JP2000017635A - Rotating screen and surface layer water intake equipment with float - Google Patents

Abstract

PROBLEM TO BE SOLVED: To permit smooth flowing of rubbish captured as bedload transport by a surface layer water intake equipment with rotating screen. SOLUTION: A surface layer water intake equipment 1 provided in a river is constituted with a water intake pipe 15, a water intake board 16 at the upper end of the water intake pipe 15, a float 17 above the water intake board 16 and a rotating screen 14 surrounding the water intake board 16 and the float 17. Then, the river water passed this rotating screen 14 is taken in through the intake board and intake pipe and sent to a predetermined place with a pump, but its rubbish is captured by the outer surface of the rotating screen 14 and sent as bedload transport by pressured water provided at inner and outer portions of the rotating screen 14. Then, the rubbish sent as bedload transport is discharged from a bedload transport outlet 7 with shielded screen 33 to the downstream of the river so that smooth bedload transport can be created without ingress of other rubbish in the river.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a float type surface water intake device with a rotating screen which is installed at a river mouth or the like.

[0002]

2. Description of the Related Art In general, a water intake tower is generally used as one of surface water intake devices, and this water intake tower is a facility provided separately from a main bank or a river bank of a dam. As the tower body, a concrete tower body, a pipe up / down sliding tower body, a pipe inclined tower body, and the like are known, and the structure of a water intake section provided in this tower body is a lifting tower. −
Known are a down gate, a double gate, a disk overflow type, a circular suction type (with a funnel-shaped intake plate).

In order to perform such surface water intake (also referred to as surface water intake), it is necessary for the water intake to follow the water level (for example, tide level) and to take surface water from a wide range. A tower (also referred to as a multi-stage cylinder gate type) is said to be preferable.

[0004] A surface water intake device using a pipe up / down sliding tower is described in, for example, Japanese Patent Application Laid-Open No. 5-272123 filed by one of the present applicants. In addition to providing a watertight packing between these adjacent intake pipes, the upper end of the upper intake pipe having the minimum diameter is an intake port composed of a drinking mouth (also referred to as a bell mouth), and the intake pipe for this intake port is provided. It is suspended on the float with a predetermined vertical interval, and therefore can be referred to as a floating pipe vertical type water intake device with a float.

[0005] On the other hand, the following proposals have been made for a device for collecting surface water having a difference in water level at lakes, marshes, river mouths and the like.

For example, according to Japanese Patent No. 2612509 filed by another applicant of the present invention, a sedimentation well opening facing the river surface, an intake well adjacent to the sedimentation well,
It consists of a pump well that takes water from this intake well and feeds it to a specified place. In this sand well, a coarse bar screen is provided at the main intake port facing the river surface, and coarse waste (this is simply called waste). In this well, the above-mentioned up-and-down slide type water intake device with a float is improved. In particular, the intake at the upper end of the intake pipe is a funnel-shaped intake plate. On the lower surface of the float, blades for rotating on the water intake plate are provided, and the float is rotated, and furthermore, substantially along the outer periphery of the float and the water intake plate, the vertical position follows the vertical movement of the float. A device surrounding a shaft-type rotary screen (a type of rotary screen whose rotation axis is set as a vertical axis) is provided.

[0007] Therefore, this device is an up-down sliding type water intake device (or a rotary screen and a pipe with a float).
It can be simply referred to as a rotary screen and a surface intake device with a float.

According to this device, fine dust (for example,
(It is also captured simply by a screen having a mesh width of 5 mm, which is also simply referred to as trash.) The water can be removed by removing the trash without manual processing. It has been.

A water pipe connected to a pump well is connected to the lowest part of the water intake pipe.
In order to discharge the trapped dust, the nozzle is provided with a cleaning nozzle which is provided inside and discharges pressure water, and sweeps the trapped dust by the pressure water. The garbage is discharged to the downstream side of the river via the discharge pit.

[0010]

However, it has been found that such a rotary screen and a pipe-sliding type water intake apparatus with a float have the following problems.

[0011] Dust trapped (adhered to the outer surface) by the rotating screen is discharged to the downstream side of the river and is caused to flow down by the flow of the river. , Including large trash trapped in the main intake on the upstream side, it tends to go underwater, especially underwater, from the swept port of the rotating screen, especially today. If the amount of various types of waste increases, it tends to flow from the sweep port to the intake well, and there is a possibility that the waste will be filled near the outer periphery of the rotating screen.

If the outer periphery of the rotary screen is filled with waste, the rotary screen is rotating integrally with the float, so that it consumes a large amount of power. Not only does this take-out of garbage require a lot of manpower, but also the rotary screen may become clogged, making it impossible to take in water.

[0013] In addition, in a vertical suction type water intake device with a rotary screen and a float disclosed in the aforementioned Japanese Patent No. 2612509, a funnel-shaped intake plate made of sheet metal which is stationary with respect to rotation is manufactured. An O-ring is interposed in the gap between the lower end of the rotating screen suspended from the can-made float to prevent intrusion of fine dust from the gap between the two.
Since the ring is a ring body having a uniform cross section, the effect of preventing dust from entering by the O-ring cannot be obtained unless this gap is adjusted accurately.

Further, the adjustment of the gap is difficult as a practical problem for the following reasons.

That is, the rotary screen is hung on a can-making technology float which is difficult to achieve high processing accuracy. On the other hand, the water intake plate requires a certain amount of sliding clearance due to the pipe vertical sliding type. Since the inclination of the intake plate must be allowed, it is impossible to easily adjust the gap between the rotary screen and the intake plate.

Accordingly, the present invention has as its main object to solve such a new problem, and has an additional object to easily apply the solution to an existing water intake device of the same type. Things.

[0017]

Means for Solving the Problems To achieve the above object, the gist of the present invention is as follows. 1) A surface intake device installed in an intake well is connected to a vertically movable intake pipe and an upper end of the intake pipe. And a rotatable float provided at a distance above the water intake plate and movable up and down integrally with the water intake plate depending on the water level. A vertical rotary screen which surrounds substantially the outer circumference and is rotatable and movable up and down integrally with the float;
In addition, in the surface water intake device provided with a scavenging port for discharging waste adhering to the outer surface of the rotary screen to the river side by pressurized water, the rotary screen is provided at the sweep port. A member that discharges litter adhering to the surface but prevents intrusion of litter from a river, and is provided with a member that is aligned with the water surface by following only the up and down movement of the float. A surface intake device with a rotary screen and a float; 2) a surface intake device installed in an intake well; an intake pipe movable up and down; an intake plate provided at an upper end of the intake pipe; A rotatable float which is provided above the water intake plate at an interval and moves up and down integrally with the water intake plate depending on the water level, and on the outer periphery of the float and on the upper surface on the outer peripheral side of the water intake plate; Vertical axis type rotation that can be installed and rotate integrally with the float and move up and down A brush or a bellows is provided between the water intake plate and the lower edge of the vertical rotary screen to prevent intrusion of waste, A rotary screen and a surface intake device with a float, characterized in that the machining precision of the intake plate is normal.

[0018]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS The present invention will be described in detail with reference to the embodiments shown in the accompanying drawings.

FIG. 1 is a partial cross-sectional detail view of an embodiment of the present invention, FIG. 2 is a front view of a main part of FIG. 1, and FIG.
1 is a cross-sectional view taken along arrows A to A, and FIG.
4 is a schematic view of FIG. 1, and FIG. 5 is a schematic plan view of the installation of FIG.

A surface water intake device according to an embodiment of the present invention, more specifically, a vertical suction type water intake device with a rotary screen and a float (a surface intake device with a rotary screen and a float) (1) ) Is installed in important rivers called first-class rivers. For example, it is installed at a scale of up to 30,000 m ³ / day and near the mouth of the river, and in accordance with high tide, draws fresh water on its surface to collect water. It is suitable for use as water.

First, the installation state of the rotary screen and a pipe vertical slide type water intake device (hereinafter simply referred to as an intake device) 1 with a float will be described with reference to FIG.

In FIG. 5, reference numeral 2 denotes an intake well in which the intake device 1 is installed, which is made of a concrete well body having a length of about 4 m.times.about 5 m and a height of about 6 m.

Reference numeral 3 denotes a sedimentation well constructed adjacent to the upstream side of the intake well 2 and has substantially the same capacity as the intake well 2.

Reference numeral 4 denotes a pump well constructed adjacent to the downstream side of the intake well 2 and has a slightly larger capacity than the intake well 2.

The sedimentation well 3, the intake well 2 and the pump well 4 are connected along the flow of the river 5 as indicated by the arrow.
It is usually covered to protect the typhoon even in the event of a typhoon, but the construction site is on the curved concave side of the river 5 and the flow path of the river is relatively steep, so that the river flow is stable. Roads are formed and sediment is less deposited on the riverbed, which is convenient for water intake.

In particular, the main intake port 6 of the sedimentation well 3 and the scavenging port 7 of the intake well 2 form this constructed riverbed 8 in a concave bank shape so that the flow of the river does not stay, and thus Is preventing the stagnation of

In FIG. 5, reference numerals 9 and 9 denote low embankments constructed in the river 5.

The main intake 6 of the settling well 3
A guide column 10 is erected in the center thereof, and a corner drop 11 and a coarse bar screen 12 are mounted to be vertically movable.

An overflow 13 is formed between the sedimentation well 3 and the intake well 2. Therefore, it is difficult for the fine dust and earth and sand that flow under the water to overflow. Further, the intake well 2 is provided with the sweeping port 7 for discharging fine dust attached to the outer surface of the rotary screen 14 facing the river surface of the river 5.

As described above, the river water that has flowed through the coarse bar screen 12 is subjected to sand deposition in the sand well 3, enters the intake well 2 through the overflow 13, and rotates in the rotary screen. Water is taken through the pump 14 and sent to the pump well 4 by gravity. Water is supplied from the pump well 4 as industrial or agricultural water through an appropriate conduit 4a.

The fine dust adhering to the outer surface of the rotary screen 14 is separated by the jet of the pressurized water taken from the bottom of the river and is swept toward the river surface from the sweep port 7. Therefore, when this water intake device 1 set is installed in a river, a timer that inputs the ebb and flow of the tide, for example, with the lid covered is provided.
Unattended operation enables stable water intake throughout the day and night.

Next, the water intake device 1 will be described. Mainly in FIGS. 1 and 4, reference numeral 15 denotes an up-down sliding type intake pipe, and a funnel-shaped intake plate 16 is fixed to an upper end thereof.
Guide rollers (not shown) are provided at four locations on the outer periphery of the water intake plate 16.
These guide rollers are guided by guide rail columns 27. A float 17 made of sheet metal (made by can-making technology) is provided above the water intake plate 16 at predetermined vertical intervals.
Are mounted so as to be retained and rotatable.

Therefore, the water intake board 16 and the water intake pipe 15 move up and down due to the vertical movement of the float 17 due to the water level, but the water intake board 16 and the water intake pipe 15 do not rotate even if the float 17 rotates.

The lower end of the water intake pipe 15 is erected in a water storage chamber 18 so as to be able to be pulled out, and the water storage chamber 18 communicates with the pump well 4 and the water guide pipe 4a through a water discharge pipe 19.

Next, the rotating device 20 of the float 17 will be described. A rotating shaft 21 is fixed to the center of the float 17, and a resin large gear 23 is fixed to the upper end side of the rotating shaft 21. The large gear 23 meshes with a small gear 24, and this small gear Reference numeral 24 denotes a water intake plate 1 which is stationary with respect to rotation.
6 is driven by an electric motor 26 attached to a portal bracket 25 erected on the outer periphery of 6.

Therefore, the float 17 is about 0.6
Low rotation at rpm. In addition, this portal type bracket 25
Is guided by guide rail columns 27, 27 and float 1
It moves up and down together with 7 and the intake plate 16. Therefore, the flow
The boat 17 and the water intake board 16 move up and down without tilting.

Next, the vertical rotary screen 14 is formed in a short cylindrical shape having an outer diameter of about 3.2 mφ, the cylindrical surface of which forms a screen, and the upper surface of which projects above water and is open. The lower surface is closed by a water intake plate 16. The mesh width of the screen is 5 mm with a V-shaped slit screen. The rotary screen 14 is suspended by cantilever brackets 28, 28 extending horizontally from the upper surface of the float 17.

Therefore, the rotary screen 14 is
It moves up and down and rotates integrally with the float 17. A washing nozzle 29 is provided upright between the outer peripheral surface of the float 17 and the inner peripheral surface of the rotary screen 14 toward the sweep port 7, and the pressurized water forms the rotary screen 14. The fine dust adhering to the outer surface is peeled off and swept to the sweeping port 7.

In particular, an assisting cleaning nozzle 29a facing upward and facing the sweep port 7 is provided outside the rotary screen 14 so as to forcibly sweep fine dust to the overflow window 35.

Here, in the water intake device 1 of the present embodiment, the water intake plate 16 which is stationary with respect to the rotation and the lower edge 14a of the rotating rotary screen 14 are disposed between the water intake plate 16 and the lower edge 14a of the rotating screen 14.
As shown in (B), the outer peripheral flange 16a of the water intake plate 16
The brush 30 is provided upright over the entire circumference.

That is, the outer periphery of the water intake plate 16 is extended horizontally to form an outer peripheral flange 16a, and a circular brush pedestal 32 is fixed on the outer peripheral flange 16a by a mounting screw 31. The brush 30 is planted. Therefore, additional construction can be performed on existing ones.

On the other hand, since the machining of the float 17 is based on the can-making technology, it is difficult to obtain such a high degree of accuracy, and the processing of the water intake plate 16 is also difficult to obtain such accuracy because of the sheet-metal welding technology. Further, since the water intake pipe 15 slides up and down, a sliding gap is required. Consequently, although the water intake pipe 15 is guided by the guide rail column 27, the water intake board 16 may be slightly inclined.

Therefore, the outer peripheral flange 16 of the water intake plate 16
It is inevitably difficult to adjust the gap between a and the lower edge 14a of the rotary screen 14. Therefore, even if the rotary screen 14 having a mesh width of 5 mm is provided, there is a risk that fine dust will enter through the gap between the two.

However, in the water intake device 1 of the present embodiment, the lower edge 14 of the rotary screen 14 is placed on the water intake plate 16.
Since the brush 30 is provided densely over the entire circumference below the portion where a overlaps, the machining accuracy is not particularly increased,
It is possible to prevent the entry of fine dust while maintaining the so-called tolerance / normal.

Of course, since the brush 30 is made of nylon or the like, the brush 30 is not only inexpensive but also can be easily added to the existing water intake device 1 without any particular change.
A bellows may be provided instead of the brush 30.

In the water intake device 1 of the present embodiment,
A shielding screen 33 as described below is provided in the rectangular sweeping port 7 so that dust from the river surface, particularly underwater, is prevented from flowing back to the well 2. In other words, the fine dust adhering to the outer surface of the rotating screen 14 is discharged to the river surface side of the river at the upper portion of the shielding screen 33 as follows, and at the same time, the backflow of the underwater waste from the river. Has been blocked.

That is, in FIG. 1, FIG. 2 and FIG. 3 (A), along the inner surface of the scavenging port 7 of the intake well 2 provided on the river surface side of the river, it is integrated with the float 7 and the like. A shielding screen 33 that only moves up and down is provided.
Reference numeral 3 denotes a screen main body 36 in which flat steel bars 34, 34... Are arranged side by side and a blind (shade) is formed by providing a gap smaller than the mesh width of the rotary screen 14. This screen body 36 is positioned substantially below the water surface of the sweep port 7,
The upper part thereof is formed as an overflow window 35.

Therefore, the fine dust caught by the rotary screen 14 is forcibly discharged through the overflow window 35 to the scavenging port 7 by the assisting cleaning nozzle 29a, and is discharged from the river surface of the river. The refuse is prevented from entering by the blind screen main body 36. The blind screen main body 36 is integrated with the float 7 and the like so as to follow only the vertical movement of the float 7.

Each bar 34 of the screen main body 36 is
The endless chain 37 is partially attached to the pair of left and right endless chains 37, 37 via an angle attachment 38 without extending over the entire length thereof. And the upper and lower sprockets 39 and 40 projecting from the inner surface of the intake well 2 above and below the sweep port 7.

The end of the endless chain 37 on the sweep port 7 side is guided by a chain guide frame 41 surrounding the sweep port 7 and moves up and down. The chain guide frame 41 is made of SUS or the like, and includes a pedestal plate 43 fixed to the inner wall surface of the intake well 2 with bolts 42, and a pedestal plate 43.
Guide rail 4 combined with a long angle material 44
5 and reinforcing ribs 46.

The endless chain 37 includes:
The tip of a chain fixing tower (connecting material) 47 erected on the portal bracket 25 is fixed, and the vertical movement of the portal bracket 25, that is, the vertical movement of the float 7 due to the water level, is performed. The endless chain 37 is rotated up and down to adjust the position of the upper end of the screen main body 36 to substantially coincide with the water surface.

Therefore, since it is flush with the water surface, the trapped waste can be easily swept, and the infiltration of the underwater waste can be prevented.
For example, the existing water intake device 1 can be added as an attachment. 1 and 2, reference numeral 48 denotes a chain tensioning device.

The water intake device according to the embodiment of the present invention comprises a sedimentation well 3 and an intake well 2 constructed along the flow of a river.
And the pump well 4, but the present invention can also be applied to sedimentation wells, intake wells and pump wells constructed substantially orthogonal to the flow of the river. In addition, it can be installed not only at the river mouth but also at the river itself.

Further, instead of the shielding screen 33,
It may be a member composed of a gutter formed slightly upward and a check valve-like screen located in the water.

Although the numerical values in this specification are desirable values, they do not limit the gist and technical scope of the present invention.

[0056]

According to the first aspect of the present invention, the debris adhering to the outer surface of the rotary screen and the vertical rotary screen in the surface water intake device with a float are discharged from the scavenging port to the river. When the water is forcibly discharged to the downstream side of the river by pressurized water, a shielding screen or the like is provided at this sweep port, so that intrusion of underwater or litter on the water surface from the river side can be prevented. Thus, the screen effect of the rotary screen can be maintained satisfactorily.
Waste that adheres to the river can be discharged to the downstream side of the river, and the treatment can be performed by natural flow without human intervention.

As a result, the surface water intake device can be operated steadily, and even in an intake well that is covered with a cover and is not normally visible, it is possible to take out water stably while leaving it unattended. Can be supplied.

In particular, since the shielding screen or the like is positioned so as to follow the floating position of the float at the sweep port, the flow of the contaminated waste, which is the discharge and intrusion of the waste, is subtly performed. By distributing, the effect of the rotating screen can be increased without manual operation.

According to the second aspect of the present invention, since a brush or a bellows is provided between the lower edge of the rotary screen and the water intake plate, when the rotary screen is rotated to obtain a screen effect, There is no intrusion of garbage from places other than the screen,
Not only can improve the quality of water, but also absorb the gap error (tolerance) between the rotary screen and the intake disk without particularly increasing the precision of machining technology for large floats and intake disks. Thus, an inexpensive float or intake plate can be provided, and in addition, it can be replaced or added to an existing one.

[Brief description of the drawings]

FIG. 1 is a partial cross-sectional overall detail view of an embodiment of the present invention.

FIG. 2 is a front view of a main part of FIG.

3A is a cross-sectional view taken along the line AA of FIG. 2, and FIG. 3B is a detailed view of another main part of FIG.

FIG. 4 is a schematic diagram of FIG. 1;

FIG. 5 is a schematic plan view of the installation of FIG. 1;

[Explanation of symbols]

DESCRIPTION OF SYMBOLS 1 ... Surface water intake device, 2 ... Intake well, 7 ... Scavenging port, 14 ... Rotary screen, 15 ... Intake pipe, 16 ... Intake board, 17 ... Float, 30 ... Brush, 33 ... Shielding screen

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[Procedure amendment]

[Submission date] June 4, 1999 (1999.6.4)

[Procedure amendment 1]

[Document name to be amended] Statement

[Correction target item name] Full text

[Correction method] Change

[Correction contents]

[Document Name] Statement

[Title of the Invention] Surface intake device with rotary screen and float

[Claims]

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a float type surface water intake device with a rotating screen which is installed at a river mouth or the like.

[0002]

2. Description of the Related Art In general, a water intake tower is generally used as one of surface water intake devices, and this water intake tower is a facility provided separately from a main bank or a river bank of a dam. As the tower body, a concrete tower body, a pipe up / down sliding tower body, a pipe inclined tower body, and the like are known, and the structure of a water intake section provided in this tower body is a lifting tower. −
Known are a down gate, a double gate, a disk overflow type, a circular suction type (with a funnel-shaped intake plate).

In order to perform such surface water intake (also referred to as surface water intake), it is necessary for the water intake to follow the water level (for example, tide level) and to take surface water from a wide range. A tower (also referred to as a multi-stage cylinder gate type) is said to be preferable.

[0004] A surface water intake device using a pipe up / down sliding tower is described in, for example, Japanese Patent Application Laid-Open No. 5-272123 filed by one of the present applicants. In addition to providing a watertight packing between these adjacent intake pipes, the upper end of the upper intake pipe having the minimum diameter is an intake port composed of a drinking mouth (also referred to as a bell mouth), and the intake pipe for this intake port is provided. It is suspended on the float with a predetermined vertical interval, and therefore can be referred to as a floating pipe vertical type water intake device with a float.

[0005] On the other hand, the following proposals have been made for a device for collecting surface water having a difference in water level at lakes, marshes, river mouths and the like.

For example, according to Japanese Patent No. 2612509 filed by another applicant of the present invention, a sedimentation well opening facing the river surface, an intake well adjacent to the sedimentation well,
It consists of a pump well that takes water from this intake well and feeds it to a specified place. In this sand well, a coarse bar screen is provided at the main intake port facing the river surface, and coarse waste (this is simply called waste). In this well, the above-mentioned up-and-down slide type water intake device with a float is improved. In particular, the intake at the upper end of the intake pipe is a funnel-shaped intake plate. On the lower surface of the float, blades for rotating on the water intake plate are provided, and the float is rotated, and furthermore, substantially along the outer periphery of the float and the water intake plate, the vertical position follows the vertical movement of the float. A device surrounding a shaft-type rotary screen (a type of rotary screen whose rotation axis is set as a vertical axis) is provided.

[0007] Therefore, this device is an up-down sliding type water intake device (or a rotary screen and a pipe with a float).
It can be simply referred to as a rotary screen and a surface intake device with a float.

According to this device, fine dust (for example,
(It is also captured simply by a screen having a mesh width of 5 mm, which is also simply referred to as trash.) The water can be removed by removing the trash without manual processing. It has been.

A water pipe connected to a pump well is connected to the lowest part of the water intake pipe.
In order to discharge the trapped dust, the nozzle is provided with a cleaning nozzle which is provided inside and discharges pressure water, and sweeps the trapped dust by the pressure water. The garbage is discharged to the downstream side of the river via the discharge pit.

[0010]

However, it has been found that such a rotary screen and a pipe-sliding type water intake apparatus with a float have the following problems.

[0011] Dust trapped (adhered to the outer surface) by the rotating screen is discharged to the downstream side of the river and is caused to flow down by the flow of the river. , Including large trash trapped in the main intake on the upstream side, it tends to go underwater, especially underwater, from the swept port of the rotating screen, especially today. If the amount of various types of waste increases, it tends to flow from the sweep port to the intake well, and there is a possibility that the waste will be filled near the outer periphery of the rotating screen.

If the outer periphery of the rotary screen is filled with waste, the rotary screen is rotating integrally with the float, so that it consumes a large amount of power. Not only does this take-out of garbage require a lot of manpower, but also the rotary screen may become clogged, making it impossible to take in water.

[0013] In addition, in a vertical suction type water intake device with a rotary screen and a float disclosed in the aforementioned Japanese Patent No. 2612509, a funnel-shaped intake plate made of sheet metal which is stationary with respect to rotation is manufactured. An O-ring is interposed in the gap between the lower end of the rotating screen suspended from the can-made float to prevent intrusion of fine dust from the gap between the two.
Since the ring is a ring body having a uniform cross section, the effect of preventing dust from entering by the O-ring cannot be obtained unless this gap is adjusted accurately.

Further, the adjustment of the gap is difficult as a practical problem for the following reasons.

That is, the rotary screen is hung on a can-making technology float which is difficult to achieve high processing accuracy. On the other hand, the water intake plate requires a certain amount of sliding clearance due to the pipe vertical sliding type. Since the inclination of the intake plate must be allowed, it is impossible to easily adjust the gap between the rotary screen and the intake plate.

Accordingly, the present invention has as its main object to solve such a new problem, and has an additional object to easily apply the solution to an existing water intake device of the same type. Things.

[0017]

Means for Solving the Problems To achieve the above object, the gist of the present invention is as follows. 1) A surface intake device installed in an intake well is connected to a vertically movable intake pipe and an upper end of the intake pipe. And a rotatable float provided at a distance above the water intake plate and movable up and down integrally with the water intake plate depending on the water level. A vertical rotary screen which surrounds substantially the outer circumference and is rotatable and movable up and down integrally with the float;
In addition, in the surface water intake device provided with a scavenging port for discharging waste adhering to the outer surface of the rotary screen to the river side by pressurized water, the rotary screen is provided at the sweep port. A member that discharges litter adhering to the surface but prevents intrusion of litter from a river, and is provided with a member that is aligned with the water surface by following only the up and down movement of the float. A rotary screen and a surface intake device with a float; and 2) the intake plate of claim 1 is an intake plate formed by sheet metal processing, and the float is a float formed by can making.
Between the intake plate and the lower edge of the vertical rotary screen,
There is provided a rotary screen and a surface intake device with a float provided with a brush or a bellows for reducing the processing accuracy of the float and the intake plate without increasing the processing accuracy and preventing intrusion of waste.

[0018]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS The present invention will be described in detail with reference to the embodiments shown in the accompanying drawings.

FIG. 1 is a partial cross-sectional detail view of an embodiment of the present invention, FIG. 2 is a front view of a main part of FIG. 1, and FIG.
1 is a cross-sectional view taken along arrows A to A, and FIG.
4 is a schematic view of FIG. 1, and FIG. 5 is a schematic plan view of the installation of FIG.

A surface water intake device according to an embodiment of the present invention, more specifically, a vertical suction type water intake device with a rotary screen and a float (a surface intake device with a rotary screen and a float) (1) ) Is installed in important rivers called first-class rivers. For example, it is installed at a scale of up to 30,000 m ³ / day and near the mouth of the river, and in accordance with high tide, draws fresh water on its surface to collect water. It is suitable for use as water.

First, the installation state of the rotary screen and a pipe vertical slide type water intake device (hereinafter simply referred to as an intake device) 1 with a float will be described with reference to FIG.

In FIG. 5, reference numeral 2 denotes an intake well in which the intake device 1 is installed, which is made of a concrete well body having a length of about 4 m.times.about 5 m and a height of about 6 m.

Reference numeral 3 denotes a sedimentation well constructed adjacent to the upstream side of the intake well 2 and has substantially the same capacity as the intake well 2.

Reference numeral 4 denotes a pump well constructed adjacent to the downstream side of the intake well 2 and has a slightly larger capacity than the intake well 2.

The sedimentation well 3, the intake well 2 and the pump well 4 are connected along the flow of the river 5 as indicated by the arrow.
It is usually covered to protect the typhoon even in the event of a typhoon, but the construction site is on the curved concave side of the river 5 and the flow path of the river is relatively steep, so that the river flow is stable. Roads are formed and sediment is less deposited on the riverbed, which is convenient for water intake. Instead, there is a high possibility that the debris will enter the sweep port 7.

In particular, the main intake port 6 of the sedimentation well 3 and the scavenging port 7 of the intake well 2 form this constructed riverbed 8 in a concave bank shape so that the flow of the river does not stay, and thus Is preventing the stagnation of

In FIG. 5, reference numerals 9 and 9 denote low embankments constructed in the river 5.

The main intake 6 of the settling well 3
A guide column 10 is erected in the center thereof, and a corner drop 11 and a coarse bar screen 12 are mounted to be vertically movable.

An overflow 13 is formed between the sedimentation well 3 and the intake well 2. Therefore, it is difficult for the fine dust and earth and sand that flow under the water to overflow. Further, the intake well 2 is provided with the sweeping port 7 for discharging fine dust attached to the outer surface of the rotary screen 14 facing the river surface of the river 5.

As described above, the river water that has flowed through the coarse bar screen 12 is subjected to sand deposition in the sand well 3, enters the intake well 2 through the overflow 13, and rotates in the rotary screen. Water is taken through the pump 14 and sent to the pump well 4 by gravity. Water is supplied from the pump well 4 as industrial or agricultural water through an appropriate conduit 4a.

The fine dust adhering to the outer surface of the rotary screen 14 is separated by the jet of the pressurized water taken from the bottom of the river and is swept toward the river surface from the sweep port 7. Therefore, when this water intake device 1 set is installed in a river, a timer that inputs the ebb and flow of the tide, for example, with the lid covered is provided.
Unattended operation enables stable water intake throughout the day and night.

Next, the water intake device 1 will be described. Mainly in FIGS. 1 and 4, reference numeral 15 denotes an up-down sliding type intake pipe, and a funnel-shaped intake plate 16 is fixed to an upper end thereof.
Guide rollers (not shown) are provided at four locations on the outer periphery of the water intake plate 16.
These guide rollers are guided by guide rail columns 27. A float 17 made of a steel plate (manufactured by canning technology) is provided above the water intake plate 16 at predetermined vertical intervals.
Are mounted so as to be retained and rotatable.

Therefore, the water intake board 16 and the water intake pipe 15 move up and down due to the vertical movement of the float 17 due to the water level, but the water intake board 16 and the water intake pipe 15 do not rotate even if the float 17 rotates.

The lower end of the water intake pipe 15 is erected in a water storage chamber 18 so as to be able to be pulled out, and the water storage chamber 18 communicates with the pump well 4 and the water guide pipe 4a through a water discharge pipe 19.

Next, the rotating device 20 of the float 17 will be described. A rotating shaft 21 is fixed to the center of the float 17, and a resin large gear 23 is fixed to the upper end side of the rotating shaft 21. The large gear 23 meshes with a small gear 24, and this small gear Reference numeral 24 denotes a water intake plate 1 which is stationary with respect to rotation.
6 is driven by an electric motor 26 attached to a portal bracket 25 erected on the outer periphery of 6.

Therefore, the float 17 is about 0.6
Low rotation at rpm. In addition, this portal type bracket 25
Is guided by guide rail columns 27, 27 and float 1
It moves up and down together with 7 and the intake plate 16. Therefore, the flow
The boat 17 and the water intake board 16 move up and down without tilting.

Next, the vertical rotary screen 14 is formed in a short cylindrical shape having an outer diameter of about 3.2 mφ, the cylindrical surface of which forms a screen, and the upper surface of which projects above water and is open. The lower surface is closed by a water intake plate 16. The mesh width of the screen is 5 mm with a V-shaped slit screen. The rotary screen 14 is suspended by cantilever brackets 28, 28 extending horizontally from the upper surface of the float 17.

Therefore, the rotary screen 14 is
It moves up and down and rotates integrally with the float 17. A washing nozzle 29 is provided upright between the outer peripheral surface of the float 17 and the inner peripheral surface of the rotary screen 14 toward the sweep port 7, and the pressurized water forms the rotary screen 14. The fine dust adhering to the outer surface is peeled off and swept to the sweeping port 7.

In particular, an assisting cleaning nozzle 29a facing upward and facing the sweep port 7 is provided outside the rotary screen 14 so as to forcibly sweep fine dust to the overflow window 35.

Here, in the water intake device 1 of the present embodiment, the water intake plate 16 which is stationary with respect to the rotation and the lower edge 14a of the rotating rotary screen 14 are disposed between the water intake plate 16 and the lower edge 14a of the rotating screen 14.
As shown in (B), the outer peripheral flange 16a of the water intake plate 16
The brush 30 is provided upright over the entire circumference.

That is, the outer periphery of the water intake plate 16 is extended horizontally to form an outer peripheral flange 16a, and a circular brush pedestal 32 is fixed on the outer peripheral flange 16a by a mounting screw 31. The brush 30 is planted. Therefore, additional construction can be performed on existing ones.

On the other hand, since the machining of the float 17 is based on the can-making technology, it is difficult to obtain such a high degree of accuracy, and the processing of the water intake plate 16 is also difficult to obtain such accuracy because of the sheet-metal welding technology. Further, since the water intake pipe 15 slides up and down, a sliding gap is required. Consequently, although the water intake pipe 15 is guided by the guide rail column 27, the water intake board 16 may be slightly inclined.

Therefore, the outer peripheral flange 16 of the water intake plate 16
It is inevitably difficult to adjust the gap between a and the lower edge 14a of the rotary screen 14. Therefore, even if the rotary screen 14 having a mesh width of 5 mm is provided, there is a risk that fine dust will enter through the gap between the two.

However, in the water intake device 1 of the present embodiment, the lower edge 14 of the rotary screen 14 is placed on the water intake plate 16.
Since the brush 30 is provided densely over the entire circumference below the portion where a overlaps, the machining accuracy is not particularly increased,
It is possible to prevent the entry of fine dust while maintaining the so-called tolerance / normal.

Of course, since the brush 30 made of nylon or the like is implanted, the brush is not only inexpensive, but also can be easily added to the existing water intake device 1 without any particular change.
A bellows may be provided instead of the brush 30.

In the water intake device 1 of the present embodiment,
A shielding screen 33 as described below is provided in the rectangular sweeping port 7 so that dust from the river surface, particularly underwater, is prevented from flowing back to the well 2. In other words, the fine dust adhering to the outer surface of the rotating screen 14 is discharged to the river surface side of the river at the upper portion of the shielding screen 33 as follows, and at the same time, the backflow of the underwater waste from the river. Has been blocked.

That is, in FIG. 1, FIG. 2 and FIG. 3 (A), along the inner surface of the scavenging port 7 of the intake well 2 provided on the river surface side of the river, it is integrated with the float 7 and the like. A shielding screen 33 that only moves up and down is provided.
Reference numeral 3 denotes a screen main body 36 in which flat steel bars 34, 34... Are arranged side by side and a blind (shade) is formed by providing a gap smaller than the mesh width of the rotary screen 14. This screen body 36 is positioned substantially below the water surface of the sweep port 7,
The upper part thereof is formed as an overflow window 35.

Therefore, the fine dust caught by the rotary screen 14 is forcibly discharged through the overflow window 35 to the scavenging port 7 by the assisting cleaning nozzle 29a, and is discharged from the river surface of the river. The refuse is prevented from entering by the blind screen main body 36. The blind screen main body 36 is integrated with the float 7 and the like so as to follow only the vertical movement of the float 7.

Each bar 34 of the screen main body 36 is
The endless chain 37 is partially attached to the pair of left and right endless chains 37, 37 via an angle attachment 38 without extending over the entire length thereof. And the upper and lower sprockets 39 and 40 projecting from the inner surface of the intake well 2 above and below the sweep port 7.

The end of the endless chain 37 on the sweep port 7 side is guided by a chain guide frame 41 surrounding the sweep port 7 and moves up and down. The chain guide frame 41 is made of SUS or the like, and includes a pedestal plate 43 fixed to the inner wall surface of the intake well 2 with bolts 42, and a pedestal plate 43.
Guide rail 4 combined with a long angle material 44
5 and reinforcing ribs 46.

The endless chain 37 includes:
The tip of a chain fixing tower (connecting material) 47 erected on the portal bracket 25 is fixed, and the vertical movement of the portal bracket 25, that is, the vertical movement of the float 7 due to the water level, is performed. The endless chain 37 is rotated up and down to adjust the position of the upper end of the screen main body 36 to substantially coincide with the water surface.

Therefore, since it is flush with the water surface, the trapped waste can be easily swept, and the infiltration of the underwater waste can be prevented.
For example, the existing water intake device 1 can be added as an attachment. 1 and 2, reference numeral 48 denotes a chain tensioning device.

The water intake device according to the embodiment of the present invention comprises a sedimentation well 3 and an intake well 2 constructed along the flow of a river.
And the pump well 4, but the present invention can also be applied to sedimentation wells, intake wells and pump wells constructed substantially orthogonal to the flow of the river. In addition, it can be installed not only at the river mouth but also at the river itself.

Further, instead of the shielding screen 33,
It may be a member composed of a gutter formed slightly upward and a check valve-like screen located in the water.

Although the numerical values in this specification are desirable values, they do not limit the gist and technical scope of the present invention.

[0056]

According to the first aspect of the present invention, the debris adhering to the outer surface of the rotary screen and the vertical rotary screen in the surface water intake device with a float are discharged from the scavenging port to the river. When the water is forcibly discharged to the downstream side of the river by pressurized water, a shielding screen or the like is provided at this sweep port, so that intrusion of underwater or litter on the water surface from the river side can be prevented. Thus, the screen effect of the rotary screen can be maintained satisfactorily.
Waste that adheres to the river can be discharged to the downstream side of the river, and the treatment can be performed by natural flow without human intervention.

As a result, the surface water intake device can be operated steadily, and even in an intake well that is covered with a cover and is not normally visible, it is possible to take out water stably while leaving it unattended. Can be supplied.

In particular, since the shielding screen and the like are positioned so as to follow the floating position of the float at the sweep port, the inconsistent flow of garbage such as discharge and intrusion of garbage is subtly performed. By distributing, the effect of the rotating screen can be increased without manual operation.

According to the second aspect of the present invention, since a brush or a bellows is provided between the lower edge of the rotary screen and the water intake plate, when the rotary screen is rotated to obtain a screen effect, There is no intrusion of garbage from places other than the screen,
Not only can improve the quality of water, but also absorb the gap error (tolerance) between the rotating screen and the intake plate without increasing the precision of machining technology for large floats and intake plates. Thus, an inexpensive float or intake plate can be provided, and in addition, it can be replaced or added to an existing one.

[Brief description of the drawings]

FIG. 1 is a partial cross-sectional overall detail view of an embodiment of the present invention.

FIG. 2 is a front view of a main part of FIG.

3A is a cross-sectional view taken along the line AA of FIG. 2, and FIG. 3B is a detailed view of another main part of FIG.

FIG. 4 is a schematic diagram of FIG. 1;

FIG. 5 is a schematic plan view of the installation of FIG. 1;

[Description of Signs] 1 ... Surface water intake device, 2 ... Water intake well, 7 ... Suction port, 14 ... Rotary screen, 15 ... Water intake pipe, 16 ... Water intake board, 17 ... Float, 30 ... Brush, 33 ... Shielding screen

Claims (2)

[Claims] A surface intake device installed in an intake well is provided with a vertically movable intake tube, an intake plate provided at an upper end of the intake tube, a space above the intake plate, and a water level. A rotatable flow that moves up and down integrally with the water intake
Around the float and the outer periphery of the float and the water intake plate;
A vertical rotary screen which is rotatable and movable up and down integrally with the float. In addition, the intake well is provided with a pressure on the waste adhering to the outer surface of the rotary screen. In a surface water intake device provided with a scavenging port for discharging to a river side by water, the scavenging port discharges litter attached to the rotating screen, but prevents intrusion of litter from the river, A rotary screen and a surface intake device with a float, provided with a member which is aligned with the water surface following only the vertical movement of the float. 2. A water intake apparatus installed in an intake well, comprising: an intake pipe movable up and down; an intake board provided at an upper end of the intake pipe; Rotatable flow that moves up and down integrally with the water intake
A vertical axis type rotary screen which is provided on the outer peripheral side of the water intake plate on the outer peripheral side of the float and which is rotatable and movable up and down integrally with the float; A brush or a bellows is provided between the water intake basin and the lower edge of the vertical rotary screen to prevent the intrusion of waste and to improve the machining accuracy of the float and the intake basin. A surface intake device with a rotary screen and a float, characterized in that: