KR102079279B1 - Initial rainwater excluding device and rain water reservoir comprising the same - Google Patents

Abstract

An embodiment of the present invention relates to an initial rainwater eliminating device, which is installed between a rainwater introduction pipe and a rainwater discharge pipe which communicate with each other in a vertical direction, and may comprise: an upper connecting unit which is coupled after communicating with the rainwater introduction pipe; a lower connecting unit which is coupled after communicating with the rainwater discharge pipe; a body unit of which an upper surface is coupled to communicate with the upper connecting unit, and a lower surface is coupled to communicate with the lower connecting unit; a side surface connecting unit which is coupled after communicating with a side surface of the body unit, and is connected to a rainwater storage tank such that stored rainwater can be introduced thereinto; a rainwater guide unit which is installed in a plate shape in the body unit in order to guide the rainwater such that the rainwater can be introduced into the side surface connecting unit, and is hinged to the body unit to be rotated around a hinge in order to be movable between a first position in which initial rainwater is not introduced into the side surface connecting unit and a second position in which the rainwater is guided to the side surface connecting unit; and an initial rainwater storage unit which is coupled to the rainwater guide unit, and stores the initial rainwater before allowing the rainwater guide unit to be rotatably moved from the first position to the second position by the weight of the stored initial rainwater, thereby guiding the rainwater to the side surface connecting unit.

Description

Initial rain exclusion device and rain storage device having same {INITIAL RAINWATER EXCLUDING DEVICE AND RAIN WATER RESERVOIR COMPRISING THE SAME}

The present invention relates to an apparatus capable of excluding an initial storm in a rain and a storm storage device having the same.

As the damage caused by abnormal weather events such as abnormal high temperatures, cold waves, and large typhoons that occur around the world increases, interest in the environment is increasing. Accordingly, the movement to recycle water is also active, and the Korean government enacted the Law on Promotion and Support of Water Reuse (hereinafter referred to as the Water Reuse Act) in 2013 to encourage water reuse. There are two main ways to recycle water, one of which is to reprocess the used water and the other is to use rainwater. In order to receive rainwater during rainfall, rainwater collection facilities capable of receiving and storing rainwater and stormwater treatment facilities that allow the use of stored rainwater for a purpose are required. As a rainwater treatment facility, various devices for filtering pollutants mixed in rainwater such as various filters and screens are used.

By the way, the Water Reuse Act stipulates the size and function of related facilities while recycling rainwater only at a certain size or more of aggregate facilities, and excellent water collection equipment companies manufacture and sell rainwater recycling facilities according to these regulations. Therefore, all of the conventional stormwater collecting facilities are made up of specialized facilities capable of storing and treating rainwater in a large capacity, and in the process of storing and treating rainwater, a large amount of electric energy is generated through the configuration of filters, pumps, and sensors. In addition to the use, additional personnel are needed to maintain the stormwater collection facilities.

In the following prior art document, several complex facilities are needed, and separate energy and manpower are required to operate them at all times. Such a conventional professional equipment has a problem that can not implement a rainwater recycling facility suitable for use in a general home.

In addition, there is no rain water recycling apparatus that can be installed and used in a general home without burden on maintenance.

Korean Patent Publication No. 10-1556157 (published Oct. 1, 2015)

The present invention is to provide a device that can be recycled by installing rain in a general home to overcome the above problems.

In addition, to provide a device that can be easily installed with a simple configuration and effectively remove the contaminants contained in the initial rainwater. Furthermore, it is intended to provide a device that does not require or minimize electrical energy or manpower to maintain the rainwater recycling system.

In addition, it is intended to provide a device that can store rainwater to be optimized for the user by varying the capacity and method in a variety of ways.

In order to achieve the above object, according to an embodiment of the present invention, the initial rainwater drainage device installed between the rainwater inlet pipe and the rainwater drain pipe communicating in the up and down direction includes: an upper connection portion coupled to the rainwater inlet pipe; The lower connection portion is coupled in communication, the upper side is coupled in communication with the upper connection portion, the lower side is coupled to communicate with the lower connection portion, the rain portion is coupled in communication with the side of the body and stored in rainwater storage tank It is installed in the form of a plate in the body and the side connection portion flowing in, guides the rainwater so that the rainwater can be introduced into the side connection portion, the hinge is coupled to the body portion rotates around the hinge so that the initial rainwater does not flow into the side connection portion A rainwater guide portion movable between the 1st position and the 2nd position which guides the rainwater to a side connection, Is coupled to a number of the guide portion may include storing the initial excellent storage rotational movement in the superior guide a first position by the weight of the initial solid to a second position to the initial excellent storage for guiding the solid in terms of connection that portion.

In addition, the initial rain rejection apparatus according to an embodiment of the present invention, when no rainfall occurs, the rainwater guide portion supports to maintain the first position, the second position by the weight of the initial rainwater stored in the initial rainwater storage unit It may further include a support for imparting an elastic force to return the rainwater guide portion moved to the first position.

In addition, in the initial rainwater rejection apparatus according to an embodiment of the present invention, the initial rainwater storage unit is integrally formed in the hollow region inside the rainwater guide portion, and the side facing the upper connection portion of the rainwater guide portion when the rainwater guide portion is in the first position. An initial storm drain in communication with the initial storm reservoir may be installed, and an initial storm drain may communicate with the initial storm reservoir on the side facing the lower connection portion of the storm guide portion when the storm guide portion is in the second position.

In addition, in the initial rainwater rejection apparatus according to an embodiment of the present invention, the initial rainwater storage unit is protruded and coupled to the lower surface of the rainwater guide portion, and initially on the side facing the upper connection of the initial rainwater storage portion when the rainwater guide portion is in the first position. The rainwater inlet may be installed and an initial rainwater drain may be installed on the side facing the lower connection of the initial rainwater reservoir when the rainwater guide is in the second position.

In addition, the initial storm draining device according to an embodiment of the present invention, the initial storm drain inlet per unit time of the initial storm drain can be larger than the initial storm drain inlet per unit time of the initial storm drain and Any one or more of the number may be determined.

In addition, in the initial rainwater rejection device according to an embodiment of the present invention, the initial rainwater storage unit is projected to the lower surface of the rainwater guide portion is coupled to the porous shell formed to have a space therein, the porous shell is accommodated in the space inside the porous It may include a moisture absorbent for absorbing and maintaining the initial rainwater flowing through the shell.

In addition, in the initial rain rejection device according to an embodiment of the present invention, the moisture absorbent may be made of any one of cotton, sponge, and silica gel.

In addition, in the initial rainwater rejection apparatus according to an embodiment of the present invention, a plurality of grooves extending in a direction toward the side connecting portion is formed on the upper surface of the storm guide portion, a plurality of storm passages are formed between the plurality of grooves, The upper surface of the storm guide portion may be formed concave toward the inside of the storm guide portion along a direction perpendicular to the direction toward the side connecting portion.

In addition, in the initial rain removal apparatus according to an embodiment of the present invention, when the rainwater guide is moved to the second position by protruding the stepped portion is provided on the side facing the side connection portion of the body portion, the rainwater guide portion is in contact with the stepped portion Can be supported.

In addition, the initial rainfall exclusion apparatus according to an embodiment of the present invention, rain sensor for detecting the rain, a driving source coupled to the rain guide portion to move the rain guide portion in the first position and the second position, rain rain sensor is excellent If it is detected that the predetermined time has elapsed after moving the rainwater guide portion to the second position, if the raindrop sensor no longer detects the rainwater, further comprising a controller for moving the rainwater guide portion back to the first position Can be.

In addition, the initial rainwater rejection apparatus according to an embodiment of the present invention, the turbidimeter installed in the initial rainwater storage unit and detects turbidity of rainwater, combined with the rainwater guide portion to move the rainwater guide portion from the first position and the second position The turbidity meter senses turbidity of the rainwater stored in the initial rainwater storage unit, and if the turbidity value exceeds a predetermined value, the rainwater is contaminated, and the rainwater guide unit is moved to the first position to maintain the turbidity value. If it is determined that the rainwater is not contaminated may further include a controller for moving to maintain the rainwater guide portion to the second position.

In addition, the rainwater storage device according to another embodiment of the present invention, the rainwater storage device for storing the rainwater from the initial rainwater rejection device, the initial rainwater rejection device, and one end to the side coupling portion 30 of the initial rainwater drainage device Is coupled in communication, the other end may comprise a rainwater reservoir tube coupled to the rainwater reservoir is flowable.

In addition, in the storm storage device according to another embodiment of the present invention, the storm storage tank is composed of a plurality of storm storage module, each storm storage module, the body with the upper side and the lower side is opened in a column shape, the body An upper cover coupled to an upper side of the upper cover, the upper member having an overflow member installed to allow the rainwater stored in the rainwater storage module to overflow; A lower cover coupled to a lower side of the body and provided with a discharge member for discharging contaminants in the rainwater stored in the storm storage module, wherein at least one of the upper cover and the lower cover communicates with an adjacent storm storage module. Connection member for the can be installed.

In addition, the rainwater storage device according to another embodiment of the present invention, coupled to the connection portion of the rainwater storage module adjacent to the adjacent rainwater storage module to communicate with each other to enable the access of rainwater and the connection pipe formed of the estrap pipe It may further include.

Initial rainwater rejection device according to the present invention can be installed in a general home to provide a device that can recycle rainwater, it is easy to install in a simple configuration and provides a device that can effectively remove the pollutants contained in the initial rainwater can do.

In addition, the initial rainwater rejection device according to the present invention can provide a device that does not require or minimize the electrical energy or manpower to maintain the rainwater recycling facility.

In addition, the rainwater storage device including the initial rainwater rejection device according to the present invention can be installed in a variable capacity and manner in a container capable of storing rainwater can provide a device optimized for use.

1 is a perspective view of an initial rain rejection device according to an embodiment of the present invention.
FIG. 2 (a) is a diagram illustrating a configuration in which the storm guide portion of the initial storm drain removal apparatus according to the embodiment of the present invention is located at a first position.
FIG. 2 (b) is a diagram illustrating a configuration in which the storm guide portion of the initial storm drain removal apparatus according to an embodiment of the present invention is located at a second position.
FIG. 3 (a) is a cross-sectional view taken along line BB ′ of FIG. 3 (b) showing the configuration of the storm guide portion and the storm rainfall storage portion of the initial storm rejection apparatus according to the embodiment of the present invention.
FIG. 3 (b) is a top view illustrating the configurations of the storm guide unit and the storm rain storage unit of the initial storm drain removal apparatus according to the embodiment of the present invention.
3 (c) is a cross-sectional view taken along line AA ′ of FIG. 3 (b) showing the configuration of the rainwater guide unit and the rainwater storage unit of the initial rainwater rejection apparatus according to the embodiment of the present invention.
4 to 6 are cross-sectional views showing the configurations of the storm guide unit and the storm rain storage unit of the initial storm drain removal apparatus according to another embodiment of the present invention.
FIG. 7 is a conceptual diagram illustrating a structure of a rainwater storage device including an initial rainwater rejection device according to another embodiment of the present invention.
FIG. 8 is an exploded perspective view illustrating a configuration of a storm storage module of a storm storage device including an initial storm drain device according to another embodiment of the present invention.

The present invention relates to an initial rainwater rejection device and a rainwater storage device including the same, and will be apparent with reference to the embodiments described below in detail with the accompanying drawings. In the following description of the present invention, if it is determined that a detailed description of a known configuration or a known function related to the present invention may obscure the gist of the embodiments, the detailed description thereof will be omitted.

In addition, the singular expression includes the plural expression unless the context clearly indicates the singular. And when a particular part is said to "include" a particular configuration, this means that unless otherwise stated, the particular portion may further include the other configuration, not to exclude other configuration than the specific configuration.

Hereinafter, specific embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1 is a block diagram according to an embodiment of the present invention. The initial stormwater rejection apparatus 100 according to an embodiment is a device for excluding initial stormwater during rainfall. The rainwater immediately after raining, or rainwater, contains dust or contaminants, and the pollutants accumulated on the roofs are mixed in the initial rainwater coming down the roof of the house. Afterwards, only the clean rainwater is stored, and the contaminated initial rainwater is not stored but flowed out.

For example, assuming that the area of a house's roof is 27 m ² to 32 m ² , typically 400 to 500 liters of rainwater flow down the roof after two hours of rainfall, which must be drained without storage. The initial storm to do refers to rain that starts up to about 30 minutes after the rainfall starts and excludes about 100 to 125 liters of rain, and stores the rain after. However, the amount of initial rainwater and the amount of rainwater to be stored and the initial rainwater exclusion time are not limited thereto, and may be adjusted by various variables such as seasons, weather conditions, the structure of houses, and the use of rainwater stored.

The initial rainwater rejection device 100 may be connected to a drain pipe that collects and drains rainwater that comes down the roof. As illustrated in FIG. 7, the initial storm draining apparatus 100 may be installed between the rainwater inlet pipe 200 communicating with the vertical direction and rainwater enters, and the rainwater drainage pipe 300 through which rainwater flows out. The initial rainwater flowing down from the roof and passing through the rainwater inlet pipe 200 may flow down as it is by the initial rainwater drainage device 100 and be drained to the ground through the rainwater drainage pipe 300. One side of the rainwater storage pipe 400 may be connected to the side of the initial rainwater discharge device 100, and the other side of the rainwater storage pipe 400 may be connected to the rainwater storage tank 500. Therefore, when the initial rainwater is drained through the rainwater drainage pipe 300 by the initial rainwater drainage device 100, the rainwater is not stored in the rainwater storage tank 500, and when the drainage of the initial rainwater is completed, the initial rainwater discharge is excluded. The device 100 is introduced into the rainwater storage tank 500 along the rainwater storage pipe 400 to be reused in the home.

A configuration in which the initial rainwater rejection device 100 excludes initial rainwater will be described with reference to FIGS. 1 and 2. Initial rainwater rejection apparatus 100 according to an embodiment of the present invention is the upper connection portion 10, the side connection portion 30 and the lower connection portion 40 is installed around the body portion 20, the body portion 20 ) May be installed in the rainwater guide unit 50 and the initial rainwater storage unit 60 to exclude the initial rainwater.

Body portion 20 is composed of a housing having an interior accommodating space for installing the rainwater guide portion 50 and the initial rainwater storage unit 60 can be excluded the initial rainwater therein, so that rainwater flows in communication It is in communication with the upper connecting portion 10, the lower connecting portion 40, and the side connecting portion 30. By this configuration, the initial rainwater is excluded from the rainwater flowing through the upper connection portion 10 is drained through the lower connection portion 40, the rainwater stored in addition to the initial rainwater rain storage tank 500 through the side connection portion 30 Can be stored in. The body portion 20 may be formed in various shapes such as a polyhedron shape or a cube shape such as a cube or a pipe shape, except for the upper connection part 10, the lower connection part 40, and the side connection part 30 of the body part 20. The entire surface may be configured to be closed and closed, or as illustrated in FIGS. 2A and 2B, a through window 21 may be formed and opened on one side thereof. When the through-window 21 is formed, the operator can easily access the inside of the body portion 20 to remove contaminants, etc. flowing into the body portion 20 with rainwater, or with the rainwater guide portion 50. Maintenance of the initial rainwater storage unit 60 can be easily made. The through window 21 may be coupled to open and close by the cover 22 to prevent the rainwater flowing into the body portion 20 unintentionally flowing through the through window 21 during rainfall. have.

The upper connection portion 10 is connected to the rainwater inlet pipe 200 in combination with the rainwater flowing down from the roof of the house flows through the rainwater inlet pipe 200 through the upper connection portion 10 to the rainwater flows into the body portion 20 To be possible. The upper connection portion 10 is protruded from the body portion 20 in a tubular shape and is integrally formed with the body portion 20 or may be coupled in various ways such as screwing the body portion 2 and applying an adhesive. have. The body portion 20 is connected to the rainwater inlet pipe 200 is configured by the upper connection portion 10 smaller or larger than the diameter of the rainwater inlet pipe 200 by a predetermined length to enable a relatively sliding movement, the body The part 20 and the excellent water supply pipe 200 overlap with each other can be fastened by various coupling methods such as screw coupling, adhesive coating.

 The lower connection part 40 is coupled in communication with the rainwater drainage pipe 300 so that the rainwater flowing out of the body portion 20 can be drained to the ground via the rainwater drainage pipe 300 via the lower connection portion 40. The lower connection part 40 may also be combined with the body part 20 and the rainwater drainage pipe 300 in a manner similar to the upper connection part 10 described above, and a detailed coupling configuration will be omitted.

Side connection portion 30 is coupled to communicate with the side of the body portion 20 is connected to the rainwater reservoir 500 to be described later rainwater to be stored in the body portion 20 passes through the side connection portion 30 to rainwater storage tank To be stored at 500. The side connection portion 30 may also be coupled to the body portion 20 in a similar manner to the upper connection portion 10 described above, directly coupled to the rainwater reservoir 500, or through a separate rainwater storage pipe 400. Can be combined.

The rainwater guide part 50 may be installed in the body part 20 to guide rainwater so that rainwater may flow into the side connection part 30. The rainwater guide portion 50 may be formed in a plate shape, the rainwater guide portion 50 is one side of the side of the body portion 20 is coupled to the hinge side via the rotation axis to the side of the side connection portion 30 is installed , The excellent guide portion 50 is configured to be rotated about the rotation axis. By such a configuration, rainwater introduced through the upper connection portion 10 may flow down into contact with the upper surface of the rainwater guide portion 50 having a plate shape and may flow into the side connection portion 30. One side coupled to the rotation shaft of the rainwater guide portion 50 may be positioned adjacent to the side connection portion 30, the rainwater flows by installing at a position directly below the side connection portion 30 or lower than the lower side of the side connection portion 30 It can be effectively delivered to the side connection 30 without falling off.

On the other hand, as shown in Figure 2 (a) and 2 (b), because the rainwater guide portion 50 is coupled to one end rotatably to the body portion 20, the rainwater guide portion 50 around the rotation axis The first rainwater can be rotated, so that the rainwater guide portion 50 is erected so that the initial rainwater does not flow into the side connection portion 30 and passes through the lower connection portion 40 to be drained from the rainwater drainage pipe 300 to the ground. Position P1 and the rainwater guide portion 50 inclined with respect to the lower surface of the body portion 30 so that the rainwater flowing from the upper connection portion 10 flows through the upper surface of the rainwater raindrop guide portion 50 and the side connection portion ( 30 is configured to rotate the rainwater guide unit 50 between the second position (P2) to be introduced into. FIG. 2 (a) shows the first position P1 which is set up so that the initial rainwater flowing through the upper connection part 1 does not contact the upper surface of the rainwater guide part 50 so as to exclude the initial rainwater. FIG. 2 (b) shows the upper surface of the rainwater excellent rainwater guide part 50 and the rainwater flowing through the upper connection part 1 when it is no longer necessary to exclude the initial rainwater after a predetermined time elapses after the rainfall starts. The second guide portion 50 is rotated to maintain the state inclined at a predetermined angle with the lower surface of the body portion 20 so that the contact and flow down the rainwater guide portion 50 flows down into the side connection portion 30 The position P2 is shown. When the stepped portion 23 is formed at the side facing the side to which the side connecting portion 30 of the body portion 20 is coupled, when the storm guide portion 50 is in the second position (P2), storm guide portion By stably supporting the 50, rainwater can be continuously introduced into the side connection part 30 and stored in the rainwater storage tank 500.

The rainwater guide unit 50 is coupled to the initial rainwater storage unit 60 to store the initial rainwater, and the rainwater guide unit 50 is moved from the first position P1 by the weight of the initial rainwater that increases as the initial rainwater is stored. It can rotate to the 2nd position P2.

More specifically, the initial rainwater storage unit 60 according to an embodiment of the present invention shown in Figure 3 (a) to Figure 3 (c) is integrally formed in the hollow region inside the rainwater guide portion 50 When the rainwater guide portion 50 is in the first position P1, the initial rainwater inlet 61 communicating with the initial rainwater storage portion 60 on the side facing the upper connection portion 10 of the rainwater guide portion 50 is provided. It is installed. Therefore, the initial rainwater is introduced into the body 20 through the upper connection portion 10, and the rainwater guide portion 50 does not store the first rainwater, that is, the initial rainwater in the rainwater storage tank 500. Since it is in the excluded position, most of the initial rainwater is drained to the ground through the rain drain pipe 300 through the lower connection portion 40, some of the initial rainwater through the initial rainwater inlet 61 and the initial rainwater storage unit 60 Are stored in. When the amount of the initial storm stored in the initial storm storage unit 60 is increased, since one end of the storm guide unit 50 is rotatably coupled around the rotation axis, the weight of the initial storm rain stored in the storm guide unit 50 is increased. Due to the rotational moment acts as the storm guide portion 50 is rotated from the first position (P1) to the second position (P2). When the storm guide portion 50 is rotated to the second position P2, the initial storm is no longer excluded and flows to the side connection portion 30 by the storm guide portion 50. Rotation moment by the weight of the initial storm stored in the initial storm storage unit 60 continues to act on the storm guide unit 50 rotated and moved to the second position P2, so the storm guide unit 50 is moved to the second position P2. ) So that storm water that excludes initial storm water can be stored.

On the other hand, the initial storm storage unit 60 and the initial storm storage unit 60 on the side facing the lower connection portion 40 of the storm guide portion 50 when the storm guide portion 50 is in the second position (P2) An initial storm drain 62 may be installed. The initial rainwater stored in the initial rainwater storage unit 60 is drained through the initial rainwater drain 62 to reduce the weight of the initial rainwater so that the rotation moment is reduced. Since the rotational moment due to the weight of the rainwater does not work, the rainwater guide part 50 may be rotatably moved from the second position P2 to the first position P1.

In addition, in one embodiment of the present invention, the initial rainwater inflow rate per unit time flowing into the initial rainwater inlet 61 may be set to be greater than the initial stormwater drainage flow rate per unit time flowing out of the initial stormwater drain port 62. By setting in this way, the moment of rotation by the initial storm weight stored in the initial storm storage unit 60 can stably maintain the storm guide portion 50 at the second position P2. The initial storm inlet 61 and the initial storm drain 62 may be formed of a plurality of circular through holes, but the shape, size, and number of the initial storm drain 61 and the initial storm drain 62 are not limited thereto. One or more of the size and number of the initial storm inlet 61 and the initial storm drain 62 may be determined to satisfy the initial storm drain flow rate and the initial storm drain flow conditions.

In addition, in an embodiment of the present invention, when no rainfall occurs, the rainwater guide unit 50 is supported to maintain the first position P1, and the rainwater storage unit 60 through the initial rainwater inlet 61. ) So that the rainwater guide portion 50 moved from the first position P1 to the second position P2 by the rotational moment acting by the weight of the initial rainwater stored in) can be maintained at the second position P2. And the rainwater guide part 50 returns to the first position P1 when the initial rainwater stored in the initial rainwater storage unit 60 flows out through the initial rainwater drain 62 and the rotation moment due to the weight of the initial rainwater disappears. Support portion 63 may be installed to impart an elastic force so as to. The support portion 63 is installed at the portion where the rainwater guide portion 50 is coupled to the rotational shaft to the body portion 20, and a coil spring, a leaf spring, a spring, a damper and the like can be used in various ways. One end of the support portion 63 may be configured to be coupled to the body portion 30 and the other end to the rainwater guide portion 50, the spring is wound around the rotating shaft coupled to the rainwater guide portion 50 and the body portion 20 It is also possible to give elasticity to the rainwater guide portion 50 in combination with the rainwater guide 50.

As shown in FIG. 3B, a plurality of grooves 52 extending in a direction toward the side connecting portion 30 may be formed on the upper surface of the rainwater guide portion 50. As the groove 52 is formed, the rainwater flowing in contact with the rainwater guide portion 50 can flow smoothly to the side connecting portion 30, as well as shown in FIG. 3 (c), FIG. Looking at the cross section of the storm guide portion 50 along the AA 'line shown in 3 (b), the upper surface of the storm guide portion 50 is a rainwater guide portion (a direction perpendicular to the direction toward the side connecting portion 30) 50) may be concave toward the inner side. The upper surface of the curved excellent rainwater guide portion 50 has the advantage that can flow at once to collect the rainwater flowing down, and the superior surface of the rainwater guide portion 50 flows at a higher speed to minimize the excellent water leakage It is possible to flow the rainwater from the guide portion 50 to the side connection portion 30.

A plurality of storm passages 53 may be formed between the grooves 52 on the upper surface of the storm guide portion 50. Rainwater passage hole 53 may pass through the upper surface of the rainwater guide portion 50 may be in communication with the initial rainwater storage unit 60. Therefore, some of the rainwater flowing along the upper surface of the rainwater guide unit 50 may be stored in the initial rainwater storage unit 60 through the rainwater passage 53.
That is, the rain passage 53 may not flow into the initial rainwater inlet 61 of the initial storm storage unit 60 when the storm guide portion 50 is in the second position P2, Stored rainwater flows out through the rainwater drain port 62 to prevent the rainwater guide part 50 from returning from the second position P2 to the first position P1 and to return the rainwater passage 53 to the rainwater discharge hole 53. Rainfall will continue to flow during rainfall. The shape, the size, the position and the number of the storm water passages 53 may be determined in consideration of the flow rate of the initial storm drain 62.

On the other hand, the rainwater guide portion 50 may be provided with a non-slip member 51 on the other front end of the rainwater guide portion 50 that is farthest away from the coupling portion with the body portion (20). Therefore, it is possible to prevent the case where the storm guide portion 50 is further rotated out of the second position P2 to guide the stormwater. The non-slip member 51 may be used together with the step 23 or may be used separately.

An initial storm reservoir 60 according to another embodiment of the present invention is shown in FIG. 4. FIG. 4 shows the storm guide portion 50 and the initial storm reservoir 60 according to the present embodiment in the same manner as FIG. 3 (a), which is a cross-sectional view along the line BB 'of FIG. 3 (b). Initial rainwater storage unit 60 is coupled to protrude to the lower surface of the rainwater guide unit (50). The initial storm storage unit 60 is configured to have a space for storing the initial storm, and the upper connection portion 10 of the initial storm storage unit 60 when the storm guide unit 50 is in the first position (P1). Initial rainwater inlet 61 is installed on the side facing the (), and the initial rainwater on the side facing the lower connection portion 40 of the initial rainwater storage unit 60 when the rainwater guide portion 50 is in the second position (P2). A drain 62 may be installed. Detailed configuration and operation of the initial storm storage unit 60 according to Figure 4 is the same as the initial storm storage unit 60 according to Figure 3 (a) to Figure 3 (c) will be omitted.

An initial storm reservoir 60 according to another embodiment of the present invention is shown in FIG. 5. FIG. 5 shows the storm guide portion 50 and the initial storm reservoir 60 according to the present embodiment in the same manner as FIG. 3 (a), which is a cross-sectional view along the line BB 'of FIG. 3 (b). Rainfall storage unit 60 is protruded to the lower surface of the rainwater guide unit 50 is coupled to the porous shell 64 is formed to have a space therein, the porous shell 64 is accommodated in the space inside the porous shell 64 It may be made of a moisture absorbent 65 to absorb and maintain the initial rain flowing through. Since the initial rainfall during rainfall is introduced into the body 20 through the upper connection portion 10 and the rainwater guide portion 50 is in the first position (P1), most of the initial rainwater through the lower connection portion 40 Drained to the ground, a portion of the initial rainwater is collected and stored in the moisture absorbent 65 through a plurality of holes formed in the porous shell (64). When the amount of initial rainwater collected and stored in the water absorbent 65 is increased, the weight of the water absorbent 65 is increased to act as a rotation moment, and accordingly, the rainwater guide portion 50 is moved to the first position P1. Is rotated to the second position P2. When the storm guide portion 50 is rotated to the second position P2, the initial storm is no longer excluded and flows to the side connection portion 30 by the storm guide portion 50. Rotational moment due to the weight of the initial rainwater absorbed by the moisture absorbent 65 continues to act on the rainwater guide part 50 rotated and moved to the second position P2 so that the rainwater guide part 50 moves to the second position P2. To keep the rainfall after the initial storm is excluded. When the rainfall is over, part of the rainwater absorbed by the moisture absorbent 65 flows out through the porous shell 64 to the lower connection portion 40, and the remaining rainwater is evaporated as the moisture absorbent 65 is dried, so that the rotation moment is increased. Since it does not work, the storm guide portion 50 may be rotated from the second position (P2) to the first position (P1).

The porous shell 64 may be formed of a mesh or screen structure made of fibers, metals, polymer materials, and the like, and the moisture absorbent 65 may be made of any one of cotton, sponge, and silica gel.

Referring to FIG. 6, the rainwater guide part 50 according to another embodiment of the present invention is not coupled to the rotational axis of the plate-shaped one end of the body portion 20, but is adjacent to or near the center of the rainwater guide part 50. By rotating shaft coupled to the body portion 20 may be configured to be rotatable. Here, FIG. 6 shows the stormwater guide portion 50 and the initial stormwater storage portion 60 according to the present embodiment in the same manner as FIG. 3A, which is a cross-sectional view along the BB ′ line of FIG. 3B. have. The initial rainwater storage unit 60 is integrally formed in the hollow region inside the rainwater guide unit 50, and the initial rainwater storage unit 60 is installed on the upper part of the rainwater guide unit 50 based on the rotation shaft coupling portion. have. In addition, the initial storm storage unit 60 is formed to have an asymmetrical shape, so that the initial storm is stored in the initial storm storage unit 60 so that the rotational moment due to the weight of the initial storm may act only in one direction. have. The storm guide portion 50 may maintain a standing upright state when the storm guide portion 50 is in the first position P1, and the initial storm rain may be stored in the initial storm storage portion 60 so that the rotation moment may occur at the first position P1. Rotational movement to the second position (P2) to maintain the inclined state flows down the upper surface of the rainwater guide portion 60 may be stored in the rainwater storage tank 500 via the side connection portion 30. Since the configuration and function of the initial rainwater inlet 61, the initial rainwater drain 62, and the rain passage 53 according to the present embodiment are the same as in the previous embodiments, description thereof will be omitted.

In the initial rainwater rejection apparatus 100 according to another embodiment of the present invention, the initial rainwater storage unit 60 protrudes to the lower surface of the rainwater guide unit 50 so that a plurality of blades are rotatably coupled (not shown). And, one end is coupled to the wing of the aberration, the other end is coupled to the body portion, and moves the storm guide portion 50 from the first position (P1) to the second position (P2) as the aberration is rotated by the initial storm It may include a moving force transmission member (not shown). Here, the movement force transmitting member may be formed in a strip shape.

In addition, in another embodiment of the present invention, the function of the initial rainwater rejection device 100 may be supplemented by using a raindrop sensor, a driving source, and a controller. More specifically, a rain sensor (not shown) that detects rainwater may be installed near the upper connection part 10 to detect rain. When the rain sensor starts to detect the storm, the controller (not shown) moves the storm guide portion 50 from the first position to the second position using a driving source (not shown) such as a DC motor after a predetermined time elapses. Move it. In this configuration, although it consumes electrical energy and requires installation of a separate sensor, motor, and controller, the initial rainwater inlet 61 of the initial rainwater storage unit 60 is clogged with contaminants or the initial rainwater storage unit ( Even if the initial rainfall is not stored due to breakage of 60, the storm guide unit 50 may be driven as a driving source based on the information detected from the sensor, thereby storing the storm. The controller may move the storm guide part 50 back to the first position P1 when the raindrop sensor no longer senses storm water. Even in this case, the rainwater drainage port 62 is blocked by contaminants and is not drained, and thus the rainwater guide unit 50 cannot return to the first position P1, and thus the rainwater containing the contaminants may not be excluded at the next rainfall. The case can be prevented.

In addition, in another embodiment of the present invention, the turbidity sensor, the drive source, and the controller may complement the initial rainwater rejection device 100. More specifically, the turbidimeter (not shown) for detecting the turbidity of the stored rainwater may be installed in the initial rainwater storage unit 60. The turbidimeter may be installed adjacent to the initial storm drain 62 in the initial storm reservoir 60. The driving guide (not shown) installed in combination with the storm guide unit 50 to move the storm guide unit 50 at the first position P1 and the second position P2 is stored in the initial storm storage unit 60. The position of the storm guide portion 50 may be changed regardless of the weight of the initial storm. When the turbidimeter detects turbidity of rainwater stored in the initial storm storage unit 60 and the turbidity value exceeds a predetermined value, the controller determines that the stormwater is contaminated beyond the threshold and moves the stormwater guide unit 50 to the first position P1. It is determined that the initial rainfall is excluded by removing the rainwater, and when the turbidity value is less than a predetermined value, it is determined that the rainwater is not contaminated enough to store the rainwater, and the rainwater guide unit 50 is moved to the second position P2 to be maintained. Can be. In this configuration, although it consumes electrical energy and requires a separate turbidimeter, drive source, and controller to be installed, it is more practical to monitor or exclude rainwater by monitoring the pollution state of the initial rainwater in the initial rainwater storage unit 60. Precise control is possible.

In another embodiment of the present invention, the storm storage device 1000 including the initial storm drain device 100 may be configured. Rainfall storage device 1000 is the initial rainwater rejection device 100, rainwater storage tank 500 for storing the rainwater flowing from the initial rainwater rejection device, and one end is coupled to the side coupling portion 30 of the initial rainwater rejection device The other end may be composed of rainwater storage pipe 400 is coupled to the rainwater storage tank (500).

Rainfall storage tank 500 is composed of a plurality of storm storage module 510, each storm storage module 510, the body 512 and the body 512, the upper side and the lower side is opened in a columnar shape, The upper cover 511 and the overflow member 514 is installed to be coupled to the upper side of the rain and stored in the rainwater storage module 510 overflows, and is coupled to the lower side of the body 512 and rainwater storage module The lower cover 513 is provided with a discharge member 517 for discharging contaminants in the rainwater stored in the 510. At least one of the upper cover 511 and the lower cover 513 may be provided with a connection member 516 for communication with the adjacent rainwater storage module 510. As such, by configuring the rainwater storage module 510, the rainwater storage module 510 may be variably connected to the rainwater storage module 510 in consideration of the usage and the amount of usage of the home. For example, only one rainwater storage module 510 may be used or multiple stormwater storage modules 510 may be connected to each household. In addition, it is possible to produce the rainwater storage module 510 having a variety of capacities by simply adjusting the size or length of the body 512, it is possible to implement the rainwater storage module 510 having a variety of capacities without increasing the manufacturing cost. have.

Rainfall storage module 510 may be connected in parallel in a standing state to form the rainwater storage tank 510 or stacked from below in a lying down state may constitute rainwater storage tank 510. The rainwater storage module 510 can be used as a wall of a house by standing in a line, and the rainwater storage module 510 and the flower bed are installed together, and a valve capable of supplying the rainwater stored from the rainwater storage module 510 to the flower bed. It can be used to grow flowers in flower beds using rainwater.

Furthermore, by installing a filtering member (not shown) such as activated carbon in some of the rainwater storage modules 510 constituting the rainwater storage tank 500, the rainwater storage module 510 is used to purify rainwater without using a separate filtration facility. Can be. The rainwater storage module 510 for filtration facilities may be sequentially disposed in the rainwater storage tank 500 to purify rainwater for various uses such as toilet water, kitchen water, and drinking water.

On the other hand, when the coupling between the upper cover 511, the body 512, the lower cover 513 may be implemented by a variety of fastening methods such as screw coupling, adhesive application, which is the upper cover 511 and the lower cover ( It may also be used in a manner to couple the overflow member 514, the discharge member 517 and the connecting member 516 to the 513. In addition, these components may be integrally formed.

 In constructing the rainwater storage tank 500 is coupled to the connection member (515, 516) of the rainwater storage module 510 adjacent to each other to connect the rainwater storage module 510 adjacent to each other to enable the access of rainwater 520 is provided, and when the connecting pipe 520 is configured as an strap tube, it is possible to prevent pests and contaminants such as mosquitoes and flies from being transmitted through the connecting pipe 520.

Further, when the temperature sensor (not shown) is mounted in the storm storage module 510 and the controller determines that there is a risk of freezing based on the detected temperature value, the controller energizes the heating element installed in the storm storage module 510. It is also possible to apply a configuration that prevents freezing.

The embodiments described above are merely illustrative of some examples of the present invention, and the scope of the present invention is not limited to the described embodiments, but is within the scope of the present invention by those skilled in the art. There may be various changes, modifications or substitutions in. For example, the components or features described together in a particular embodiment may be implemented in a distributed manner, and the components or features described in each of the different embodiments may be implemented in a combined form. Likewise, the elements or features described in each claim may be embodied in a distributed manner or in combination with one another. And all such implementations should be regarded as falling within the scope of the present technical idea.

100: initial rain rejection device 10: upper connection
20: body 21: through window
22: cover 23: stepped portion
30: side connection part 40: lower connection part
50: excellent guide portion 51: non-slip member
52: home 53: storm hole
60: initial rainwater reservoir 61: initial rainwater inlet
62: initial storm drain 63: support
64: porous skin 65: moisture absorbing material
200: rainwater inlet pipe 300: rainwater drain pipe
400: storm water reservoir 500: storm water reservoir
510: storm storage module 511: top cover
512: body 513: lower cover
514: overflow member 515: connection member
516: connection member 517: discharge member
520: connector 1000: storm water storage device
P1: first position P2: second position

Claims (15)

In the initial rainwater drainage device installed between the rainwater inlet pipe and rainwater drain pipe communicating in the vertical direction,
An upper connection part connected to the rainwater inlet pipe;
A lower connection portion coupled to the rain drain pipe;
An upper side is coupled to communicate with the upper connection, and a lower side is coupled to communicate with the lower connection;
A side connection part connected to the side of the body part and connected to the rainwater storage tank to receive rainwater stored therein;
It is installed in the body portion in the shape of a plate and guides the rainwater so that rainwater may flow into the side connection portion, one side is hinged to the body portion is rotated around the hinge first rainwater does not flow into the side connection portion A rainwater guide portion movable between a first position and a second position for guiding rainwater to the lateral connection; And
The first rainwater storage unit coupled to the rainwater guide part and guiding rainwater to the side connection by rotating the rainwater guide part from the first position to the second position by the weight of the initial rainwater that stores and stores the initial rainwater. Including;
A plurality of grooves are formed on an upper surface of the rainwater guide part, and a plurality of grooves extending in a direction toward the side connection part are formed, and a plurality of grooves storing some of the rainwater flowing along the upper surface of the rainwater guide part in the initial rainwater storage part. Storm holes are formed,
The upper surface of the storm guide portion is formed concave toward the inside of the storm guide portion in a direction perpendicular to the direction toward the side connecting portion,
And an anti-slip member installed at the other end portion of the rainwater guide part to prevent the rainwater guide part from being rotated further from the second position when the rainwater guide part rotates about the hinge. The method according to claim 1,
If no rainfall occurs, the storm guide portion is supported to maintain the first position, and the storm guide portion moved to the second position by the weight of the initial storm rain stored in the initial storm rain storage unit to the first position An initial storm drain device further comprising a support for imparting an elastic force to return. The method according to claim 1,
The initial storm storage unit is integrally formed in the hollow region inside the storm guide unit,
An initial rainwater inlet communicating with the initial rainwater storage portion is provided on a side facing the upper connection portion of the rainwater guide portion when the rainwater guide portion is in the first position,
And an initial storm drain, which is in communication with the initial storm drain, is provided on a side facing the lower connection portion of the storm guide portion when the storm guide portion is in the second position. The method according to claim 3,
Initial rain exclusion, wherein any one or more of the size and number of the initial storm water inlet and the initial storm drain are determined such that the initial storm water flow rate per unit time of the initial storm drain is greater than the initial storm drain flow rate per unit time of the initial storm drain. Device. The method according to claim 1,
The initial storm storage unit is coupled to protrude to the lower surface of the storm guide portion,
An initial storm inlet is provided on the side facing the upper connection of the initial storm reservoir when the storm guide portion is in the first position,
An initial storm drain apparatus, wherein an initial storm drain is installed at a side facing the lower connection portion of the initial storm reservoir when the storm guide portion is in the second position. The method according to claim 5,
Initial rain exclusion, wherein any one or more of the size and number of the initial storm water inlet and the initial storm drain are determined such that the initial storm water flow rate per unit time of the initial storm drain is greater than the initial storm drain flow rate per unit time of the initial storm drain. Device. The method according to claim 1,
The initial storm storage unit,
And coupled to protruding to the lower surface of the excellent guide portion and formed to have a space therein,
And a water absorbent material contained in the space inside the porous shell and absorbing and maintaining the initial rainwater introduced through the porous shell. The method according to claim 7,
The water absorbing material is made of any one of cotton, sponge, and silica gel, initial rain rejection device. delete The method according to claim 1,
The side wall facing the side connection portion of the body portion is provided with a stepped portion protruding so that when the rainwater guide portion is moved to the second position, the rainwater guide portion is supported in contact with the stepped portion, initial rain removal apparatus. The method according to claim 1,
Rain sensor to detect rain,
A driving source coupled to the storm guide portion to move the storm guide portion at the first position and the second position;
When the rain sensor starts to detect the storm, after the predetermined time elapses, the storm guide unit is moved to the second position, and when the rain sensor no longer detects the storm, the storm guide unit is again And a controller for moving to the first position. The method according to claim 1,
A turbidity meter installed in the initial rainwater storage unit and detecting turbidity of rainwater;
A driving source coupled to the storm guide portion to move the storm guide portion at the first position and the second position;
The turbidimeter detects turbidity of rainwater stored in the initial rainwater storage unit, and if the turbidity value exceeds a predetermined value, determines that the rainwater is contaminated and moves the rainwater guide part to the first position and maintains the turbidity value below a predetermined value. If it is determined that the rainwater is not contaminated, and further comprises a controller for moving the rainwater guide portion to the second position, the initial rainwater rejection device. An initial rain rejection device according to any one of claims 1 to 8 and 10 to 12;
A rainwater storage tank for storing rainwater flowing from the initial rainwater rejection device;
Rainwater storage device comprising a; one end is connected in communication with the side coupling portion of the initial rainwater rejection device, the other end is connected to the rainwater reservoir in communication with the rainwater storage pipe; The method according to claim 13,
The storm storage tank is composed of a plurality of storm storage modules,
Each of the storm storage module,
A body having an upper side and a lower side opened in a columnar shape;
An upper cover coupled to an upper side of the body and provided with an overflow member to overflow the rainwater stored in the rainwater storage module;
A lower cover coupled to a lower side of the body and provided with a discharge member for discharging contaminants in the rainwater stored in the rainwater storage module; Include,
At least one of the upper cover and the lower cover is provided with a connection member for communication with the adjacent rainwater storage module, storm storage device. The method according to claim 14,
The rainwater storage device further comprises a connection pipe coupled to a connection member of the rainwater storage module adjacent to each other to allow the rainwater storage module to communicate with each other to allow the rainwater to enter and exit. .

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