JP2010090605A - Rainwater utilization system - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a rainwater utilization system for utilizing stored rainwater. <P>SOLUTION: A rainwater gully 17 is installed in the rainwater utilization system S. The gully is connected with: an inflow pipe 18 which the rainwater flows into; and an overflow pipe 23 which opens above the pipe top of the inflow pipe 18 for overflowing and discharging the stored rainwater. An intake pipe 31 for taking in the stored rainwater is connected to the rainwater gully 17, and a position L1 of the pipe top of the intake pipe 31 is arranged in such a manner as to be lower than the pipe bottom L2 of the inflow pipe 18. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention relates to a rainwater utilization system that stores and uses rainwater.

  In recent years, rapid urbanization has led to an increase in the area of pavement, so that rainwater does not soak into the ground and flows into the river all at once.

  For this reason, while urban floods occur, there are usually problems such as low river flow, poor water quality, and dry groundwater.

  It has also become clear that the decline in groundwater increases the risk of drought, losing moisture such as green spaces and roadside trees, raising the temperature and drying the ground, resulting in urban climate change. ing.

  In order to solve such problems, techniques for storing rainwater and techniques for infiltrating rainwater into the ground have been developed.

  For example, Patent Literature 1 discloses a residential rainwater storage system that can store rainwater by providing an overflow member in a rainwater mass located at the end of a residential land.

According to this configuration, since rainwater can be temporarily stored in the rainwater mass and the pipe, it is possible to suppress the occurrence of flood due to sudden increase in sewage facilities and rivers even during heavy rain.
JP 2006-63761 A

  However, in Patent Document 1 described above, means for draining the stored rainwater to the sewage facility has been proposed, but means for using the stored rainwater has not been proposed.

  Then, this invention aims at providing the rainwater utilization system for utilizing the stored rainwater.

  In order to achieve the above object, a rainwater utilization system according to the present invention is connected to an inflow pipe into which rainwater flows and drains the rainwater stored by opening upward from the top of the inflow pipe. A rainwater utilization system in which a rainwater mass having an overflow pipe is installed, wherein the rainwater mass is connected to an intake pipe for taking in the stored rainwater, and the position of the top of the intake pipe is It is arranged to be lower than the bottom of the inflow pipe.

  Moreover, it is preferable that the intake mass which can take in the rainwater stored by connecting with the said rainwater mass by the said intake pipe from the ground surface is provided in the vicinity of the place using rainwater.

  Furthermore, it is preferable that the intake pipe is provided with a gradient in which the stored rainwater flows down from the rainwater mass toward the intake mass.

  And it is preferable that the said intake mass is provided with the mud part which precipitates the turbidity mixed in rainwater.

  Further, it is preferable that the intake mass is provided with a reservoir section divided by a mesh member above the mud reservoir section, and water intake means is disposed in the reservoir section.

  Furthermore, it is preferable that a manual pump as a water intake means for taking in the stored rainwater is stored in the water intake mass.

  Thus, in the rainwater utilization system according to the present invention, the rainwater mass is connected to the intake pipe for taking in the stored rainwater, and the top position of the intake pipe is lower than the bottom of the inflow pipe. It is characterized by being arranged like this.

  Therefore, rainwater can be reliably taken in by the intake pipe arranged lower than the inflow pipe, and rainwater can be stored in the intake pipe.

  Also, near the place where rainwater is used, there is a water intake trough that can be connected to the rainwater mass by a water intake pipe and collected from the surface of the rainwater, so that rainwater can be easily used with simple equipment through the water intake mass. .

  Further, the intake pipe is provided with a gradient in which the stored rainwater flows from the rainwater mass to the intake mass, so that rainwater can be stored over substantially the entire length of the intake pipe.

  The intake mass is provided with a mud reservoir for precipitating turbidity mixed in the rainwater, so that it becomes possible to use the rainwater that has been removed and is in a clean state.

  In addition, the intake mass is provided with a reservoir section divided by a mesh member above the mud reservoir section, and the intake section is provided with intake means so that turbidity is removed and a clean state is obtained. It will be possible to take rainwater.

  Further, the intake mass stores a manual pump as an intake means for taking stored rainwater, so that the manual pump does not become an obstacle when a person or an object moves.

  The best mode for carrying out the present invention will be described below with reference to the drawings.

  First, the whole structure of the rainwater utilization system S of this invention is demonstrated using FIG.

  As shown in FIG. 2, the rainwater utilization system S according to the present invention has a roof 15 that receives rainwater in a housing land 14 of a house 13, and a vertical guide that leads to a rainwater mass 16 while preventing rainwater from falling on the roof 15. , A rainwater mass 16,... Located in the middle for receiving rainwater from the vertical rod 19, a pipe 18,... Connecting the rainwater mass 16,. The rainwater mass 17 connected to the most downstream side (terminal) close to the sewer main 22 is provided.

  In addition, a large-scale public rainwater mass 21 that collectively receives rainwater from a plurality of houses (not shown) is connected to the downstream side of the rainwater mass 17 located at the end via a pipe 23.

  Furthermore, a large-diameter sewer main 22 is connected to a further downstream side of the public rainwater mass 21 via a pipe 24 to guide rainwater to a sewage treatment facility, a river, or the like.

  Then, in the final rainwater mass 17 located downstream (terminal) in the residential land 14, as shown in FIGS. 2 and 3, a pipe 18 as an inflow pipe into which rainwater flows and a top of the pipe 18 are provided. A pipe 23 serving as an overflow pipe that drains the rainwater stored in the rainwater mass 17 by allowing it to open, and a water intake pipe 31 for taking in the stored rainwater so that it can be used. It is connected.

  The pipe 18 as the inflow pipe is formed in a long cylindrical shape as shown in FIG. 1, and packing rubber is provided in a circular hole provided at an intermediate position of the side surface of the main body of the cylindrical water container 17. It is inserted and fixed through.

  Moreover, the piping 23 as an overflow pipe is formed in a long cylindrical shape, as shown in FIG. 1, and is opposite to the circumferential direction of the piping 18 as an inflow pipe of the rainwater mass 17. It is inserted and fixed via a packing rubber in a circular hole provided at an intermediate position on the side surface.

  In addition, an elbow 174 is fitted to the tip of the pipe 23 that protrudes to the inside of the rainwater mass 17, and the elbow 174 has a cylindrical overflow port portion whose length can be adjusted according to the stored water level WL. 174a is fitted.

  And the intake pipe 31 of the rain water mass 17 of this Embodiment is formed in an elongate cylindrical shape, as shown in FIG. 1, The plane position orthogonal to the piping 18 and 23 in the side surface of the rain water mass 17 The pipe top position L1 is arranged so as to be lower than the pipe bottom position L2 of the pipe 18 as the inflow pipe.

  Further, as shown in FIG. 3, the intake pipe 31 is provided with a gradient along the arrangement direction (axial direction) so that the stored rainwater flows down naturally, A water intake mass 32 is connected.

  As shown in FIGS. 2, 3, and 4, the intake mass 32 is formed in an elongated cylindrical container shape, and is erected in the ground in the vicinity of the planter 34 for cultivating flowers in the residential land 14. Yes.

  Further, as shown in FIG. 4, the intake pipe 32 is connected to the intake pipe 31 for allowing rainwater to naturally flow down from the rainwater mass 17 at an intermediate position on the side surface. A mud reservoir 325 is provided at the bottom via a mesh member 324.

  Accordingly, a reservoir 326 is formed on the mesh member 324 so as to be separated from the mud reservoir 325 and store clean water. As will be described later, water intake means is disposed in the reservoir 326. Yes.

  Further, an upright pipe portion 331 of a manual pump 33 as a water intake means is inserted into the intake water mass 32, and the stored rain water is sucked up by the piston structure by moving up and down the handle portion 332 attached to the upper end. It is configured.

  Since the upright pipe portion 331 of the manual pump 33 has a small inner diameter and is inserted into the elongated intake water mass 32, the manual pump 33 is made to stand up even if there is no special structure for supporting.

  Therefore, when watering the flowers, the user raises the handle portion 332 of the manual pump 33 to suck up the rainwater and pump it into the water bottle 35, etc. The planter 34 can be sprinkled with water.

  As the water intake means, a retractable manual pump 33A as shown in FIGS. 5 (a) and 5 (b), a submersible pump 33B as shown in FIG. 6 (a), and a shallow as shown in FIG. 6 (b). A well pump 33C or the like can also be used.

  As shown in FIG. 5A, the retractable manual pump 33A has a lower suction pipe 322 fixed to a holding plate 321 fixed to the middle part of the main body, and a locking hole provided in the holding plate 321. And an upper suction pipe 323 that is locked.

  And when using, as shown in FIG.5 (b), the upper suction pipe 323 latched by the holding plate 321 is lifted, and a lower end is inserted in the insertion port of the upper end of the lower suction pipe 322. Use with self-supporting and fixing.

  The submersible pump 33 </ b> B is a waterproof pump that is installed in the water, and is placed on the mesh member 324 so as not to suck the turbidity accumulated in the mud reservoir 325. Has been.

  Similarly, the shallow well pump 33C is installed on land, and the suction port is arranged on the mesh member 324 so that the suspended matter accumulated in the mud reservoir 325 is not sucked. ing.

  Next, the effect | action of the rainwater utilization system S of this Embodiment is demonstrated.

  Thus, in the rainwater utilization system S of the present invention, the rainwater mass 17 is connected to the intake pipe 31 for taking in the stored rainwater, and the pipe top position L1 of the intake pipe 31 is a pipe as an inflow pipe. It is characterized by being arranged to be lower than 18 tube bottom positions L2.

  Therefore, rainwater can be reliably taken in by the intake pipe arranged lower than the pipe bottom position L <b> 2 of the pipe 18 as the inflow pipe, and rainwater can also be stored in the intake pipe 31.

  In other words, in the rainwater utilization system S, the overflow water pipe is opened above the inflow pipe in the rainwater mass 17 so that the rainwater can be stored in the pipe 18 as the inflow pipe, and the stored water level WL is maintained. .

  If the intake pipe 31 is positioned above the pipe 18 as the inflow pipe, the intake pipe 31 is first stored in the pipe 18 and cannot be stored in the intake pipe 31. As a result, rainwater is taken in. And can no longer be used.

  Therefore, by positioning the intake pipe 31 below the pipe 18 serving as the inflow pipe, the rainwater can be reliably stored in the intake pipe 31 so that the rainwater can be used reliably.

  In this case, by setting the top position L1 of the intake pipe 31 lower than the bottom position L2 of the pipe 18 as the inflow pipe, the intake pipe is not stored in the pipe 18 even when the water level is low. The rainwater can be efficiently stored in the interior 31.

  Further, near the place where rainwater is used, there is provided a water intake mass 32 that is connected to the rainwater mass 17 by the intake pipe 31 and can take in the stored rainwater from the ground surface. Rainwater is available.

  That is, if the intake mass 32 is close to the place where rainwater is used, it is not necessary to distribute rainwater for a long distance, so that the intake facility can be simplified as a manual pump 33 described later.

  Furthermore, since the intake pipe 32 of a predetermined length is arranged by arranging the intake mass 32 near the place where rainwater is used in this way, a portion that precipitates impurities and turbidity mixed in the rainwater There is also an effect that only clean water can be taken.

  In particular, by connecting the intake water mass 32 to the final rainwater mass 17 as in the present embodiment, the longer the path to intake water, the longer the length of the portion to be settled. it can.

  Further, the intake pipe 31 is provided with a gradient in which the stored rainwater flows from the rainwater mass 17 toward the intake mass 32, so that the rainwater can be stored over substantially the entire length of the intake pipe 31.

  In other words, if the intake pipe 31 has a downward slope with the rainwater mass 17 side upstream, rainwater is stored in order from the downstream intake mass 32, so that rainwater can be efficiently stored near the place where rainwater is used. become.

  In addition, in this case, even if there is no water distribution facility such as a pump, rainwater can be distributed to the place of use by natural flow.

  The intake mass 32 is provided with a mud reservoir 325 for precipitating the turbidity mixed in the rainwater, so that the rainwater that has been removed from the turbidity and becomes clean can be used.

  In particular, when the intake pipe 31 is provided with a gradient for allowing natural rain water to flow down as described above, when rainwater naturally flows down the intake pipe 31, By washing away turbidity with water, impurities and turbidity can be stored and removed in the mud reservoir 325.

  The intake mass 32 is provided with a reservoir 326 divided by a mesh member above the mud reservoir 325, and a manual pump 33 as an intake means is disposed in the reservoir 326, thereby It is possible to take in rainwater that has been removed and is in a clean state.

  In other words, the turbidity is generally heavier than water, so that it accumulates near the bottom of the intake mass 32. However, when water is taken in by a pump or the like without installing the mesh member 324, the suction port of the pump is located near the bottom. In order to do so, turbidity near the bottom will be sucked in.

  Therefore, by installing the mesh member 324, the pump suction port is kept away from the turbidity so that the turbidity collected near the bottom is not sucked, while the water momentum at the time of suction is weakened and only clean water is supplied. Can take water.

  In addition, if rainwater can be easily used in this way, the frequency of rainwater use will increase, the amount of drainage to the sewage facility in the case of combined sewerage will decrease, and the addition of treatment facilities will decrease.

  Furthermore, the retractable mass 32 stores a retractable manual pump 33A as a means for taking in stored rainwater, which may cause an obstacle to the manual pump 33A when a person or an object moves. Disappear.

  Thus, it can be said that storing the manual pump 33A is particularly effective in the vicinity of a place where rainwater is frequently used.

  Although the best embodiment of the present invention has been described in detail with reference to the drawings, the specific configuration is not limited to this embodiment, and design changes that do not depart from the gist of the present invention are possible. Are included in the present invention.

  For example, in the above-described embodiment, the case where only one intake pipe 31 is connected to the rainwater mass 17 is described. However, the present invention is not limited to this, and a plurality of intake pipes 31 are connected. May be.

  Moreover, although the said embodiment demonstrated the case where the fixed gradient was provided in the intake pipe 31, it is not limited to this, It may be provided substantially horizontally, rainwater mass If it is a downward slope as a whole as viewed from 17, a configuration having a reverse slope portion may be used.

  Furthermore, in the above-described embodiment, as an example of using rainwater, a case where water is applied to a flower planted in the planter 34 has been described. However, the present invention is not limited to this, and water is supplied to a flush toilet in an emergency such as an earthquake. It is also possible to use it for beverages by providing a filtration device.

It is sectional drawing explaining the structure of the rainwater mass with which the rainwater utilization system of the best embodiment of this invention is provided. It is a perspective view explaining the whole structure of the rainwater utilization system of the best embodiment of this invention. It is sectional drawing explaining the positional relationship of a rainwater utilization system. It is sectional drawing explaining the structure of a water intake mass and a water intake means. It is sectional drawing of the retractable manual pump as a water intake means. It is sectional drawing of a water intake means. (A) is a submersible pump, (b) is a shallow well pump.

Explanation of symbols

S Rainwater Utilization System WL Reservoir Level L1 Pipe Top Position L2 Pipe Bottom Position 16 Rainwater Mass 17 Rainwater Mass 174 Elbow 174a Overflow Port 18 Piping (Inflow Pipe)
23 Piping (overflow pipe)
31 Intake pipe 32 Intake mass 321 Holding plate 322 Lower suction pipe 323 Upper suction pipe 324 Mesh member 325 Mud reservoir 33 Manual pump (water intake means)
33A Manual pump (water intake means)
33B Submersible pump (intake means)
33C shallow well pump (intake means)
34 Planter

Claims (6)

A rainwater utilization system in which an inflow pipe into which rainwater flows is connected and a rainwater mass is installed that has an overflow pipe that opens and drains the stored rainwater that opens upward from the top of the inflow pipe. There,
The rainwater mass is connected to a water intake pipe for taking stored rainwater, and the top of the water intake pipe is arranged to be lower than the bottom of the inflow pipe. Rainwater utilization system.   2. The rainwater utilization system according to claim 1, wherein a water intake mass is provided near a place where rainwater is used so that rainwater connected to the rainwater mass through the intake pipe can be taken from the ground surface.   The rainwater utilization system according to claim 2, wherein the intake pipe is provided with a gradient in which the stored rainwater flows down from the rainwater mass toward the intake mass.   The rainwater utilization system according to claim 2 or 3, wherein the intake mass is provided with a mud reservoir for precipitating turbidity mixed in rainwater.   The rainwater utilization according to claim 4, wherein the intake mass is provided with a reservoir section divided by a mesh member above the mud reservoir, and water intake means is disposed in the reservoir section. system.   The rainwater utilization system according to any one of claims 2 to 5, wherein a manual pump as water intake means for taking in stored rainwater is stored in the water intake mass.

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