JPH0355655Y2 - - Google Patents

Description

[Detailed explanation of the invention] (a) Industrial application field The present invention relates to rainwater collection tanks, and is particularly applicable to various buildings such as houses, apartments, hotels, offices, department stores, shops, factories, and schools. It relates to a rainwater collection tank.

(b) Conventional technology In large buildings, rainwater storage tanks are installed in order to use high-quality rainwater from rooftops and roof surfaces as flushing water for flush toilets and the like.

However, rainwater contains suspended matter in the air.
Furthermore, dust and sand from water collection surfaces such as roofs are also included. This cannot be said uniformly depending on atmospheric and geographical conditions, but in general, this applies when the amount of rainfall is small, that is, in the case of minute rainwater, and in the case of initial rainwater when rainfall is more than minute rainwater, that is, in the case of initial rainwater. Since it is unsuitable for use due to the contamination caused by such dust and the like, it is used after removing the contamination caused by such initial rainwater, etc., or by excluding the initial rainwater, etc.

(c) Problems that the invention aims to solve However, as a method for removing dirt caused by such initial rainwater, etc., there is a method of letting the dirt settle naturally, but this method requires a large amount of cleaning cost, which is a problem. There is also a method of over-separating dirt by installing a filtration device, but this method increases construction costs and maintenance costs such as replacement of the over-layer, which is a problem.

Therefore, a method of installing a rain gauge on the rooftop or roof surface and not collecting water if the rainfall does not reach a certain amount has been adopted, but this method requires an expensive rain gauge and does not require human labor. This is problematic because it requires expensive peripheral devices such as automatic detection devices, and also requires a lot of time and effort for their installation and wiring work.

The present invention aims to solve the problems with these conventional devices.

(d) Means for solving the problem The present invention provides a small-sized rainwater collection tank that can collect high-quality rainwater by monitoring the amount of rainfall based on the water level according to the amount of inflowing rainfall. .

That is, the present invention has a first chamber and a second chamber that communicate with each other through a communication hole in the lower part and communicate with each other in the upper part, and a rainwater inlet is formed in the first chamber. A water level detector is arranged near the upper part of the communication hole formation position, and the second chamber is provided with an on-off valve at the bottom thereof, and a water sampling pipe extending from the outside into the room and having an opening at the upper end. The rainwater sampling tank is characterized in that a water level detector is arranged near the opening position of the water sampling pipe, and a counter and a timer are provided connected to the on-off valve.

In the present invention, a small-diameter communication hole is formed in the lower part of the first chamber and the second chamber to communicate with each other. This communication hole is designed to have a size that can exclude only rainwater smaller than micro rainwater, and is not limited to one.

The location shall be at a sufficient height so that it will not be easily buried by contaminants from initial rainwater. When there is a large amount of rainfall, rainwater accumulates in the first chamber because it cannot be treated by discharging water from the communication hole.

A water level detector is provided in the first chamber at a position where it can be detected that rainwater has started to accumulate, that is, above the communication hole formation position. This water level detector detects that the water level increases beyond this detection position and issues a command to close the on-off valve provided at the bottom of the second chamber.

In the second chamber, a water level detector is arranged at a position corresponding to the amount of initial rainwater to be discharged at one time to be removed multiple times. This detector detects an increase in the amount beyond the detection position, and sends a command to open the on-off valve provided at the lower part of the second chamber, and also sends a command to a timer or flow meter for closing the on-off valve. The on-off valve closing timer and flow meter operate to close the on-off valve when the amount of water flowing out from the on-off valve reaches a predetermined amount. However, after issuing this command, this detector will continue to operate until the next rainfall detection time.
Automatically stops working. Therefore, the water sampling pipe installed in the second chamber has its water sampling opening located above the water level detection position of the water level detector, and collects rainwater that can be collected in the second chamber. A siphon tube is formed to collect as much water as possible.

When the rain stops, the water level in the first chamber decreases, and eventually the water level in the first chamber moves downward as water is drawn from the siphon pipe in the second chamber, and then stops. Therefore, a water level detector with a timer is installed above the opening of the water sampling pipe, and the opening/closing valve of the second chamber is opened by not detecting an increase in the water level from this stop position even after a certain period of time has elapsed. is preferred.

The setting positions of these water level detectors in the present invention may be strictly determined, but since the initial amount of waste such as rainwater is generally determined roughly, any position that can achieve the purpose is sufficient, and teeth,
It means this purpose.

The signal from the water level detector may indicate the necessity of opening/closing the on-off valve by lighting, etc., or it may be sent via a signal line, etc., or by providing a relay circuit, timer, etc. You may also do so.

(E) Effect In this invention, a first chamber and a second chamber are provided which communicate with each other at the lower and upper portions, and a water level detector is placed in each chamber, and by detecting the water level of these water level detectors, the water storage Since the opening/closing operation of the drainage on/off valve in the second chamber is controlled, it is possible to detect when rainwater has started to be introduced, and to reliably remove minute rainwater and initial rainwater before water can be sampled.

Furthermore, since the rainwater sampling tank of the present invention is connected to an on-off valve and equipped with a counter, a timer, etc., the initial rainwater can be discharged in multiple batches.

Therefore, the rainwater sampling tank of the present invention can be downsized and save space by setting the initial number of times rainwater is discharged to an appropriate number. Moreover, the present invention can be applied to roof areas of various sizes even though the volume is constant, so it can be mass-produced and provided at a lower price. Further, in this way, the present invention can reliably separate and discharge initial rain water, so despite the small size and simple structure, water can be collected without waste and cleaning is easy.

(f) Examples Hereinafter, an example of an embodiment of the present invention will be described with reference to the accompanying drawings, but the present invention is not limited in any way by the following explanation and illustrations.

The figure is a schematic explanatory diagram showing an embodiment of the rainwater sampling tank of the present invention.

The rainwater sampling tank 1 is provided with a rainwater inlet 2, an overflow outlet 3, a drain 5 having an on-off valve 4, and a water sampling pipe 6 with a siphon pipe. The partition wall 7 has a through hole 8 formed in its lower part, and an overflow port 9 formed in its upper part. This partition wall 7 allows the tank 1 to
It is divided into a first chamber 10 and a second chamber 11. A first water level detector 12 is provided above the through hole 8, and a water sampling port 1 of the water sampling pipe 6 is provided above the partition wall 7.
A second water level detector 14 is provided between the position 3 and the overflow port 9. A third water level detector 15 is provided in the second chamber 11 at a position corresponding to the discharge amount of the initial rainwater that should be removed multiple times. In this example, the position of the third water level detector 15 is such that the initial amount of rainwater is, for example, 0.3 mm/m ² .
If the initial rainwater is discharged in three parts, for example, the volume corresponding to the discharge amount of the initial rainwater in one time, that is, for example, 2000m ² × 0.0001m, for example, for a rooftop area of 2000m ² . A third water level detector 15 is provided at a height corresponding to a volume of 0.2 m ³ .

In this example, the first water level detector 12, the second water level detector 14, and the third water level detector 15 include:
Display devices 16, 17 and 18 are connected to each other. The indicator 16 of the first water level detector indicates that rainwater has started flowing into the rainwater sampling tank 1 of this example, and the indicator 17 of the second water level detector
is connected to the timer 19, indicating that the water level in the first chamber 10 has fallen from the detection position of the second water level detector 14, and there is no new inflow of rainwater.
An indicator 18 connected to the third water level detector 15 indicates that the water level in the second chamber 11 is at the detection position of the third water level detector 15.

In addition, in this example, the on-off valve 4 is an electric motor,
It is connected to a power source 20 such as an air cylinder, and the switch 21 of the power source 20 is set to the open or closed side to open and close the on-off valve. In particular, a switch 24 serving as a timer 22 and a counter 23 is provided at the upper end of the valve body of the on-off valve 4, and it indicates the number of times the on-off valve 4 is opened, and also indicates the opening time of the on-off valve 4. It is becoming constant. The siphon pipe 25 connected to the water sampling pipe 6 is
The curved point 26 is formed to be located between the position of the third water level detector 15 and the position of the water sampling port 13 of the water sampling pipe 6, and the position of the water sampling port 27 of the siphon pipe is It is located at such a position that stagnation at the bottom of the chamber 11 can be avoided.

In this way, by providing the siphon pipe 25 in the water sampling pipe 6, the water sampling port of the water sampling pipe can be installed at a position far lower than the position of the water level detector and not affected by stagnation when collecting rainwater. , water will be collected without waste. Furthermore, the rainwater sampling tank 1 of this example is provided with an inspection lid 28 on the ceiling.

Since the rainwater sampling tank of this example is configured as described above, rainwater is collected, introduced into the first chamber 10 from the rainwater inlet, and stored. At this point, the on-off valve 4 of the drain port 5 is open.

The amount of rainwater in the first chamber 14 increases and flows out from the through hole 8 when it exceeds the through hole 8. In this example, the amount of rainwater flowing out from the through hole 8 is 2
mm/m ² hours or less. Rainwater flowing out from the through hole 8 is drained from the drain port 5. When there is a lot of rainfall, the water level in the first chamber 10 rises, and the first water level detector 12 near the upper part of the through hole 8
The water surface is detected and displayed on the display 16. By detecting the water level of the first water level detector, the switch 21 of the power source 20 is turned on to close the second chamber 1.
Close the on-off valve 4 of the drain port 5 of No. 1. Eventually, the water level in the first chamber rises, reaches the overflow port 9 of the partition wall 7, overflows the partition wall 7, and the rainwater flows into the second chamber 11. Rainwater flows into the second chamber from the first chamber 10 via the weir through hole 8 and overflow port 9, increases the water level, and when the rise in the water level is detected by the third water level detector 15, Based on the water level detection display by the indicator 18 of the water level detector 15, the switch 21 of the power source 20 is turned on to the open side, the on-off valve 4 of the drain port 5 of the second chamber 11 is opened, and the switch 24 is pushed.
The counter 23 counts and the timer 22 operates. The number of times the on-off valve 4 is opened due to the operation of the third water level detector 15 is counted by the counter 23, and when the opening and closing is repeated a predetermined number of times, for example, three times, the operation of the third water level detector 15 is stopped. and the second water level detector 14 is put into operation. Here, initial rainwater, in this example, a capacity of 0.3 mm/m ² , that is, 0.6 m ³ of rainwater is discharged from the drain port 5 . Closing of the on-off valve 4 at the end of draining is performed according to the indication on the timer 19. When the on-off valve 4 of the drain port 5 is closed, the rainwater introduced from the rainwater inlet 2 is
The water is stored in the second chamber 11 again, and the water level in the second chamber increases until it reaches the water sampling port 13 of the water sampling pipe 6.
Water is sampled. Since the operation of the third water level detector 15 has stopped, the third water level detector 15 does not operate at this water sampling stage.

When the rain stops and the introduction of rainwater from the rainwater inlet 2 is stopped, water sampling from the water sampling port 13 is stopped, but water sampling from the siphon pipe 25 is continued. As the water level in the second chamber decreases, the water level in the first chamber also decreases, and also decreases from the position of the second water level detector 14.
Therefore, the second water level detector 14 detects the drop in the water level and activates the timer 19. After waiting until a water level detection signal is not oscillated from the second water level detector 14 even after a certain period of time has elapsed, the timer displays a signal to open the on-off valve 4 of the drain port 5 of the second chamber. Here, the second water level detector 14 stops operating. In this way, rainwater can be collected without waste while checking the amount of precipitation by operating the water level detectors 12, 14, and 15 and removing minute rainwater and initial rainwater.

For convenience, the explanation of this example focuses on manual operation, but
Manual work associated with detection by the water level detector can be performed by forming a sequence circuit incorporating a relay circuit such as an electromagnetic relay or a non-contact relay.

(g) Effect of the invention In this invention, the inside of the tank is divided into a first and second chamber by a weir member having a through hole, a water level detector is arranged in each chamber, and the water level of these water level detectors is The detection signal of detection or water level movement is used to control the opening and closing of the drainage on-off valve in the second water storage chamber and to count the number of openings and closings. There is no need to install an expensive rain gauge. Moreover, the present invention can accommodate considerable fluctuations in the water collection area by changing the number of times the drainage on-off valve is opened and closed, so even if the volume of the rainwater collection tank is set to a size that allows for mass production, it is still possible. It is economical because it can respond to changes in the water catchment area. Moreover, in the present invention, since the initial number of times rainwater is discharged can be set to an appropriate number, the rainwater collection tank can be made smaller accordingly, and the installation area can be saved compared to conventional devices. Moreover, since the work is mainly performed by operating the on-off valve, automation using a relay circuit or the like becomes simple and easy.

The rainwater sampling tank of the present invention also functions as a sedimentation separation tank for removing impurities from initial rainwater, and its miniaturization can reduce area, construction costs, etc.

Furthermore, the present invention has a simple structure in which the inside of the tank is partitioned with a weir member and the water level detector and water sampling pipe with siphon pipe are placed at predetermined locations, making it easy to manufacture and easy to clean. Moreover, it is also excellent in that rainwater can be collected without waste and manufacturing and maintenance costs can be reduced.

[Brief explanation of the drawing]

The figure is a schematic explanatory diagram showing an embodiment of the rainwater sampling tank of the present invention. Regarding the symbols, 1 is the rainwater sampling tank, 2 is the rainwater inlet, 3 is the overflow outlet, 4 is the on-off valve, 5 is the drain, 6 is the water sampling pipe, 7 is the partition wall, 8 is the through hole, and 9 is the Overflow port, 10 is the first chamber, 11 is the second chamber, 12 is the first water level detector, 13 is the water sampling port of the water sampling pipe, 14 is the second water level detector, 15 is the third water level detector, 16, 1
7 and 18 are indicators, 19 and 22 are timers,
20 is a power source, 21 and 24 are switches, 23 is a counter, 25 is a siphon tube, 26 is a bending point, 27
is a water sampling port, and 28 is an inspection lid.

Claims (1)

[Scope of utility model registration request] It has a first chamber and a second chamber that communicate with each other through a communication hole in the lower part and communicate with each other in the upper part,
A rainwater inlet is formed in the first chamber, and
A water level detector is arranged near the upper part of the communication hole formation position, and the second chamber is provided with an on-off valve at its lower part and a water sampling pipe extending from the outside into the room and having an opening at the upper end. In addition, a water level detector is placed near the opening of the water sampling pipe.
A rainwater sampling tank characterized by being connected to an on-off valve and equipped with a counter and a timer.