KR20150114105A - Rainwater catchment apparatus and rainwater recycling facility having the same - Google Patents

Abstract

The present invention provides a rainwater catchment device comprising: an expanding and contracting rainwater receptacle installed in a wall of a rooftop, configured to be able to expand outwards from the wall of the rooftop and contract in an opposite direction when rainwater is collected; and an expansion and contraction driving means to expand and contract the rainwater receptacle. Also the present invention provides a rainwater recycling facility including the rainwater catchment device.

Description

TECHNICAL FIELD [0001] The present invention relates to a water collecting apparatus and an excellent reuse apparatus including the water collecting apparatus and the water re-

The present invention relates to a water collecting apparatus for collecting rain (rainwater) and an apparatus for treating the rain water for reuse.

Water is one of the essential factors for man to survive and live. However, there is a shortage of water in the world as well as in Korea, and various water reuse schemes are suggested to solve this water shortage problem. In particular, reusing stormwater has been done for a long time by mankind, and it is not difficult to confirm reuse of stormwater in everyday life.

Collected stormwater can be reused as water when properly treated, but there is a lack of effective collection and treatment of stormwater at present. For example, in terms of the treatment of stormwater, various contaminants present in the atmosphere are washed away from stormwater and contained in the stormwater. Therefore, when stormwater stormwater can not be appropriately treated, it is difficult to reuse the storm water.

[Problem to be solved]

It is an object of the present invention to provide a water collecting device and an excellent reuse facility capable of effectively collecting rainwater (rainwater) and reusably collecting collected water.

The problems to be solved by the present invention are not limited thereto, and other matters which are not mentioned can be understood by those skilled in the art from the following description.

[MEANS FOR SOLVING PROBLEMS]

According to an embodiment of the present invention, there is provided a resilient storey comprising: a stretch-type stormwater receiver installed on a roof of a rooftop to gather stormwater and to be stretched outwardly from the rooftop wall and contracted in the opposite direction; And a water collecting device including stretching and driving means for stretching and shrinking the excellent receiving portion.

The superior receiver may be composed of a plurality of superior receiving segments coupled to each other by a telescopic method. One of the plurality of received segments may be a fixed segment mounted on the wall on the roof, and the remainder other than the fixed segment may be a movable segment movable in a direction in which the superior receiving unit is expanded and contracted.

Wherein the elongating and contracting drive unit comprises a stationary member and a movable member movably coupled to the stationary member along a longitudinal direction, the elongated and contractible drive unit including a forwardmost movable segment positioned at the foremost position when the stand is elongated, At least one stretchable member connected rotatably in the up-and-down direction and expanded and contracted in the rotation direction; And a transmission mechanism that transmits power of the driving source to the driving source and the elastic member to rotate the elastic member in the vertical direction.

The transmission mechanism includes a first operating wire connected to the elastic member and rotating the elastic member in the upward direction when pulled out; A second operating wire connected to the elastic member and rotating the elastic member in a downward direction when the elastic member is pulled; And a rotary drum rotated in both directions by the driving source and each of which is wound in a direction opposite to the first and second operating wires to pull the first operating wire or pull the second operating wire according to the rotating direction .

The water collecting apparatus according to an embodiment of the present invention includes a plurality of collecting panels arranged in a matrix structure on the bottom of the roof and collecting storms, the collecting panels being composed of a plate-shaped member and a leg member supporting the plate- And a trough disposed on the lower side between the plurality of the collecting panels to receive the storm that has been dropped and to transport the storm to a desired place. The stormwater receiver may be configured to provide a gathering storm on the collecting panel.

Each of the water collecting panels may further include a cover member disposed on the plate member and made of basalt to purify the water.

According to an embodiment of the present invention, there is provided an air conditioner comprising: a plurality of water collecting panels arranged in a matrix structure at the bottom of a roof and collecting rainwater; And a trough disposed below the plurality of water collecting panels and adapted to receive the falling rainwater and transport it to a desired place, wherein each of the water collecting panels comprises: a plate-shaped member; A leg member for supporting the plate member from below; And a cover member disposed on the plate member and composed of basalt to purify the rainwater.

According to an embodiment of the present invention, there is provided a water collecting apparatus comprising: And a stormwater treatment apparatus that receives stormwater from the water collecting apparatus and processes the stormwater. The stormwater treatment apparatus may be provided with an excellent reuse facility including a purification tank for receiving granular basalt and purifying storm water.

The stormwater treatment apparatus may further include a storage tank for storing stormwater from the water collecting device, and the purification tank may be purified by receiving stormwater from the storage tank.

The stormwater treatment apparatus may further include a flow generation device for forcibly flowing the storm stored in the storage tank.

The flow generating device includes: a water discharge pipe disposed inside the storage tank; And an underwater pump for supplying the water spray tube with the storages stored in the storage tank.

According to an embodiment of the present invention, a water collecting apparatus having the plurality of collecting panels and troughs; And a stormwater treatment apparatus that receives stormwater from the water collecting apparatus and processes the stormwater. The stormwater treatment apparatus may be provided with an excellent reuse facility including a purification tank for receiving granular basalt and purifying storm water.

Means for solving the problems will be more specifically and clarified through the embodiments, drawings, and the like described below. In addition, various solution means other than the above-mentioned solution means may be further proposed.

1 is a configuration diagram showing an excellent reuse facility according to an embodiment of the present invention.
Fig. 2 is a plan view showing the excellent reusing facility shown in Fig. 1. Fig.
Figs. 3 and 4 show the construction and operation of the abdominal support and stretching and driving means shown in Figs.
Fig. 5 is a perspective view showing the collecting panel and the trough shown in Figs. 1 and 2. Fig.
6 is a cross-sectional view showing the stormwater treatment apparatus shown in Fig.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, preferred embodiments of a reusing device including a water collecting device and a water collecting device according to the present invention will be described with reference to the accompanying drawings. For the sake of convenience of understanding, the size of element, the thickness of line, and the like in the drawings referred to for explaining the embodiment of the present invention may be exaggeratedly expressed. The terms used to describe the embodiments of the present invention are mainly defined in consideration of the functions of the present invention, and thus may be changed depending on the intentions and customs of the user and the operator. Therefore, the terminology should be interpreted based on the content of the present specification throughout.

An excellent reuse facility including a water collecting device according to an embodiment of the present invention is shown in Figs. As shown in the figure, the excellent reuse facility according to the embodiment of the present invention includes a water collecting device (refer to reference numerals 10, 20, 30 and 40) and a water collecting device (reference numerals 10, 20, 30, (Refer to reference numerals 50, 60 and 70) for treating the level of the water (tap water) by receiving the storm water collected from the water tank

As shown in Figs. 1 and 2, a water collecting device (see 10, 20, 30 and 40) is installed on the roof of the building to collect rainwater. A water collecting device (refer to reference numeral 10, 20, 30 and 40) is installed on a wall (parapet) 2 erected on the edge of the roof and includes a single or a plurality of storages 10 A plurality of water collecting panels 30 installed on the roof 4 on the roof and collecting storms of rain by direct collection and collecting storm water collected from the water receiving panes 10, And troughs 40 for transporting the stormwater to the stormwater treatment system (see reference numerals 50, 60 and 70).

The storm water receptacle (10) is configured to be stretchable and adjustable to vary the catchment area receiving the storm. Specifically, the ceiling panel 10 is configured to be substantially horizontally arranged and to be contracted in the opposite direction from the rooftop wall 2 in the substantially horizontal direction toward the outside of the roof.

Since the storm water receptacle 10 protrudes to a position relatively far away from the rooftop in the outward direction when it is extended, the rainfall falling on the corresponding area (enlarged catchment area) can be collected. In other words, it is possible to collect the rainfall falling from the rooftop to the neighboring area on the outer side, thereby collecting the abandoned rainfall without being used separately.

In addition, according to the superior receiving unit 10, since the rainfall is prevented from directly touching the outer wall of the building to some extent, the outer wall of the building can be protected from the acid rain and the leaking phenomenon of the building It is possible to prevent the shortening of the life of the building caused by rainfall.

3 and 4, the superior receiver 10 is composed of a plurality of segments 11, 12, and 13 coupled to each other by a telescopic method, From the rooftop wall (2) in the substantially horizontal direction toward the outside of the roof, or contracted in the opposite direction.

Each of the segments 11, 12, 13 has two elongated bottom plates and two side plates erected on both sides of the bottom plate. Assuming that the three segments 11, 12 and 13 are provided, the second segment (refer to reference numeral 12) corresponds to the first segment (see reference numeral 11) And the third segment (refer to reference numeral 13) can be slidably moved in the forward and backward directions in front of the second segment (refer to reference numeral 12) to the second segment (refer to reference numeral 12) Can be inserted.

One of the plurality of segments 11, 12 and 13 is a stationary segment 11 mounted on the roof 2 on the roof and the rest except for the stationary segment 11 has a cross- And movable segments (12, 13) slidable in a stretching direction.

Reference numerals 14, 15, and 16 are support rods coupled to each other by a telescopic method. The support rods (14, 15, 16) constitute a support member. The support members support the superior supports 10 from below, are provided in plural, and are spaced apart from one another along the lateral direction of the superior supports 10 so as to be spaced apart from each other. The support rods 14, 15, 16 are provided in the same number as the segments 11, 12, 13. When three segments 11, 12 and 13 are provided, three support rods 14, 15 and 16 are provided. The first support rods 14 (refer to reference numeral 14) The second support rod (refer to reference numeral 15) is connected to the second segment (refer to reference numeral 12), and the third support rod (refer to reference numeral 16) is connected to the third segment (refer to reference numeral 13). At this time, assuming that the second segment (see reference numeral 12) and the third segment (see reference numeral 13) are movable segments, the second and third support rods (refer to reference numerals 15 and 16) Segments (refer to reference numerals 12 and 13).

The front end of the best movable segment (13) positioned at the foremost position in the extension of the stand (10) is provided with a front plate for preventing the accumulated therein from being discharged to the outside of the roof. The bottom plate of each of the segments 11, 12 and 13 may be provided with an inclined surface for guiding the storm gathered in the downward slope toward the roof toward the roof.

The elongating and contracting drive unit 20 has a structure in which the best movable segment 13 (or the supporting rod 16 to which the best movable segment 13 is connected) and the outer wall (outer wall of the building) At least one stretching member (21) connected at both ends in a hinge manner so as to be rotatable in the up and down direction and capable of stretching in length, a hinge connection portion (21) of the elastic member (21) And a driving mechanism 22 and a transmission mechanism 23 for rotating the elastic member 21 in the vertical direction.

The stretching member 21 is composed of an elongated linear fixing member 211 and a movable member 212 coupled to the fixing member 211 so as to be slidable along the longitudinal direction. A fixing member 211 may be rotatably connected to the outer wall of the wall body 2 in a vertical direction, and the movable member 212 may be rotatably connected in a vertical direction. The stretchable member 21 is elongated or contracted in the rotating direction as both ends of the stretchable member 21 are rotatably connected to the outer wall of the wall 2 at both ends so as to be vertically rotatable. Is elongated or contracted in accordance with the elongation and contraction of the stretchable member (21).

The driving source 22 is constituted by a driving motor. The transmission mechanism 23 includes a first operation wire 231 that is connected to the elastic member 21 and rotates the elastic member 21 upward when the elastic member 21 is pulled and connected to the elastic member 21 when the elastic member 21 is pulled, (Forward rotation and reverse rotation) in both directions by the drive motor serving as the drive source 22 and is connected to the first operation wire 231 and the second operation wire 232, And a rotary drum 233 wound in a direction opposite to each other.

When the movable member 212 is connected to the best movable segment 13, the first operating wire 231 is connected to the movable member 212, And the second operating wire 232 may be connected to the fixing member 211. [

The rotary drum 233 can be rotatably installed on the inner wall of the wall body 2. The first and second operating wires 231 and 232 are connected to the elastic members 21 at one ends thereof The wall 2 can be passed from the outside to the inside and wound on the rotary drum 233 in the direction opposite to the other. In order to prevent the first and second operation wires 231 and 232 wound on the rotary drum 233 from being wound in a direction opposite to each other to be tangled with each other during winding and unwinding, the rotary drum 233 is provided with two pulleys for wires And they can be structured to be coupled to each other in the axial direction.

When the rotary drum 233 is rotated in one direction of the both directions by the drive source 22 and the first operating wire 231 is wound around the rotary drum 233 and pulled, the elastic member 21 is rotated upward, Whereby the base 10 is also contracted together. Of course, in this process, the second operating wire 232 is released from the rotary drum 233.

On the contrary, when the rotary drum 233 is rotated in the other direction of the two directions by the drive source 22 and the second operation wire 232 is wound around the rotary drum 233 and pulled, the elastic member 21 is rotated in the downward direction So that the receiving tray 10 is also stretched. Of course, in this process, the first operating wire 231 is released from the rotary drum 233.

According to the transmission mechanism 23 having such a configuration, even when a plurality of elastic members 21 are provided in the embodiment of the present invention, all of the elastic members 21 can be expanded and contracted together by one driving source 22. [ That is, the power of the driving source 22 can be transmitted to each of the positions of the superior receiving unit 10 to which the plurality of stretching members 21 are applied. Of course, it is also possible to provide a plurality of excellent receivers 10 depending on the operating conditions, and all of the receiver receivers 10 can be stretched and contracted together by one driving source 22. [

Reference numerals 25 and 26 denote the tension of the first and second operating wires 231 and 232, respectively. When the first or second operating wire 231 or 232 is pulled, the elastic member 21 corresponds to this operation The first guide roller and the second guide roller for guiding the conveyance of the first and second operation wires 231 and 232 so as to be accurately rotated in the upward direction or the downward direction.

The number of the first and second guide rollers 25 and 26 can be appropriately increased or decreased depending on the operating conditions and the like. 3, the second guide roller 26 includes a stationary body 261, a movable body 262 slidably coupled to the stationary body 261, a stationary body 261, An elastic member 264 for applying an elastic force to the movable body 262 between the movable bodies 262 and 262 and a roller 263 mounted at the tip of the movable body 262. [ That is, the second guide roller 26 has a configuration capable of flexibly holding the tension of the second operation wire 232. Of course, the first guide roller 25 may be configured to be the same or similar to have the same function as the second guide roller 26. [

The plurality of water collecting panels 30 are arranged in a matrix form on the floor 4 of the roof so that they can be collected by the water receiving platform 10 and collected by storm from the water receiving platform 10 to the inside of the roof, do. That is, they are arranged in a state of being slightly spaced from each other in the horizontal and vertical directions or in a state of being in contact with each other. 1 and 5, the water collecting panel 30 includes a rectangular plate-shaped member 31, a plurality of leg members 32 for supporting the plate-shaped member 31 from below, (Laminated) on the cover member 33. [ The cover member 33 is made of a powdery or particulate high-purity basalt, and is made of a plate-like (basalt slate) to purify the storm.

Basalt has numerous micropores and keeps continuous pores of 40 ~ 60% of micropores, so it is light and has excellent adsorption power. In addition, basalt rock contains a large amount of iron oxide (Fe2O3) which reacts with water to generate OH radicals, and has a good generation of far infrared rays and anion generation. Natural basalt rocks have a far infrared emissivity of about 90%, which is a much better value than germanium, elvan, and loess.

According to the various functions of the basalt, the water collecting panel 30 purifies the collected water firstly (adsorption of impurities, etc.). That is, the stormwater is preliminarily processed before being fully processed by the stormwater treatment apparatus (refer to reference numerals 50, 60 and 70).

Reference numeral 331 denotes a single or a plurality of guide flow paths provided on the upper surface of the cover member 33 so as to guide the flow of rain to the side between the adjacent water collecting panels 30, The water received from the superior receiver 10 flows along the guide passage 331 and falls into the space between the plurality of water collecting panels 30. [

The troughs 40 are arranged on the lower side between the plurality of the water collecting panels 30 and receive the excellent drops falling from the space between the plurality of the water collecting panels 30 to the floor 4 on the roof.

According to the collecting panel 30 and the trough 40, not only the storm can be collected but also the rooftop waterproof effect can be expected as the area or the amount of the storm that directly touches the bottom 4 of the roof is minimized. Of course, there is no need for a separate roof waterproofing work.

As shown in Figs. 1 and 6, storm surges collected on the catch panel 30 after falling from the storm catcher 10 and the storm catcher panel 40, which are collected directly on the plurality of catch panel 30 by rainfall, (Refer to reference numerals 50, 60 and 70) through a merging pipe 45 connected to the trough 40. [

A drain pipe (47) is connected to the junction pipe (45). A three way valve 49 is provided at a connecting point between the merging pipe 45 and the drain pipe 47. According to the three-way valve 49, the rain from the trough 40 can be continuously flowed along the confluent pipe 45 and supplied to the stormwater treatment apparatus (refer to reference numerals 50, 60 and 70) It may be drained.

Foreign matter such as dust and dirt may accumulate on the rainwater receiving panel 10 and the water collecting panel 30 when rain does not occur. Therefore, since the initial rainwater collected by the rainwater receiving panel 10 and the rainwater collecting panel 30 may contain a large amount of such foreign matter, the rainwater collected rainwater may be collected in the rainwater collecting apparatus 10 (refer to reference numerals 50, 60 and 70) It is preferable to operate the three-way valve 49 so as to be drained through the drain pipe 47 without being supplied.

(Refer to reference numerals 50, 60 and 70) includes a storage tank 60, a purifying tank 50, a flow generating device 70, and a tank cleaning device 80, 90.

A confluent pipe 45 is connected to the storage tank 60 so that the stormwater from the water collecting device (see 10, 20, 30 and 40) flowing along the confluent pipe 45 is stored in the storage tank 60. The purifying tank 50 is provided to be connected to the storage tank 60 on the bottom side of the storage tank 60 and receives clean water from the storage tank 60 to purify it. The granular basalt 55 is accommodated in the purification tank 50 and the fine granular material supplied to the purification tank 50 is purified by the granular basalt 55. As described above, since the basalt rock 55 has an excellent purification function and the like, the purification (impurity adsorption, etc.) for the rainwater supplied to the purification tank 50 is effectively advanced by the basalt rock 55. [

The storage tank 60 is formed long in the horizontal direction. The purifying tank 50 is disposed so that its upper end is connected to one end of the bottom of the storage tank 60. The storage tank 60 and the purifying tank 50 are connected to each other (the storage tank 60 is one end of the bottom and the upper end of the purifying tank 50 is opened) Can be supplied to the purification tank 50 naturally.

The bottom plate 61 constituting the bottom of the storage tank 60 is provided so as to be inclined downward toward the upper end side which is the inlet side of the purifying tank 50. The bottom plate 51 constituting the bottom of the purifying tank 50 has an inclined surface which induces foreign matter or the like included in the storm to be collected toward the center side. For example, the inclined surface at this time can be formed by forming a part or all of the bottom plate 51 of the purification tank 50 into a sharp cone shape downward. Alternatively, the inclined surfaces can be provided by constructing the bottom plate 51 of the purification tank 50 with two inclined plates whose lower ends are in contact with each other.

The flow generating device 70 prevents the contamination of the stormwater in the stor- age tank 60 and stormwater (which may be treated water) in the purifier tank 50 by forcibly flowing stormwater stored in the stor- age tank 60. [ The flow generating device 70 includes a water injection pipe 71 disposed inside the storage tank 60 and a water pump 72 for providing the water stored in the storage tank 60 to the water injection pipe 71 .

The water spray tubes 71 are provided in plural and can be arranged horizontally on the bottom side of the storage tank 60. The water spray tube 71 may be provided with a plurality of nozzles for spraying water spaced apart from each other along the longitudinal direction. When the submerged pump 72 is operated, the storm stored in the storage tank 60 is injected through the water injection pipe 71. At this time, the storages stored in the storage tank (60) are forced to flow.

Although not shown, a flow generating device as mentioned in the purification tank 50 may be installed.

Reference numerals 85 and 86 denote water supply pipes for sending clean water (purified water) purified in the purification tank 50 to the use place, and purified water from the water supply pipes 85 and 86 are used for various purposes such as domestic water, .

The tank cleaners 80 and 90 include a cleaning unit 80 for cleaning the storage tank 60 by spraying water on the inner surface side of the storage tank 60. [ The tank cleaning apparatuses 80 and 90 further include a foreign matter discharging unit 90 for discharging foreign matter generated in the cleaning process of the storage tank 60 by the cleaning unit 80.

The cleaning unit 80 includes a single or a plurality of injectors 81 for spraying water to the inner surface (wall surface, ceiling, etc.) side of the storage tank 60 and a plurality of injectors 81 for injecting water into the purifier tank 50 as cleaning water And a cleaning water supply pipe 82 for supplying the cleaning water. The injector 81 may include a nozzle for diffusing and injecting water from the pump and the wash water supply pipe 82. [ Depending on the operating conditions and the like, the injector 81 may have a configuration in which the pump is omitted, and a pump may be installed in the cleaning water supply pipe 82. The cleansing water supply pipe 82 is provided so that its inlet is located on the concave center side of the bottom of the purification tank 50, so that the cleansing water can be utilized as much as possible in the purification tank 50.

The foreign matter discharge unit 90 includes a foreign matter discharge pipe 91 drawn out to the outside of the purification tank 50 from the concave central portion side in the bottom of the purification tank 50 and a pump 92 provided on the foreign matter discharge pipe 91 do.

The cleaning of the storage tank 60 using the tank cleaners 80 and 90 is carried out in such a manner that the storage tank 60 is kept empty and the purifying tank 50 ) May remain in a state in which a small amount of storm remains.

When the cleaning unit 80 is operated, the rainwater in the cleaning tank 50 is sprayed to the inner surface side of the storage tank 60 through the cleaning water supply pipe 82 and the sprayer 81. At this time, the washing water from the jetted sprayer 81 cleans the inner surface of the storage tank 60, and the foreign matter (dirt) removed from the inner surface of the storage tank 60 during the cleaning process is discharged to the outside of the storage tank 60 Along with the cleansing water used for cleaning along the photographic bottom plate 61 and gathered in the concave central portion of the bottom of the purification tank 50.

When the cleaning of the storage tank 60 is completed, the cleaning unit 80 is stopped and the foreign-body discharging unit 90 is operated. Then, the foreign matter collected in the concave central portion of the bottom of the purification tank 50 (sewage containing dirt) is discharged to the outside.

Applicants have conducted the following tests to demonstrate the cleansing efficacy of basalt for storms.

Two vessels (hereinafter, referred to as containers 1 and 2, respectively) were prepared, and 8 liters of each of the prepared vessels 1 and 2 was introduced into the prepared vessels 1 and 2, respectively. The pH was measured. The measurement results are shown in Table 1 below.

[Table 1]

Then, 1.5 kg of granular basalt crushed into vessels 1 and 2 at 10 mm to 20 mm were respectively introduced. In the container 1, a small submerged pump was introduced, and a process of generating a flow for 20 seconds using an underwater pump was repeated at intervals of 3 minutes for the storm that was introduced into the container 1. On the other hand, in the case of the storm that was introduced into the vessel 2, the flow was not caused to occur. The results of measuring pH by using a pH meter with respect to each storm introduced into vessels 1 and 2 at 5 minutes, 30 minutes, 1 hour, and 2 hours after the introduction of basalt were measured are shown in Table 2 below .

[Table 2]

While the present invention has been described in connection with what is presently considered to be the most practical and preferred embodiments, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, is intended to cover various modifications and equivalent arrangements included within the spirit and scope of the invention.

2: rooftop wall 4: rooftop floor
10: excellent receiving unit 20: stretching and driving means
21: elastic member 22: driving source
23: transmission mechanism 231: first operation wire
232: second operating wire 233: rotary drum
30: Collecting panel 31: Plate member
32: leg member 33: cover member of basalt
40: Trough 50: Purification tank
55: granite basalt 60: storage tank
70: Flow generating device 71: Water spraying pipe
72: Submerged pump 80: Cleaning unit
90: Foreign body discharge unit

Claims (12)

(10) which is installed on the roof wall (2) and collects storm water and is stretched outwardly from the roof wall (2) and contracted in the opposite direction;
(20) for expanding and contracting the stand (10)
Water collecting device. The method according to claim 1,
The superior receiver (10) comprises a plurality of superior receiving segments (11, 12, 13) connected to each other by a telescopic method,
Wherein one of the plurality of superior receiving segments 11,12 and 13 is a fixed segment 11 mounted on the roof wall 2 and the rest except for the fixed segment 11 is positioned on the superior receiving platform 10 (12, 13) movable in the direction in which the movable segments
Water collecting device. 3. The apparatus according to claim 2, wherein the stretching and driving unit (20)
And a movable member 212 movably coupled to the fixed member 211 along the longitudinal direction. When the movable member 212 is extended, the most movable segment 13) and at least one stretching member (21) connected to the outer wall of the wall body (2) so that both ends thereof are rotatably connected to each other in the vertical direction and expanded or contracted in the rotating direction;
And a transmission mechanism (23) for transmitting the power of the driving source (22) to the driving source (22) and the elastic member (21) to rotate the elastic member (21)
Water collecting device. The transmission mechanism according to claim 3, wherein the transmission mechanism (23)
A first operation wire 231 connected to the elastic member 21 and rotating the elastic member 21 in an upward direction when the elastic member 21 is pulled;
A second operation wire 232 connected to the elastic member 21 and rotating the elastic member 21 in the downward direction when the elastic member 21 is pulled;
The first operating wire 231 is rotated in both directions by the driving source 22 and the first and second operating wires 231 and 232 are wound in opposite directions to pull the first operating wire 231 in the rotating direction, 2, a rotating drum 233 pulling the operating wire 232,
Water collecting device. The method according to claim 1,
The water collecting device includes:
A plurality of water collecting panels 30 arranged in a matrix structure on the roof floor 4 and composed of a leg member 32 for supporting the plate members 31 and the plate members 31 from below, ;
Further comprising a trough (40) arranged below the plurality of water collecting panels (30) for transporting the rainwater to the desired place,
The stormwater receiver (10) is configured to have a structure to provide gathering storms on the catchment panel (30)
Water collecting device. The method of claim 5,
Each of the water collecting panels 30 is disposed on the plate member 31 and further comprises a cover member 33 made of basalt,
Water collecting device. A plurality of water collecting panels (30) arranged in a matrix structure on the roof top (4) and collecting rainwater;
And a trough (40) disposed below the plurality of water collecting panels (30) and adapted to receive the falling rainwater and transport it to a desired place,
Each of the water collecting panels (30)
A plate-like member (31);
A leg member 32 for supporting the plate-shaped member 31 from below;
And a cover member (33) disposed on the plate member (31) and made of basalt to purify the rainwater,
Water collecting device. A water collecting apparatus comprising the storm water receiving apparatus (10) and the stretching and driving means (20) according to claim 1;
And a stormwater treatment device for receiving and processing stormwater from the water collecting device,
The stormwater treatment apparatus comprises a purification tank (50) for receiving particulate basalt (55)
Excellent reuse facility. The method of claim 8,
The stormwater treatment apparatus further includes a storage tank (60) for storing stormwater from the water collecting apparatus,
The purifying tank (50) is provided with a tank (60)
Excellent reuse facility. The method of claim 9,
Wherein the stormwater treatment apparatus further comprises a flow generating device (70) for forcibly flowing stormwater stored in the storage tank (60)
Excellent reuse facility. The flow generating device (70) according to claim 10,
A water spray pipe (71) disposed inside the storage tank (60);
And a submerged pump (72) provided in the storage tank (60) to provide water to the water injection pipe (71)
Excellent reuse facility. A water collecting device having a plurality of water collecting panels (30) and a trough (40) according to claim 7;
And a stormwater treatment device for receiving and processing stormwater from the water collecting device,
The stormwater treatment apparatus comprises a purification tank (50) for receiving particulate basalt (55)
Excellent reuse facility.

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