provided with a drain pump 31 and a stagnant water pump 32, and sewage such as rain water pumped up by the stagnant water pump 32 is supplied to the pump pit 2. Then, the water is supplied to sand collecting nozzles 40, 41, and 42 for jetting pressure water so that the sand accumulated on the bottom surface 1a of the sand basin 1 flows out.

  Hereinafter, the procedures for sand collection and sand discharge will be described in detail.

  The inflow of sewage into the sand basin 1 is stopped at the gate 50.

  Next, the staying water in the settling basin 1 is drained by a staying water pump 32 to a sewage settling pond, an inflow trough, etc. (not shown).

However, drainage here has certain limits. This is because the sand basin 1 is connected to the pump well 30 through the continuous portion 60, and the water staying in the sand basin below the continuous portion 60 is not drained by the drain pump 31 . That is, if it demonstrates using FIG. 4, after draining with the drainage pump 31 to the level L which is the top level of the connection part 60, the accumulated water below the L level of the sand basin 1 will not be drained. In this state, that is, underwater, not only is the amount of pumped water transferred by the sand pump increased, which is uneconomical, but it is also necessary to overcome the water pressure and move the sediment to collect the sand. It is necessary to eject at high pressure. High-pressure sand collection not only requires a running cost to generate high pressure, but also increases the number of components. In addition, the generation of sewage mist due to high-pressure water is also a major problem from a hygienic point of view, and the sand collection efficiency also has the disadvantage that a part of the sand sinks and floats underwater, and then sinks and accumulates again. . Therefore, in order to solve these problems, sand collection and pumping sand in a dry (drainage) state, and sand collection that ejects pressure water from a nozzle at a low pressure are desired.

Therefore, first, after the drainage pump 31 is stopped, as described above, pressure water is jetted from the nozzles 20a and 20b to the sand that has settled near the suction port 11 of the sand pump 10 of the present invention, and is disturbed for a certain period of time. Then, the sand pump 10 is operated to drain the accumulated water below the level L. It is preferable to use water pumped up by the staying water pump 32 for the nozzles 20a and 20b at this time. And if it drains to the predetermined water level in the pump pit 2, the operation of the sand pump 10 is stopped. Here, the predetermined water level is a water level that realizes a dry (drainage) state in the sand basin 1 and is ideally the level of the suction port 11. However, as long as the sand pump 10 does not require high load or high pressure sand collection, some stagnation of rainwater is allowed, and the center extending through the pump pit 2 in the inflow-outflow direction of the sand basin 1 is allowed. The bottom level of the trough 1b may be used. For example, it may be the bottom level X of the opening end to the pump pit 2.

Next, the sand deposited on the central trough 1b is guided into the pump pit 2 and sprayed by a sand collecting nozzle 40 from which pressure fluid is ejected in the extending direction of the central trough 1b in order to clean the central trough 1b. The central trough 1b is the final and main trough connected to the pump pit 2, and is therefore intended to prevent burial due to sedimentation when rainwater is received.

And thereafter, sand collecting nozzles 41, 41,... For ejecting pressure fluid in a direction orthogonal to the extending direction of the central trough 1b provided between the plurality of small troughs 1c orthogonal to the central trough 1b. By alternately ejecting the sand collecting nozzles 40, 40, sand collection to the pump pit 2 is performed via the small trough 1c and the central trough 1b. The sand basin is appropriately divided into a plurality of areas depending on its size, and a plurality of sand collecting nozzles 41, 41,... Are performed in order from the side closer to the pump pit 2.

Finally, Atsumarisuna sand deposited in the pond width direction of the sand basin near the pump pit 2 by Atsumarisuna nozzles 42, 42 to the pump pit 2, the grit separator (not shown) together with the collecting sand water at Agesuna pump 10 It is sent and the sanding is completed.

As described above, in this embodiment, the bottom surface of the precipitation sand pond is continuously provided via a connecting portion to the pump well of the sewage treatment facility, provided with a pump pit below the its connecting portions, the pump A nozzle is provided for jetting the pressure fluid so that the sand accumulated on the bottom face flows out toward the pit, and the sand collected in the pump pit is sucked in with the water by the sand pump 10 and put into a predetermined place. A sand-pumping device to be transported is provided with drive control means for driving the sand-pumping pump before draining the nozzle and draining accumulated water such as rain water below the connecting portion. And the nozzle which injects pressure water to sand and disturbs near the suction port of the said suction means is provided.

(A) is sectional drawing when the sand raising apparatus which concerns on one embodiment of this invention is applied to a sand basin, (b) is the top view. FIG. 2 is a cross-sectional view taken along the line II in FIG. It is a flowchart which shows control operation. It is sectional drawing of the whole sand basin. It is a top view of the left side part of FIG.

1 rainwater settling basin (sedimentation basin)
2 pump pit 2a bottom
2b Pump pit slope
3 Axis of rotation of sand pump 10 Sand pump 11 Suction port 12 Discharge pipe 20a, 20b Nozzle 21a, 21b Supply pipe

Claims (2)

The sand precipitated settling basin rainwater settling basin or the like, in Agesuna apparatus by suction with water transport in place by Agesuna pump having a spiral blade provided in the pump pit,
The sand pump is provided in the pump pit so that the spiral blades are horizontally rotated, and a nozzle for injecting pressure water into the sand precipitated near the suction port of the sand pump to disturb the pump pit is provided on the pump pit side. A sand raising device provided substantially horizontally toward the suction port . 2. The sand raising apparatus according to claim 1 , wherein the jetting direction of the nozzle is directed toward a vortex outside the center of rotation of the spiral blade of the sand raising pump .