JP2004211385A - Water reservoir - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a water reservoir capable of securely storing rainwater with a necessary water level in a simple structure without separate water storage means. <P>SOLUTION: The water passage in a leader 10 for the rainwater from a roof 3 of a building 2 is opened/closed based on a predetermined water level by an opening/closing means 6 provided in the lower end 10a of the leader 10. The rainwater is stored in the leader 10 when its water level is lower than the predetermined water level and led to a drain 4 when it goes over. In this way, rainwater with a predetermined water level can be securely stored in the leader 10 in the simple constitution without a separate water reservoir means. The rainwater can be effectively used for car washing and water sprinkling to grasses and trees by extracting the stored rainwater by an extraction means 7. <P>COPYRIGHT: (C)2004,JPO&NCIPI

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to a water storage device for storing rainwater. In the present invention, the term “substantially vertical” includes vertical, the term “substantially vertical” includes vertical, and the term “substantially parallel” includes parallel.
[0002]
[Prior art]
In the first prior art water storage device, a water storage tank is provided below the call gutter. The call gutter and the water storage tank are connected by a guide frame including an annular support ring and three shafts. Rainwater is guided from the drain gutter to the water storage tank and stored. A net provided with a light-shielding plate is provided at an upper end portion of the water storage tank (for example, see Patent Document 1).
[0003]
In the water storage device of the second prior art, a water storage tank is provided below the call gutter, similarly to the water storage device of the first prior art. The lower end of the water storage tank is fixed by the foundation of the building, and the side is fixed by the outer wall of the building. The water storage tank is provided with a water pipe, a drain pipe, and an overflow pipe. Rainwater in the water storage tank is taken in by a water pipe. Turbid water in the water storage tank is discharged by a drain pipe. Excess rainwater exceeding the amount of water that can be stored in the water storage tank is discharged by the overflow pipe. The drain pipe is provided with opening / closing means such as a valve, and the user operates the opening / closing means to discharge turbid water and perform maintenance in the water storage tank (for example, see Patent Document 2).
[0004]
In the third prior art water storage device, instead of the water storage tank of the second prior art water storage device being fixed at the outer wall of the building, the call gutter and the water storage tank are fixed to each other by the guide frame. (For example, see Patent Document 3). In the fourth conventional water storage device, a plurality of water storage tanks are provided on the outer wall of the building in parallel with the horizontal direction. Excess rainwater exceeding the amount of water that can be stored in the water storage tank is guided to the drain by an overflow pipe. Further, the water storage tank is provided with a pipe for guiding the stored rainwater to the toilet tank and a pipe for cleaning the inside of the water storage tank at the beginning of rainfall. The two pipes are provided with opening and closing means such as valves (for example, see Patent Document 4).
[0005]
In the fifth conventional water storage device, the water storage tank is separately provided outside the vertical gutter. Rainwater is guided from a vertical gutter to a water storage tank and stored. A water intake section, a wastewater section, and a water level gauge are provided outside the water storage tank. The rainwater stored is taken from the water intake section. The wastewater accumulated in the water storage tank is discharged from a wastewater part having a valve. The amount of stored rainwater is checked by a water level gauge. The wastewater is discharged by a user operating a valve, whereby maintenance in the water storage tank is performed. Further, the water storage tank is shielded from light (for example, see Patent Document 5 or 6).
[0006]
In the water storage device of the sixth prior art, a water storage tank is separately provided outside the vertical gutter. A valve device is provided in the vertical gutter. The water storage tank has a float mechanism that moves up and down in conjunction with the amount of rainwater stored in the water storage tank. The float mechanism has a float and a magnet. The float moves up and down according to the amount of water stored in the water storage tank. The magnet is provided to sandwich the side of the vertical gutter from inside and outside, and moves up and down along the side of the vertical gutter as the float moves up and down. The valve device in the vertical gutter is opened and closed by the magnet moving up and down along the side of the vertical gutter. As a result, rainwater is stored in the water storage tank and is guided from the vertical gutter to the drain. (For example, see Patent Document 7).
[0007]
[Patent Document 1]
JP-A-9-111815
[Patent Document 2]
JP-A-9-071980
[Patent Document 3]
JP 2002-054188 A
[Patent Document 4]
JP-A-2000-303509
[Patent Document 5]
JP 2001-279728 A
[Patent Document 6]
JP 2001-279729 A
[Patent Document 7]
JP-A-2002-266381
[0008]
[Problems to be solved by the invention]
In the above-described first to sixth conventional water storage devices, a water storage tank for storing water is provided separately from the gutter body, or a user operates a valve to open the storage tank, thereby removing sediment such as sludge. It is discharged outside the water storage tank. Thus, there is no idea to use the gutter for guiding rainwater from the roof of the building to the drainage channel as a means for storing rainwater, and it is possible to secure rainwater at a desired water level and automatically perform maintenance. The configuration is not possible. This causes problems such as an extra space for arranging the device and complicating the configuration, and also necessitates regular maintenance by the user, resulting in low maintainability. In addition, although we are trying to keep the rainwater in the water tank clean by shading the water tank or using nets, it may not be possible to suppress the growth of very fine things such as bacteria, and we may not be able to keep the rainwater long. It cannot be kept clean over time.
[0009]
An object of the present invention is to provide a water storage device that can reliably store rainwater of a required water level with a simple configuration without separately providing a means for storing water.
[0010]
[Means for Solving the Problems]
The present invention according to claim 1, a gutter having a vertical gutter having a vertical gutter for guiding rainwater received from a roof of a building to a drainage channel,
Opening / closing means that is provided at the lower end of the vertical gutter and that can be opened when the level of rainwater in the vertical gutter is equal to or higher than a predetermined set water level and closes a water channel in the vertical gutter,
A water storage device provided above the opening / closing means and including a water intake means for taking out rainwater from the vertical gutter.
[0011]
According to the present invention, the rainwater received from the roof of the building is guided to the drainage channel by the vertically extending gutter of the gutter body. Opening / closing means capable of opening and closing a water channel in the vertical gutter is provided at a lower end portion of the vertical gutter. This opening / closing means closes the water channel in the vertical gutter so that it can be opened when the level of rainwater in the vertical gutter reaches or exceeds a predetermined set water level. Above the opening / closing means, a water intake means is provided, and by this water intake means, rainwater in the vertical gutter is taken out. The rainwater received from the roof of the building is not guided to the drainage channel when the level of the rainwater in the vertical channel is less than a predetermined set water level because the water channel in the vertical channel is closed by the opening / closing means. It is stored inside. Thus, rainwater can be reliably stored in the vertical gutter until the water level reaches a desired level. Even when rainwater is guided to the vertical gutter for a long time, when the level of the rainwater in the vertical gutter exceeds the set water level, the opening / closing means opens the water channel in the vertical gutter, so that the rainwater flows from the vertical gutter. It is possible to prevent a problem such as overflow from occurring and to maintain a constant water level. Since rainwater is stored in the vertical gutter in this way, it is not necessary to provide a means for storing water, such as a tank, separately from the gutter body of the building, and it is not necessary to take extra space for arrangement. Furthermore, rainwater of a predetermined water level can be stored with a simple configuration in which only the opening and closing means is provided on the vertical gutter. Therefore, it is possible to reliably store rainwater at a required water level in a vertical gutter with a simple configuration without separately providing a means for storing water such as a tank. By taking out the stored rainwater by means of water, it can be effectively used, for example, for car washing and spraying on plants and trees.
[0012]
According to a second aspect of the present invention, when the level of the rainwater in the vertical gutter is equal to or higher than the set water level, the opening / closing means opens the water channel so that sediment can be discharged together with the rainwater in the vertical gutter. .
[0013]
According to the present invention, when the level of the rainwater in the vertical gutter is equal to or higher than the set water level, the opening / closing means opens the water channel so that sediment can be discharged together with the rainwater in the vertical gutter. As described above, by the opening operation of the water channel of the opening / closing means according to the level of rainwater in the vertical gutter, sediment such as sludge accumulated below the vertical gutter is automatically guided to the drainage channel together with rainwater. This makes it possible to automatically perform maintenance in the vertical gutter by using means for adjusting the level of rainwater in the vertical gutter without separately providing a special means for removing sediment. Therefore, the cost can be reduced, and maintenance by the user can be eliminated.
[0014]
The present invention according to claim 3 is characterized by further comprising a copper ion supply means for giving copper ions to rainwater in the vertical gutter.
[0015]
According to the present invention, the water storage device further includes a copper ion supply unit for supplying copper ions to rainwater in the vertical gutter. Thereby, even when rainwater in the vertical gutter is stored for a long period of time, algae and fungi can be killed by the copper ions by the copper ion supply means. Therefore, the rainwater in the vertical gutter can be maintained clean for a long period of time, and the maintainability of the water storage device can be further improved.
[0016]
In the present invention according to claim 4, the gutter body further includes a gutter that opens upward and receives rainwater from the roof of the building.
It is characterized by further comprising a temporary water storage means provided above the set water level and for temporarily storing rainwater.
[0017]
According to the present invention, the gutter body further has a gutter that opens upward and receives rainwater from the roof of the building. Rainwater from the roof of the building is guided to the vertical gutter via the gutter. Above the set water level, a temporary water storage means for temporarily storing rainwater is provided. For example, if a large amount of rain falls in a short time and rainwater with a flow rate larger than the flow rate that can be discharged by the opening and closing means is guided from the gutter, excess rainwater may overflow from the vertical gutter and eventually overflow from the gutter. There is. On the other hand, since the surplus rainwater is temporarily stored by the temporary storage means, it is possible to eliminate the problem that the rainwater overflows from the receiving gutter.
[0018]
BEST MODE FOR CARRYING OUT THE INVENTION
FIG. 1 is a sectional view schematically showing a water storage device 1 according to one embodiment of the present invention. FIG. 2 is a simplified cross-sectional view showing a building 2 provided with the water storage device 1. FIG. 3 is a side view showing the building 2 in a simplified manner. FIG. 4 is a diagram for explaining an operation when the water storage device 1 guides rainwater to a drain pipe. In the water storage device 1 shown in FIGS. 1 and 4, the thickness is partially omitted. The water storage device 1 is a device for storing rainwater. The water storage device 1 is provided in a building 2 such as a general house shown in FIGS. 2 and 3, for example. The roof 3 of the building 2 such as a general house is sloped so as to slope downward from one end 3a constituting the ridge toward the other end 3b. The building 2 has a side wall 11 arranged parallel to the vertical direction A and provided with a vertical gutter 10 described later.
[0019]
The rainwater received by the roof 3 flows from one end 3a of the roof 3 toward the other end 3b, and is guided to the water storage device 1 to be stored. The rainwater stored in the water storage device 1 is reused, for example, by washing the car, giving it to plants and trees, or flushing a toilet bowl. The water storage device 1 is connected to the drain 4 and discharges excess rainwater to the drain 4. The drainage channel 4 is configured to include a public drainage pipe 4a owned by a municipality or the like and a private drainage pipe 4b described later. The water storage device 1 is configured to include a gutter body 5, opening / closing means 6 and water intake means 7.
[0020]
The gutter 5 guides rainwater received from the roof 3 to a public drain pipe 4a. The gutter body 5 has a vertical gutter 10 provided substantially vertically. The vertical gutter 10 is formed in a bottomed cylindrical shape. In the present embodiment, the vertical gutter 10 has a circular cross section perpendicular to the axial direction. The vertical gutter 10 has its axis L10 arranged substantially vertically, and is provided along the side wall 11 of the building 2. In a state where the vertical gutter 10 is provided in the building 2, the vertical gutter 10 is arranged to extend over the ground surface 12 and near the upper end of the side wall 11. The vertical gutter 10 is provided, for example, near a corner formed by the plurality of side walls 11 of the building 2.
[0021]
The upright gutter 10 is provided in the building 2 and has a disk-shaped upright bottom 13 as a bottom at a lower end 10a, and is provided with an upper end 10b opened. A bottom through hole 13a is formed at the center of the bottom portion 13 of the standing gutter 10 at the center thereof. The bottom through-hole 13a is, for example, a circular shape having a peripheral portion along the axial direction and the circumferential direction, and penetrates along the axial direction. The bottom through hole 13a is formed, for example, to have an inner diameter of about 50 mm.
[0022]
The vertical gutter 10 is connected at its lower end 10a to a private drain pipe 4b. The private drain 4b is connected to the public drain 4a. The inner diameter of the private drainage pipe 4a is, for example, about 50 mm. When the water level of the rainwater in the vertical gutter 10 is equal to or higher than a predetermined set water level, the water storage device 1 discharges excess rainwater to the drainage channel 4. The water level of the rainwater in the vertical gutter 10 is the position of the water surface from the vertical gutter bottom 13. The set water level is set, for example, near the upper end 10b of the vertical gutter 10.
[0023]
The gutter body 5 further includes a temporary storage pipe 8 which is a temporary storage means. The temporary storage pipe 8 is provided above a position corresponding to the set water level, and temporarily stores rainwater. The temporary storage pipe 8 is formed in a substantially cylindrical shape with a bottom, and its axis L8 is provided on the upper end 10b of the vertical gutter 10 so as to be coaxial with the axis L10 of the vertical gutter 10. In the present embodiment, temporary storage tube 8 has a circular cross section perpendicular to its axis. The temporary storage pipe 8 is formed such that its inner diameter is larger than the inner diameter of the vertical gutter 10.
[0024]
The temporary storage pipe 8 is provided in the vertical gutter 10 and has a disk-shaped storage pipe bottom 9 as a bottom at a lower end 8a, and is provided with an upper end 8b opened. The storage tube bottom 9 has a storage tube through hole 9a formed at the center thereof. The storage tube through-hole 9 is, for example, a circular shape having a peripheral portion along the axial direction and the circumferential direction, and penetrates along the axial direction. The storage pipe through-hole 9 is formed so that the inner diameter thereof is smaller than the inner diameter of the vertical gutter 10.
[0025]
If rainwater with a flow rate larger than the flow rate that can be discharged from the vertical gutter bottom 13 is guided into the vertical gutter 10, there is a possibility that surplus rainwater will eventually overflow from the eaves gutter 14. By providing the temporary storage pipe 8, surplus rainwater is temporarily stored, so that the problem of overflow from the eaves gutter 14 can be eliminated.
[0026]
The gutter body 5 further has an eaves gutter 14 which is a receiving gutter. The eaves gutter 14 is provided to be open upward and receives rainwater from the roof 3. The eaves gutter 14 is formed substantially in a semi-cylindrical shape. The eaves gutter 14 faces the other end 3b of the roof in a state where it is open downward and upward, and a part of the eaves gutter in the circumferential direction is further away from the side wall 11 than the other end 3b of the roof 3. Be placed. Further, the eaves gutter 14 is provided substantially horizontally along the other end 3 b of the roof 3. When the temporary storage pipe 8 is not provided, the upright gutter 10 and the eaves gutter 14 may be directly connected to each other, or may be connected by, for example, a call gutter 15. When the temporary storage pipe 8 is provided, the vertical gutter 10 and the eaves gutter 14 may be connected by the temporary storage pipe 8 or may be connected by the temporary storage pipe 8 and the call gutter 15. In the present embodiment, the call gutter 15 connects the eaves gutter 14 and the temporary storage pipe 8. Rainwater is received from the roof 3 by the eaves gutter 14, and is guided from the eaves gutter 14 to the vertical gutter 10 via the call gutter 15 and the temporary storage pipe 8. Further, at least one of the temporary storage pipe 8 and the eaves gutter 14 is provided with a removing means such as a filter for removing insects and the like.
[0027]
The opening / closing means 6 is provided at a lower end 10 a of the vertical gutter 10. The opening / closing means 6 is specifically arranged in the vertical gutter 10 and is provided at the vertical gutter bottom 13 of the vertical gutter 10. The opening and closing means 6 opens and closes a water channel in the vertical gutter 10 according to the level of rainwater in the vertical gutter 10. When the water level of the rainwater in the vertical gutter 10 does not exceed the predetermined water level, the opening / closing means 6 closes the water channel in the vertical gutter 10 as shown in FIG. When the opening / closing means 6 closes the water channel in the vertical gutter 10, rainwater is stored in the vertical gutter 10. When the level of the rainwater in the vertical gutter 10 is equal to or higher than the set water level, the opening / closing means 6 opens the water channel in the vertical gutter 10 as shown in FIG. When the opening / closing means 6 opens the water channel in the vertical gutter, rainwater is guided to the drain channel 4 through the bottom through hole 13a.
[0028]
A sediment 16 such as mud, for example, has settled on the bottom 13 of the vertical gutter 10. The sediment 16 is discharged from the inside of the vertical gutter 10 together with rainwater when the opening / closing means 6 opens the water channel in the vertical gutter 10. In this way, the sediment 16 is discharged from the inside of the vertical gutter 10 with the rainwater discharging operation by the opening / closing means 6. This allows the sediment 16 to be automatically discharged without the user operating the opening / closing means 6 or providing any special means such as a drain pipe. Further, since the opening / closing means 6 is provided on the bottom 13 of the vertical gutter 10, the water pressure of the rainwater in the vertical gutter 10 is maximized as compared with the case where the opening / closing means 6 is provided on the side of the vertical gutter 10. , The precipitate 16 can be easily discharged.
[0029]
The opening / closing means 6 has a valve body 20 and a valve seat 21 which are arranged in the vertical gutter 10 in detail. The valve body 20 is provided so as to face the vertical gutter bottom 13 of the vertical gutter 10. The valve body 20 is provided so as to be displaceable with respect to the vertical gutter bottom 13. Specifically, the valve element 20 is provided so as to be angularly displaceable with respect to the upright bottom 13 around a valve element axis L20 parallel to the first horizontal direction B. The first horizontal direction B is one of predetermined horizontal directions perpendicular to the vertical direction A. The valve body 20 is angularly displaced with respect to the vertical bottom 13 of the vertical gutter 10 between a vertical channel closing position 22 for closing the vertical channel in the vertical gutter 10 and a horizontal channel opening position 23 for opening the vertical channel in the vertical gutter 10. . The waterway opening position 23 includes a waterway maximum opening position 23a where the valve element 20 is arranged at the most angular displacement from the waterway closing position 22.
[0030]
The valve body 20 has a base portion 20a abutting on the valve seat 21 and a connection portion 20b provided integrally with the base portion 20a. The base 20a is formed substantially in a disk shape. The base 20 a is provided with one convex surface on one side in the thickness direction facing the valve seat 21. The connecting portion 20b is provided to protrude radially outward from a part of the base 20a in the circumferential direction. A through-hole is formed in the connecting portion 20b so as to penetrate perpendicularly in the thickness direction and the radial direction of the base portion 20a. The through-hole of the connection part 20b is a circular shape having a peripheral portion along the axial direction and the circumferential direction.
[0031]
The valve body 20 is connected to the upright gutter bottom 13 by a valve body connecting portion 24 realized by, for example, a hinge. The valve body connecting portion 24 has a connecting portion 24a. The connecting portion 24a has a plate-like shape extending upward from the upright bottom 13 substantially in parallel with the axis L10 of the upright 10. A circular through hole penetrating in the thickness direction is formed at the upper end of the connecting portion 24a. In the present embodiment, another connecting portion (not shown) having the same configuration as the connecting portion 24a is provided at a position sandwiching the connecting portion 20b of the valve body 20. In the present embodiment, an arm connecting portion 25 having the same configuration as the valve body connecting portion 24 is provided on the vertical gutter bottom portion 13 at a position sandwiching the valve seat 21. In this manner, the valve body 20 is connected to the upright gutter bottom 13 by the valve body connecting portion 24 so as to be angularly displaceable around the valve body axis L20.
[0032]
The valve seat 21 is formed in a substantially cylindrical shape. The valve seat 21 has flexibility and elasticity. In the present embodiment, the valve seat 21 is formed such that the radial dimension is larger than the axial dimension. The inner diameter of the valve seat 21 is equal to or larger than the inner diameter of the bottom through hole 13a. The valve seat 21 is provided in the vertical gutter bottom portion 13 so as to expand, for example, downward. The valve seat 21 is provided in the vicinity of the periphery of the bottom through hole 13a over the entire circumference in the circumferential direction. At the water channel closing position 22, the valve seat 21 resiliently contacts the valve body 20 over the entire circumference in the one surface portion of the valve body 20. At this time, the valve body 20 is disposed substantially parallel to the vertical gutter bottom 13. At the water channel opening position 23, the valve seat 21 is angularly displaced in a direction in which the valve body 20 is separated from the valve seat 21, and the contact of the one surface portion with the valve body 20 over the entire circumference in the circumferential direction is released. .
[0033]
The water intake means 7 is a means for extracting rainwater from the vertical gutter 10, and is provided above the opening means 6. The water intake means 7 is provided on the outer periphery of the vertical gutter 10. The water intake means 7 has means such as a valve for opening and closing a water channel in the vertical gutter 10. By operating the valve, the rainwater stored can be effectively reused.
[0034]
The water storage device 1 is configured to further include an operation unit 30 and a copper ion supply unit 31. The operating means 30 is disposed in the vertical gutter 10 and operates the opening / closing means 6 to open and close a water channel in the vertical gutter 10. The operating means 30 includes a buoyant body 32, an arm 33, and a connecting cable 34. The buoyancy body 32 is displaced according to the level of rainwater in the vertical gutter 10. The buoyant body 32 is called a float, and is an object that floats on rainwater. For example, the buoyancy body 32 has a density lower than the density of rainwater.
[0035]
The buoyant body 32 has an axially intermediate portion 32a formed in a cylindrical shape. The outer diameter of the intermediate portion 32 a in the axial direction of the buoyant body 32 is formed to be substantially the same as the inner diameter of the through hole of the storage tube bottom 9. The buoyant body 32 is formed to have a tapered shape as both axial end portions 32b and 32c move toward both axial ends. The most protruding portions of both ends 32 b and 32 c in the axial direction are located at positions passing through the axis of the buoyant body 32. Specifically, the buoyant body 32 is formed in a hemispherical shape in which both ends 32b and 32c in the axial direction protrude toward both sides in the axial direction.
[0036]
The buoyant body 32 is held with the axial middle portion 32a fitted into the peripheral edge of the storage tube bottom 9 so that the buoyant body 32 is not completely dropped into the upright gutter 10 when the water channel in the upright gutter 10 is closed. You. In a state where the rainwater is held at the peripheral edge of the storage pipe bottom 9, the rainwater guided into the temporary storage pipe 8 enters the vertical gutter 10 by a through hole formed near the periphery of the through hole of the storage pipe bottom 9. Be guided. When the rainwater is guided into the temporary storage pipe 8 and the level of the rainwater in the temporary storage pipe 8 becomes equal to or higher than the buoyant body floating water level, the buoyant body 32 is displaced upward and separates from the storage pipe bottom 9. The buoyant body floating water level is determined when the buoyancy acting on the buoyant body 32 exceeds the downward force due to gravity acting on the buoyant body 32 in a state where rainwater is stored over the upright gutter 10 and the temporary storage pipe 8. Water level. When the buoyant body 32 is displaced upward, rainwater is guided through the through-hole of the storage pipe bottom 9 of the temporary storage pipe 8 into the gutter 10.
[0037]
As shown in FIG. 4, when rainwater is stored in the vertical gutter 10 and the temporary storage pipe 8, the buoyant body 32 is displaced upward and separates from the storage pipe bottom 9. At this time, with the displacement of the buoyant body 32, the valve body 20 is arranged at the channel opening position 23, so that the channel in the vertical gutter 10 is opened and the rainwater is guided to the drain channel 4.
[0038]
As the rainwater in the temporary storage pipe 8 is guided into the vertical gutter 10, the buoyant body 32 is displaced downward, and when the water level of the rainwater falls below the buoyancy water level, the buoyancy body 32 fits into the peripheral edge of the storage pipe bottom 9. Will be retained. As the buoyant body 32 repeats the above-described operation, rainwater in the temporary storage pipe 8 is guided into the vertical gutter 10. Since the lower end 32b in the axial direction of the buoyant body 32 is formed into a curved surface, even when the buoyant body 32 is fitted into the peripheral edge while being inclined with respect to the storage tube bottom 9, the buoyant body 32 is guided by the peripheral edge. The axial direction intermediate portion 32a can be firmly fitted by sliding while being moved.
[0039]
The arm 33 is provided on the bottom 13 of the vertical gutter. The arm portion 33 is provided so as to be displaceable with respect to the vertical gutter bottom portion 13 in accordance with the displacement of the buoyant body 32. The arm section 33 displaces the valve body 20 over the channel closed position 22 and the channel maximum open position 23 by being displaced. The arm 33 is provided so as to be angularly displaceable with respect to the vertical gutter bottom 13 around an arm axis L33 parallel to the valve element axis L20. The arm axis L33 is disposed above the valve element axis L20. The arm portion 33 is connected to the vertical gutter bottom portion 13 by the arm connecting portion 25. The arm connecting portion 25 holds the arm portion 33 so as to be angularly displaceable about the arm axis L33.
[0040]
The arm part 33 is formed substantially in a J-shape. The arm part 33 has a fulcrum part 33a, a power point part 33b and an action part 33c. The fulcrum portion 33a of the arm portion 33 is held by the arm connecting portion 25 near one end thereof so as to be angularly displaceable around the arm axis L33. The fulcrum part 33a is provided with a power point part 33b at one end and an action part 33c at the other end. The power point portion 33b and the action portion 33c are arranged substantially in parallel, and protrude from the fulcrum portion 33 toward the axis L10 of the vertical gutter 10. The force point portion 33b is disposed above the valve body 20. The distal end portion of the force point portion 33b is formed in an annular shape penetrating in parallel with the valve body axis L20 and the arm axis L33. The action portion 33c is disposed between the vertical gutter bottom portion 13 and the valve body 20. The action portion 33c is displaced in a direction approaching and separating from the valve body 20 due to the angular displacement of the arm portion 33.
[0041]
The connecting cable 34 connects the buoyancy body 32 and the arm 33. One end 34a of the connecting cable 34 is connected to the buoyant body 32, and the other end 34b is connected to a power point 33b of the arm 33. The connecting cable 34 is made of, for example, nylon or polyethylene, and is as light as possible. The other end 33b of the connecting cable 34 is slidably connected along the circumferential direction of the distal end of the action portion 33c.
[0042]
Since the valve element 20 is provided at the bottom of the vertical gutter 13, the valve element 20 receives a large water pressure due to rainwater and is difficult to open and close. By configuring the buoyant body 32, the arm portion 33, and the connecting cable 34 as described above, the force based on the buoyancy acting on the buoyant body 32 is increased by the arm portion 33 utilizing the leverage principle, and the valve body Give to 20. Thus, the valve body 20 can be easily angularly displaced with a simple configuration.
[0043]
The copper ion supply means 31 supplies copper ions to rainwater in the vertical gutter 10. The copper ion supply means 31 is disposed in the upright gutter 10, connected to the upper end 10 b of the upright gutter 10, and extended to near the lower end 10 a of the upright gutter 10. The copper ion supply means 31 is realized by, for example, a cable plated with copper or the like. The copper ion supply means 31 may be realized by a cable made of copper. The cable has a configuration in which an annular ring piece including an oval and a perfect circle is a constituent unit, a plurality of ring pieces are connected to each other so as to be displaceable, and a unit member having a predetermined shape is displaceable to each other. Includes a connected link or a long link structure.
[0044]
When rainwater is stored in the vertical gutter 10 for a long period of time, for example, algae and fungi may propagate. By providing the copper ion supply means 31 in the vertical gutter 10, algae and fungi can be killed by the copper ions. Accordingly, even when rainwater is stored in the vertical gutter 10 for a long period of time, the user can keep the vertical gutter 10 clean without regularly cleaning the inside of the vertical gutter 10.
[0045]
Further, by providing the copper ion supply means 31 over the upper end 10b and the lower end 10a of the vertical gutter 10, copper ions can be efficiently provided to rainwater in the vertical gutter 10. Thus, the rainwater in the vertical gutter 10 can be surely kept clean. Therefore, the maintainability of the water storage device 1 can be reliably improved without forcing the user to perform maintenance. In addition, by configuring the copper ion supply means with a cord, the surface area in contact with rainwater can be increased. Thereby, copper ions can be reliably supplied to the rainwater in the vertical gutter 10.
[0046]
FIG. 5 is a diagram for explaining a state in which the valve body 20 is disposed at the water channel closing position 22. FIG. 6 is a view for explaining a state in which the valve body 20 is angularly displaced and is arranged at the water channel maximum open position 23. FIG. 7 is a diagram for explaining a state in which the valve body 20 is disposed at the water channel maximum open position 23. 5 to 7, the thickness is partially omitted. When the valve element 20 is disposed at the channel closing position 22 as shown in FIG. 5, the channel in the vertical gutter 10 is closed. At this time, the power point portion 33b and the action portion 33c of the arm portion 33 are arranged substantially parallel to the valve body 20. The action portion 33c has, for example, a contact portion 40 that is inclined downward toward the axis L10 of the vertical gutter 10. When the valve body 20 is angularly displaced toward the channel closing position 22 and the contact with the contact portion 40 is released, the contact portion 40 is disposed at the channel closing position 22. When the contact portion 40 of the action portion 33c is angularly displaced so as to angularly displace the valve body 20 toward the channel closing position 22, the contact portion with the valve body 20 receives a force received from the base 20a of the valve body 20. On the other hand, it is formed in a shape that is easy to slide. The contact portion 40 is separated from the valve body 20 when the valve body 20 is disposed at the water channel closing position 22.
[0047]
When rainwater is stored in the vertical gutter 10 and the water level of the rainwater rises, the buoyancy body 32 is displaced upward accordingly. With the upward displacement of the buoyancy body 32, the connecting cable 34 angularly displaces the arm 33 so that the arm 33 presses the valve body 20 from below. Although the arm portion 33 is angularly displaced, the contact portion 40 of the action portion 33b contacts the valve body 20 and presses the valve body 20 from below, but if the rainwater level does not exceed the set water level, rainwater The water pressure in the upright gutter 10 is not opened by the water pressure on the valve body 20.
[0048]
When the water level of the rainwater is equal to or higher than the set water level, the pressing force from the contact portion 40 of the action portion 33b becomes larger than the water pressure applied to the valve body 20, and the valve body 20 is angularly displaced in a direction approaching from the valve seat 21. I do. As a result, the contact between the valve body 20 and the valve seat 21 over the entire circumferential direction is released, so that the water channel in the vertical gutter 10 is opened, and as shown by an arrow 45 in FIG. It is discharged to the pipe 4b. At this time, the rainwater in the vicinity of the vertical gutter bottom 13 flows so as to be scooped up along the vertical gutter bottom 13 and the valve seat 21, and is discharged to the private drain pipe 4b. With the flow of the rainwater, sediment 16 such as mud that settles on the bottom of the vertical gutter 13 flows so as to be lifted along the bottom of the vertical gutter 13 and the valve seat 21, and flows into the private drain pipe 4 b together with the rainwater. Is discharged. Thus, the sediment 16 is removed from the bottom of the vertical gutter 13 without remaining on the bottom of the vertical gutter 13.
[0049]
When the water level of the rainwater exceeds the set water level and the buoyancy body 32 is further displaced upward, the valve body 20 is pressed by the action portion 33c, and is arranged at the channel maximum open position 23a as shown in FIG. The arm 33 is provided with a regulating member 50 indicated by a virtual line in FIG. When the restricting member 50 is disposed at the water channel maximum open position 23a, the restricting member 50 contacts the inner peripheral portion of the vertical gutter 10 to restrict the angular displacement of the arm 33. Thus, the arm 33 is angularly displaced so that the valve body 20 is angularly displaced beyond the water channel maximum open position with the rise of the water level of the rainwater. It is possible to solve the problem that the operation cannot be performed.
[0050]
When the amount of rainwater required for discharging from the inside of the vertical gutter 10 is discharged, the contact portion 40 of the action portion 33c is displaced in a direction away from the valve body with the downward displacement of the buoyant body 32. Accordingly, the valve body 20 is angularly displaced toward the water channel closing position 22 and is disposed at the water channel closing position 22 when the contact with the contact portion 40 is released. Since the contact portion 40 of the action portion 33c is provided so as to be inclined away from the valve body 20, the valve body 20 is promptly arranged at the channel closing position 22 when closing the channel in the vertical gutter 10. You. This prevents the rainwater in the vertical gutter 10 from being discharged more than necessary, and can store rainwater at a desired water level in the vertical gutter 10. In addition, since the water pressure due to the rainwater in the vertical gutter 10 is given along the vertical direction A, the load on the building 2 provided with the vertical gutter 10 can be reduced as much as possible.
[0051]
By using the opening / closing means 6 in cooperation with the operating means 30 suitably utilizing the principle of buoyancy and leverage, the opening / closing means 6 can be provided with a simple configuration without using a solenoid valve or the like which requires a power supply. Rainwater of the above water level can be stored in the vertical gutter 10. Further, with the opening operation of the water channel of the opening / closing means 6, the sediment 16 can be automatically guided to the drain channel 4 together with rainwater. This makes it possible to automatically perform maintenance in the vertical gutter 10 without separately providing a special means for removing the sediment 16 and without regular operation by the user. Therefore, the cost can be reduced, and maintenance by the user can be eliminated.
[0052]
FIG. 8 is a diagram for explaining an example of the dimensions of the water storage device 1. In FIG. 8, the thickness is partially omitted. In the example of FIG. 8, the vertical gutter 10 is formed such that the axial dimension D1 is 2 to 4 meters, the inner diameter D2 is 140 mm, and the inner diameter D3 of the bottom through hole 13a is 50 to 60 mm. You. In the present embodiment, the dimension D1 in the axial direction of the gutter 10 is 4 meters, and the inner diameter D3 of the bottom through hole 13a is 50 mm. The amount of water that can be stored by the vertical gutter 10 is about 15.4 liters / meter per one based on the above-described dimensions. Therefore, the 4m vertical gutter 10 can store about 61.6 liters of rainwater per line. In a building 2 (a two-story building) such as a general house, a plurality of standing gutters 10 are provided. For example, if there are four standing gutters 10, rain water of about 250 liters is provided by the four standing gutters 10. Can be stored. Since the amount of water required for washing the car is about 26.5 liters, it is possible to store sufficient rainwater for washing the car by using the plurality of vertical gutters 10. In addition, the surplus rainwater can be effectively used by spraying the plants and trees.
[0053]
For example, in Osaka Prefecture, in the month with the least rainfall, for example, in December, about 34 mm of rain falls per square meter. For example, assuming a building 2 having a floor area of 66 square meters (20 tsubo), 2244 liters of rain falls on the roof of this building 2. As described above, even at the time when the amount of rainfall is the smallest, rainfall necessary and sufficient for use in car washing is falling, and this rainwater can be stored in the standing gutter 10 in a necessary and sufficient manner. Providing the water storage device 1 in the building 2 in this manner is particularly effective in areas such as Okinawa where the amount of rainfall is small.
[0054]
When the above amount of rainwater is stored in the vertical gutter 10, a water pressure of about 7.8 kg is applied downward from the rainwater to the valve body 20, and about 2.8 kg is applied to the buoyancy body 32. Buoyancy is given upward. As described above, by utilizing this principle, an upward external force that is not sufficient only by buoyancy is increased by the operating means 30 and applied to the opening / closing means 6, thereby suitably performing the opening operation of the water channel in the vertical gutter 10. be able to. As a result, it is possible to reliably store rainwater in the vertical gutter 10 and to discharge the sediment 16 together with excess rainwater.
[0055]
The above embodiments are merely examples of the present invention, and the configuration may be changed within the scope of the invention. For example, the standing gutter 10 may have a rectangular tube shape in addition to a cylindrical shape. The valve seat 21 may be formed in a cylindrical shape, or may be formed in a mortar shape. Further, the copper ion supply means 31 may be formed in a cylindrical shape provided along the inner peripheral portion of the vertical gutter 10. Further, instead of the copper ion supply means 31, the valve element 20, the arm portion 33, the connecting cord 34, and the like may be copper-plated or the like to serve as the copper ion supply means. The contact portion 40 of the action portion 33c may have any shape as long as it is easy to slide with respect to the base portion 20a. For example, the cross-sectional shape perpendicular to the arm axis L33 may be formed in a hemispherical shape protruding toward the tip. , May be formed so as to be inclined in a direction approaching the power point portion 33b toward the front end. The axially intermediate portion 32 a of the buoyant body 32 may have an outer diameter smaller than the inner diameter of the through hole of the storage tube bottom 9.
[0056]
【The invention's effect】
According to the first aspect of the present invention, the rainwater received from the roof of the building is opened and closed by using the opening / closing means to open and close the water channel in the vertical gutter so that the rainwater in the vertical gutter does not exceed a predetermined set water level. The water can be reliably stored. This makes it possible to reliably store rainwater of a predetermined water level in a vertical gutter with a simple configuration without separately providing a means for storing water such as a tank. By taking out the stored rainwater by means of water, it can be effectively used, for example, for car washing and spraying on plants and trees.
[0057]
According to the second aspect of the present invention, when the level of the rainwater in the vertical gutter is equal to or higher than the set water level, the opening / closing means opens the water channel so that the sediment can be discharged together with the rainwater in the vertical gutter. In this manner, by opening the water channel of the opening / closing means according to the level of the rainwater in the vertical gutter, sediment such as sludge accumulated below the vertical gutter can be automatically guided to the drainage along with the rainwater. This makes it possible to automatically perform maintenance in the vertical gutter by using means for adjusting the level of rainwater in the vertical gutter without separately providing a special means for removing sediment. Therefore, the cost can be reduced, and maintenance by the user can be eliminated.
[0058]
According to the third aspect of the present invention, the water storage device further includes a copper ion supply means for supplying copper ions to rainwater in the vertical gutter. Thus, even when rainwater in the vertical gutter is stored for a long period of time, algae and fungi can be killed by the copper ion supply means. Therefore, the rainwater in the vertical gutter can be maintained clean for a long period of time, and the maintainability of the water storage device can be further improved.
[0059]
According to the present invention as set forth in claim 4, the gutter body further has a gutter that opens upward and receives rainwater from the roof of the building, and temporarily stores rainwater above the set water level. Temporary water storage means is provided. For example, if a large amount of rain falls in a short time and rainwater with a flow rate larger than the flow rate that can be discharged by the opening and closing means is guided from the gutter, excess rainwater may overflow from the vertical gutter and eventually overflow from the gutter. There is. On the other hand, since the surplus rainwater is temporarily stored by the temporary storage means, it is possible to eliminate the problem that the rainwater overflows from the receiving gutter.
[Brief description of the drawings]
FIG. 1 is a simplified sectional view showing a water storage device 1 according to an embodiment of the present invention.
FIG. 2 is a simplified sectional view showing a building 2 provided with the water storage device 1. FIG.
FIG. 3 is a side view showing the building 2 in a simplified manner.
FIG. 4 is a diagram for explaining an operation when the water storage device 1 guides rainwater to a drain pipe.
FIG. 5 is a view for explaining a state in which the valve body 20 is arranged at a water channel closing position 22.
FIG. 6 is a view for explaining a state in which the valve element 20 is angularly displaced toward a water channel maximum open position 23.
FIG. 7 is a view for explaining a state in which the valve body 20 is arranged at a water channel maximum open position 23.
FIG. 8 is a view for explaining an example of dimensions of the water storage device 1.
[Explanation of symbols]
1 Water storage device
2 Building
3 roof
4 drainage channel
5 gutter
6 Opening / closing means
7 Water intake means
8 Temporary storage pipe
10 Standing gutter
10a Lower end

Claims (4)

A gutter body that is provided substantially vertically and has a vertical gutter that guides rainwater received from a building roof to a drainage channel;
Opening / closing means that is provided at the lower end of the vertical gutter and that can be opened when the level of rainwater in the vertical gutter is equal to or higher than a predetermined set water level and closes a water channel in the vertical gutter,
A water intake device provided above the opening / closing means, and a water intake means for taking out rainwater in the vertical gutter. 2. The water storage device according to claim 1, wherein the opening / closing means opens the water channel so that sediment can be discharged together with the rainwater in the vertical gutter when the level of the rainwater in the vertical gutter is equal to or higher than the set water level. 3. 3. The water storage device according to claim 1, further comprising a copper ion supply unit for supplying copper ions to rainwater in the vertical gutter. The gutter body further has a gutter opening upward and receiving rainwater from the roof of the building,
The water storage device according to any one of claims 1 to 3, further comprising a temporary water storage means provided above the set water level to temporarily store rainwater.

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