JP2007107269A - Dust removing system - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a dust removing system capable of being constructed at low cost, capable of eliminating the clogging of a screen, and capable of effectively preventing dirt from re-adhering to the screen. <P>SOLUTION: This dust removing system comprises the screen 120 installed along the full width of a water tank 110 to arrest refuse, a jetting means (such as a jetting part 121) jetting at least one of air and water in the form of jet to remove the refuse adhered to the surface of the screen 120, and a discharge means (such as a discharge channel 130) for discharging the water and the refuse over the upper end of the wall of the water tank 110 when a water level in the water tank 110 exceeds a predetermined level. <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

  The present invention relates to a dust removal system for removing dust adhering to a screen provided in a water tank between a water source and a conduit communicating with a water turbine of a hydroelectric power generation facility.

  A water tank for supplying water to the water turbine of the hydroelectric power generation facility is provided with a screen for preventing dust from entering the water turbine of the hydroelectric power generation facility. By providing a screen, it is possible to prevent dust from entering the hydroelectric power generation facility. However, since dust adheres to the screen itself and clogging occurs, it is necessary to periodically remove dust attached to the screen. It was. Conventionally, dust attached to the screen was manually removed by a dust remover such as a rake dust remover or a net dust remover.

  However, there is a problem that a large amount of money is required to install a conventional dust remover. In addition, there is a problem that a large amount of labor costs and a lot of time are required to remove garbage manually, and when removing dust in the event of a disaster such as a typhoon, the arrival time will be due to the cutting of the road to the site. There was a problem that it was not possible to remove dust with priority given to emergency disaster recovery work.

  On the other hand, various types of dust removers for removing dust attached to a screen provided in a water tank for supplying water to a water turbine of a hydroelectric power generation facility have been proposed (see, for example, Patent Document 1). However, there is a problem that the dust remover itself is expensive because it is complicated, and that a large amount of money is required to install the dust remover.

JP 2004-50112 A

  In view of such circumstances, the present invention provides a dust removal system that can be constructed at low cost, can eliminate clogging of the screen, and can effectively prevent dust from reattaching to the screen. The issue is to provide.

  A first aspect of the present invention that solves the above problem is a dust removal system provided in a water tank between a water source and a conduit communicating with a water turbine of a hydroelectric power generation facility, and is provided over the entire width of the water tank. A screen that captures the air, and an injection means that is provided in the vicinity of the screen or in the screen itself, and injects at least one of air and water for removing dust adhering to the surface of the screen as a jet, and the water tank In the dust removal system, the apparatus includes a discharging unit for discharging water and the dust beyond the upper end surface of the water tank wall when the water exceeds a predetermined water level.

  In the first aspect, the dust removal system can be constructed at a low cost, the clogging of the screen can be eliminated, and the dust can be effectively prevented from reattaching to the screen.

  The second aspect of the present invention further comprises water level detection means provided on the upstream side and the downstream side of the water tank across the screen to detect the water level between the upstream side and the downstream side of the water tank. The first aspect according to the first aspect, wherein water intake to the water turbine is stopped and the injection unit is operated based on a water level difference between the upstream water level and the downstream water level detected by the detection unit. In the dust removal system.

  In the second aspect, clogging of the screen can be automatically eliminated, and dust can be effectively prevented from reattaching to the screen.

  The third aspect of the present invention further includes a curvature portion that is provided from the flow direction end of the downstream bottom of the water tank across the screen to generate a water flow in the water surface direction. The dust removal system according to any one of the first and second aspects.

  In the third aspect, it is possible to efficiently generate a water flow in the water surface direction.

  According to a fourth aspect of the present invention, in a dust removal system provided in a water tank between a water source and a conduit communicating with a water turbine of a hydroelectric power generation facility, a screen is provided across the entire width of the water tank to capture dust. A water level difference detecting step for detecting a water level difference between the upstream side and the downstream side of the water tank, a stopping step for stopping water intake to the water wheel when the water level difference exceeds a predetermined magnitude, and a vicinity of the screen or An ejection step of ejecting at least one of air or water as a jet from the ejection means provided on the screen itself to remove dust adhering to the surface of the screen and pushing the dust in the direction of the water surface, and the pushed up And a discharging step of discharging the waste beyond the upper end surface of the water tank wall.

  In the fourth aspect, clogging of the screen can be eliminated, and dust can be effectively prevented from reattaching to the screen.

  According to the present invention, the existing equipment can be constructed at low cost, the clogging of the screen can be eliminated, and the dust can be effectively prevented from reattaching to the screen. There is an effect that the cost for dust removal can be reduced.

  The best mode for carrying out the present invention will be described below with reference to the drawings. The description of the present embodiment is an exemplification, and the configuration of the present invention is not limited to the following description.

(Embodiment 1)
FIG. 1 is a schematic top view of a dust removal system according to Embodiment 1 of the present invention, and FIG. 2 is a cross-sectional view taken along the plane AA ′ shown in FIG.

  As shown in FIGS. 1 and 2, the dust removal system 100 according to the present embodiment includes a screen 120 that is provided over the entire width of the water tank 110 and captures dust, and is provided on the upstream surface of the screen 120. When the water in the water tank 110 exceeds a predetermined water level, the injection unit 121 is a part of the injection means that injects at least one of air or water as a jet to remove dust adhering to the surface. A drainage passage 130 that is a discharge means for discharging water and dust beyond the upper end surface of the wall, and is a part of the injection means and connected to the injection unit 121 to supply a jet to the injection unit 121 And a water level detecting means provided on the upstream side and the downstream side of the water tank 110 across the screen 120 for detecting the water level between the upstream side and the downstream side of the water tank 110. An upstream water level meter 150 and a downstream water level meter 151 and a mesh for preventing dust from flowing into the water tank 110 downstream of the screen 120 together with water provided from the entire width of the upper part of the screen 120 to the drainage channel 130. Hydroelectric power generation based on the difference in water level between the upstream water level detected by the upstream water level meter 150 and the downstream water level detected by the downstream water level meter 151. The pump 140 is actuated while stopping the water intake of the facility water turbine. In the present embodiment, the injection unit includes a part of the screen 120, the pump 140, and a jet supply pipe 141 that connects the pump 140 and the screen 120.

  The screen 120 is not particularly limited as long as the screen 120 is provided over the entire width of the water tank 110 and can capture dust such as driftwood contained in the water flowing through the water tank 110. Nor. In the present embodiment, the screen 120 has a plurality of tubular members 122 arranged in parallel at a predetermined interval, and both ends of the tubular members 122 are arranged in a horizontal direction perpendicular to the tubular member 122. It is fixed with members 123a and 123b. The horizontal tubular member 123a and the plurality of tubular members 122 are in communication with each other, and a jet flowing inside the horizontal tubular member 123a flows into the tubular member 122.

  The injection unit 121 is provided on the upstream surface of the tubular member 122 constituting the screen 120 and is at least one of air and water for removing dust adhering to the surface of the screen 120, that is, air, water, or these The structure and the like are not particularly limited as long as the mixture can be jetted as a jet. In the present embodiment, the ejection unit 121 opens on the upstream surface of the screen 120 so that dust attached to the surface of the screen 120 can be efficiently removed, but not only in the upstream direction but also in various directions. It may be open.

  The drainage channel 130 is not particularly limited in structure as long as the water in the water tank 110 can discharge water and dust beyond the upper end surface of the wall of the water tank 110 when the water in the water tank 110 exceeds a predetermined water level.

  The pump 140 is connected to the injection unit 121 through the jet supply pipe 141, the horizontal tubular member 123a, and the tubular member 122, and can supply at least one of air or water to the injection unit 121 as a jet. Although it will not specifically limit, what can supply what mixed air and water as a jet is preferable. When a mixture of air and water that can be supplied as a jet is used, dust attached to the surface of the screen 120 can be removed and the dust can be efficiently pushed up in the water surface direction.

  The upstream water level meter 150 and the downstream water level meter 151 can be provided in the upstream water tank 110 and the downstream water tank 110 of the screen 120, and the water level of the upstream water tank 110 and the downstream water tank 110 of the screen 120. Although it will not specifically limit if a water level can be measured, A float type water level meter is preferable. The upstream water level meter 150 and the downstream water level meter 151 are connected to a water intake control unit 190 that controls water intake to the pump 140 and a water turbine (not shown).

  The mesh member 170 is not particularly limited as long as it is provided from the entire width of the upper part of the screen 120 to the drainage channel 130 and can prevent dust and water from flowing into the water tank 110 on the downstream side of the screen 120. . However, in the present embodiment, a mesh member 170 having a shape through which the downstream water level meter 151 can pass is used. By using such a mesh member 170, the downstream water level according to the water level of the downstream water tank 110 with the screen 120 interposed therebetween is prevented while preventing dust from flowing into the downstream water tank 110 with the water. The total 151 can move up and down through the mesh member 170.

  In the present embodiment, a conduit 111 communicating with the water turbine of the hydroelectric power generation facility is provided below the drainage channel 130, and the conduit 111 is provided with an air valve 112 for taking air into the conduit 111.

  Next, operation | movement of the dust removal system 100 of this embodiment is demonstrated. When the water is supplied to the water tank 110, as shown in FIG. 3, the water passes through the screen 120 and flows into the conduit 111 communicating with the water turbine of the hydroelectric power generation facility. At this time, if dust such as driftwood is contained in the water, the dust is captured by the screen 120 and adheres to the surface of the screen 120. When the removal of dust by the screen 120 is continuously performed for a certain period, clogging due to a large amount of dust adhering to the surface of the screen 120 occurs, and the downstream side of the water tank 110 with the screen 120 interposed therebetween. Water will not flow easily.

  Then, as shown in FIG. 4, the water level rises on the upstream side of the water tank 110 across the screen 120, but the water level falls on the downstream side of the water tank 110. Therefore, a water level difference is generated between the upstream water level and the downstream water level of the water tank 110 with the screen 120 interposed therebetween. This water level difference can be obtained from the water level detected by the upstream water level meter 150 and the downstream water level meter 151.

  And when this water level difference becomes larger than a predetermined value, the hydroelectric generator is stopped first, and water intake is stopped. Then, since water does not flow into the conduit 111 communicating with the water turbine, the water level on the downstream side rises together with the water level on the upstream side of the water tank 110, and as shown in FIG. The water in the water tank 110 is discharged from the drainage channel 130.

  Next, the pump 140 shown in FIG. 1 is operated, and a mixture of air and water is supplied as a jet. A mixture of air and water supplied as a jet is provided on the surface of the screen 120 through the inside of the jet supply pipe 141, the horizontal tubular member 123 a, and the tubular member 122 that connect the pump 140 and the screen 120. Injected from the injection unit 121. Then, the dust 124 adhering to the surface of the screen 120 is removed from the surface of the screen 120 by a jet and pushed out toward the water surface above the screen 120. In this way, since the dust 124 attached to the surface of the screen 120 is removed, the clogging of the screen 120 can be eliminated. In addition, since the dust 124 removed by the mixture of air and water is efficiently pushed up toward the water surface above the screen 120, the dust 124 can be prevented from reattaching to the screen 120. .

  Then, the trash 124 pushed up in the direction of the water surface rides over the water tank and flows into the drainage channel 130, and is finally discharged to the spillway 160 together with water. In this way, it is possible to more effectively prevent the dust 124 attached to the screen 120 from reattaching to the screen 120. Note that the dust 124 discharged to the spillway 160 adheres to the surface of the spillway screen 161 provided in the spillway 160. If a large amount of dust adheres to the spillway screen 161, it becomes difficult for water to flow downstream of the spillway 160 across the spillway screen 161 as in the case of the screen 120. Even if the water level on the downstream side falls, there is no problem because it has no effect on the hydroelectric power generation equipment.

  On the other hand, when the clogging of the screen 120 is eliminated and all the garbage 124 is drained into the drainage channel 130 and the operation of the hydroelectric generator is started, the water on the upstream side of the water tank 110 easily passes through the screen 120. Therefore, the water level on the downstream side of the water tank 110 is lowered and the water level on the upstream side is lowered. Then, the water level on the upstream side of the water tank 110 becomes equal to the water level on the downstream side, and the screen 120 returns to the state before clogging. Therefore, water can be appropriately supplied to the turbine of the hydroelectric power generation facility. become able to. That is, the water that has flowed into the spillway 160 through the drainage channel 130 flows into the conduit 111 that communicates with the water turbine of the hydropower generation facility through the screen 120, and the wastewater drained water is passed to the hydropower generation facility. Since it can be supplied, resources can be used effectively.

  As described above, the dust removal system 100 of the present embodiment can be constructed at low cost by using existing equipment, can eliminate clogging of the screen 120, and dust adheres to the screen 120 again. Can be more effectively prevented.

(Embodiment 2)
6 is a schematic top view of the dust removal system according to the second embodiment of the present invention, and FIG. 7 is a cross-sectional view taken along the plane BB ′ shown in FIG.

  As shown in FIGS. 6 and 7, the dust removal system 100A of the present embodiment includes a screen 120A that is provided over the entire width of the water tank 110A and captures dust, and is provided on the upstream surface of the screen 120A. When the water in the water tank 110A exceeds a predetermined water level, the injection unit 121A, which is part of the injection means that injects at least one of air or water for removing dust adhering to the surface as a jet, and the water in the water tank 110A And a drainage channel 130A that is a discharge means for discharging water and dust beyond the upper end surface of the wall, and is a part of the injection means and connected to the injection unit 121A to supply a jet to the injection unit 121A A pump 140A, and an upstream side and a downstream side of the water tank 110A across the screen 120A. An upstream water level meter 150A and a downstream water level meter 151A that are water level detection means for detecting the position, and a curvature part that is provided across the wall surface from the flow direction end of the downstream bottom of the water tank 110A and generates a water flow in the water surface direction. 113, and the intake of water to the turbine is taken based on the water level difference between the upstream water level detected by the upstream water level meter 150A and the downstream water level detected by the downstream water level meter 151A. The pump 140A is operated while stopping. In this embodiment as well, the injection means includes a part of the screen 120A, the pump 140A, and the jet supply pipe 141A that connects the pump 140A and the screen 120A.

  The basic configuration is substantially the same as the dust removal system 100 of the first embodiment described above, but the dust removal system 100A of the present embodiment is a direction in which the drainage channel 130A intersects the drainage channel 130A instead of the longitudinal direction of the water tank 110A. And the point where the curvature portion 113 is provided is different. In the present embodiment, the same constituent elements as those in the first embodiment are indicated by the same numbers as those in the first embodiment with A added.

  The curvature 113 is particularly limited as long as the curvature 113 is provided across the wall surface from the flow direction end of the downstream bottom of the water tank 110A across the screen 120A and can generate a water flow in the water surface direction. Not. By providing the curvature part 113, the direction of the water flow from the water source flowing through the water tank 110A toward the conduit 111A can be efficiently changed depending on the water surface direction. When the water flow in the water surface direction reaches the water surface, as a result, a water flow from the conduit 111A toward the water source, that is, an inverted water flow can be generated.

  Next, operation | movement of 100 A of dust removal systems of this embodiment in this embodiment is demonstrated. When the water is supplied to the water tank 110A, as shown in FIG. 8, the water passes through the screen 120A and flows into the conduit 111A of the hydroelectric power generation facility. At that time, if dust such as driftwood is contained in the water, the dust of a predetermined size is captured by the screen 120A, and the dust adheres to the surface of the screen 120A. When the removal of dust by the screen 120A is continuously performed for a certain period, clogging due to a large amount of dust adhering to the surface of the screen 120A occurs, and the downstream side of the water tank 110A with the screen 120A interposed therebetween. Water will not flow easily.

  Then, as shown in FIG. 9, the water level rises on the upstream side of the water tank 110A across the screen 120A, but the water level falls on the downstream side of the water tank 110A. Therefore, a water level difference is generated between the upstream water level and the downstream water level of the water tank 110A across the screen 120A. This water level difference can be obtained from the water level detected by the upstream water level meter 150A and the downstream water level meter 151A.

  And when the water level difference becomes larger than a predetermined value, the hydroelectric generator is first stopped and water intake is stopped. Then, since water does not flow into the conduit 111A communicating with the water turbine, as shown in FIG. 10, the water level on the downstream side of the water tank 110A rises, an inverted water flow is generated, and a water tank overflow that flows into the drainage channel 130A is generated. . And the water in the water tank 110A is discharged | emitted from the drainage channel 130A by this reverse water flow and water tank overflow. At this time, part of the dust adhering to the surface of the screen 120A is also discharged from the water tank 110A by the reverse water flow and the water tank overflow.

  Next, a pump 140A (not shown) is operated, and a mixture of air and water is supplied as a jet from the pump 140A. Then, as in the first embodiment, the dust 124A adhering to the surface of the screen 120A due to the mixture of the air and water is removed from the surface of the screen 120A and pushed out toward the water surface above the screen 120A. . In this way, the dust 124A attached to the surface of the screen 120A is removed, so that the clogging of the screen 120A can be eliminated. Further, the dust 124A removed by the mixture of air and water is efficiently pushed up toward the water surface above the screen 120A, so that the dust 124A can be prevented from reattaching to the screen 120A. .

  Then, the dust 124A pushed up in the direction of the water surface rides on the reverse water flow and the overflow of the water tank, flows into the drainage channel 130A, and is finally discharged together with water into the spillway 160A shown in FIG. In this way, it is possible to more effectively prevent the dust 124A attached to the screen 120A from reattaching to the screen 120A. The dust 124 discharged to the spillway 160A adheres to the surface of the spillway screen 161A provided in the spillway 160A as in the first embodiment. If a large amount of dust adheres to the spillway screen 161A, it becomes difficult for water to flow downstream of the spillway 160A across the spillway screen 161A as in the case of the screen 120A. Even if the water level on the downstream side falls, there is no problem because it has no effect on the hydroelectric power generation equipment.

  On the other hand, when the clogging of the screen 120A is eliminated and all the garbage 124A is drained into the drainage channel 130A, when the operation of the hydroelectric generator is started, the water on the upstream side of the water tank 110A easily passes through the screen 120A. Therefore, the water level on the downstream side of the water tank 110A is lowered and the water level on the upstream side is lowered. Then, the water level on the upstream side of the water tank 110A becomes equal to the water level on the downstream side, and the screen 120A returns to the state before clogging. Therefore, water can be appropriately supplied to the water turbine of the hydroelectric power generation facility. become able to. That is, the water that has flowed into the spillway 160A through the drainage channel 130A flows into the conduit 111A that communicates with the water turbine of the hydroelectric power generation facility through the screen 120A, and wastefully drained water is supplied to the hydroelectric power generation facility. Since it can be supplied, resources can be used effectively.

  Thus, the dust removal system 100A of the present embodiment can also obtain the same effects as the dust removal system 100 of the first embodiment.

(Other embodiments)
In the first and second embodiments, the jets 121 and 121A are provided on the screens 120 and 120A themselves to remove dust adhering to the surface of the screen. However, the jets are provided in the vicinity of the screen, not on the screen itself. May be. Specifically, a tubular member having an opening in the vicinity of the downstream side of the screen is provided as an injection unit, and at least one of air and water for removing dust attached to the surface of the screen can be injected as a jet from the opening. You may do it. Even if it does in this way, the effect similar to Embodiment 1 and 2 is acquired.

  In the first and second embodiments, only one screen 120, 120A is used. For example, a screen having a wide interval separating the tubular members constituting the screen is arranged on the water source side, and the interval is arranged on the downstream side. A screen with a narrower interval may be arranged, and a screen with a smaller interval may be arranged downstream thereof. By using such a plurality of screens, dust contained in water can be removed more efficiently.

  In addition, in the dust removal system 100A of the second embodiment, when a sufficient reversal water flow is not generated, a reversal water flow generation means for causing the reversal water flow may be provided. Specifically, a water flow pump may be provided at the bottom on the downstream side of the water tank 110 </ b> A with the screen 120 </ b> A of the second embodiment interposed therebetween, and water may be ejected toward the curvature portion 113. When water is jetted in the direction of the curvature portion 113, the water is reflected by the curvature portion 113 to generate a stronger water flow in the water surface direction. When the water flow reaches the water surface, the water flow in the direction from the conduit 111A toward the water source results. Can generate strong reversal water flow. By adopting such a configuration, even if the water level on the downstream side of the screen 120A changes, a stronger reversal water flow can be generated near the water surface.

  Also, instead of stopping the operation of the hydroelectric generator, the output of the generator is throttled in the operating state to generate a tank overflow with surplus water and supply a jet to remove the dust adhering to the screen. May be. That is, by reducing the amount of water intake, the amount of water supplied to the water tank is made larger than the amount of water taken from the water tank, and surplus water is forcibly created. Then, the water adhering to the screen may be removed by generating a water tank overflow and supplying a jet.

  The present invention is applicable not only to a water tank for supplying water to a hydroelectric power generation facility but also to a water tank that needs to remove dust when taking water.

It is a schematic top view of the dust removal system of Embodiment 1 which concerns on this invention. It is A-A 'sectional view of the dust removal system of Embodiment 1 concerning the present invention. It is A-A 'sectional drawing in case dust does not adhere to the surface of the screen of the dust removal system of Embodiment 1 concerning the present invention. It is A-A 'sectional drawing in case dust adheres to the surface of the screen of the dust removal system of Embodiment 1 concerning the present invention. It is A-A 'sectional drawing in case a tank overflow occurs in the dust removal system of Embodiment 1 concerning the present invention. It is a schematic top view of the dust removal system of Embodiment 2 which concerns on this invention. It is B-B 'sectional drawing of the dust removal system of Embodiment 2 which concerns on this invention. It is B-B 'sectional drawing in case dust does not adhere to the surface of the screen of the dust removal system of Embodiment 2 concerning the present invention. It is B-B 'sectional drawing in case dust adheres to the surface of the screen of the dust removal system of Embodiment 2 concerning the present invention. It is a B-B 'sectional view in case a tank overflow occurs in the dust removal system of Embodiment 2 concerning the present invention.

Explanation of symbols

100, 100A Dust removal system 110, 110A Water tank 111, 111A Conduit 112, 112A Air valve 113 Curvature part 120, 120A Screen 121, 121A Injection part 122 Tubular member 123a, 123b Horizontal tubular member 124, 124A Garbage 130, 130A Drainage path 140, 140A Pump 141 Jet supply pipe 150, 150A Upstream water level meter 151, 151A Downstream water level meter 160, 160A Spillway 161, 161A Spillway screen 190, 190A Intake control unit

Claims (4)

A dust removal system provided in a water tank between a water source and a conduit communicating with a water turbine of a hydroelectric power generation facility,
A screen provided over the entire width of the aquarium for catching dust;
Injecting means for injecting at least one of air or water provided in the vicinity of the screen or in the screen itself to remove dust adhering to the surface of the screen as a jet,
A dust removal system comprising: a discharge means for discharging water and the dust beyond the upper end surface of the water tank wall when the water in the water tank exceeds a predetermined water level. Water level detecting means provided on the upstream side and downstream side of the water tank across the screen to detect the water level between the upstream side and the downstream side of the water tank, and further comprising the water tank of the water tank detected by the water level detection means 2. The dust removal system according to claim 1, wherein water intake to the water turbine is stopped and the injection unit is operated based on a water level difference between an upstream water level and a downstream water level. Either of the Claims 1 or 2 further provided with the curvature part which is provided over a wall surface from the flow direction edge part of the downstream bottom part of the said water tank on both sides of the said screen, and produces | generates the water flow of a water surface direction. The dust removal system described in 1. In a dust removal system provided in a water tank between a water source and a conduit communicating with a water turbine of a hydroelectric power generation facility,
A water level difference detection step for detecting a water level difference between the upstream side and the downstream side of the water tank with a screen for capturing dust disposed across the entire width of the water tank,
A stopping step of stopping water intake for the water wheel when the water level difference exceeds a predetermined magnitude;
An ejection step of ejecting at least one of air or water as a jet from the ejection means provided in the vicinity of the screen or in the screen itself to remove dust adhering to the surface of the screen and pushing the dust in the water surface direction; ,
And a discharging step of discharging the pushed up dust beyond the upper end surface of the wall of the water tank.

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