KR20220017951A - Energy circulation type house equipped with rainwater recycling system - Google Patents

Abstract

The present invention relates to an energy circulation type house having a rainwater recycling system, which can purify collected rainwater by using an additionally provided rainwater purification device and can supply the purified rainwater into the house as living water, thereby smoothly supplying water in isolated regions which is hard to supply water and reducing environment contamination by recirculation of resources.

Description

Energy circulation type house equipped with rainwater recycling system {ENERGY CIRCULATION TYPE HOUSE EQUIPPED WITH RAINWATER RECYCLING SYSTEM

The present invention relates to an energy circulation type house equipped with a rainwater recycling system, and more particularly, it is composed of a modular assembly structure so that it can be easily assembled and installed on site, and at the same time, a rainwater collection and purification structure is configured in the house It relates to an energy circulation type house equipped with a rainwater recycling system capable of reducing water consumption.

Recently, as one of the global issues, the seriousness of various resource shortages due to climate change is emerging. In particular, as the pollution of water resources due to wastewater and domestic sewage increases with the increase of urban and industrial facilities along with global warming and abnormal climate, it is difficult to secure stable water resources.

Water resources are essential for maintaining life, and efforts and research are constantly being made to secure safer and cleaner water resources. We supply tap water.

However, in mountainous areas where it is difficult to supply tap water from purification facilities, separate facilities are being built to use valley water, underground water, or rainwater coming down from the mountains.

The conventional method according to the use of double rainwater receives and stores rainwater in a storage space, allows impurities to settle to the floor for a certain period of time, and then filters only the water from the upper part for cleaning or supplying to plants in flower beds. Since it is used only for various purposes, there is a problem in that it is difficult to use it as water for a variety of purposes.

Therefore, in order to use rainwater for a variety of purposes, there is a demand for a rainwater regeneration system that can be used for drinking or showering by purifying rainwater using a water purification device such as a separate water purifier.

Conventional Patent Registration No. 10-0622269 for using rainwater for domestic use includes the steps of neutralizing rainwater collected and stored in the first water collecting tank as filled steelmaking slag, and detection of the first water level meter detecting the water level of the neutralized rainwater. Filtering foreign substances and turbidity by operating the first transfer pump according to the signal to pass rainwater through the filter medium of the filtering device, calling the filtering device to store the filtered rainwater in the second water collecting tank, and detecting the water level of the filtered rainwater A step of discharging the rainwater in the second water collecting tank to the groundwater layer by opening the valve member of the rainwater discharge pipe according to the detection signal of the second water level measuring device is provided.

In addition, according to the related art Registration Patent No. 10-0450486, a check valve is provided and rainwater flows into the lower portion of the filter medium, and a solenoid valve is provided and a backwash water discharge pipe used to wash the filter medium is installed. Rainwater consisting of a filter media layer, a non-woven fabric layer, and a sponge layer, which are supported by a perforated plate having a plurality of through holes formed therein and are coated with activated carbon on the surface of the storage tank, with a diameter of 3 to 15 mm A filter is provided.

However, such conventional techniques still have problems in that facilities for purifying rainwater are complicated, and that the purification effect appears only through several steps, making them somewhat unsuitable for use as living water.

In addition, the conventional techniques still remain somewhat difficult to apply to a small-scale private house due to the maintenance cost along with the facility scale and installation cost.

Korean Patent Publication No. 10-0622269 (2006.09.02.) Korean Patent Publication No. 10-0450486 (2004.09.17.)

The present invention was devised to solve the above problems, and more specifically, when masonry is built to be fixed to a structure such as an outer wall in constructing a modular house, a reduction in the load applied to the structure and resistance to external forces such as typhoons and earthquakes The purpose of the present invention is to provide an energy circulation type house equipped with a rainwater recycling system that can be used for living by collecting and purifying rainwater.

The present invention for solving the above object, the structure (A) constituting the overall shape of the house, is in close contact with the outer surface of the structure (A), one or more through-holes 20 formed in the longitudinal direction are formed to form a plurality It includes a masonry brick (B) composed of stacking and a rainwater treatment unit (C) that is buried underground to collect, store and use rainwater from the outside, and the masonry brick (B) is a masonry brick ( The masonry connector 100 that allows B) to be connected to each other, and the through-holes 20 of the masonry upper and lower masonry bricks B formed in plurality on the upper and lower surfaces of the masonry connector 100, respectively. It includes a connector 200 to be fastened, wherein the connector 200 is respectively fastened to the through hole 20 of the neighboring masonry brick (B), and is bound by the masonry connector 100. do.

According to another embodiment of the present invention, the masonry connector 100 is characterized in that it further includes an outer wall connector 300 that extends to one side and is fastened to the structure A including the outer wall of the building.

According to another embodiment of the present invention, the outer wall connector 300 includes a joint plate part 310 connected to the masonry connector 100 and a fastening plate part extending at a predetermined angle from an end of the joint plate part 310 . (320) and a fastening hole (330a) formed in the fastening plate part (320) is characterized in that it includes.

According to another embodiment of the present invention, the fastening hole 330a is penetrated by an anchor bolt 330b, and the anchor bolt 330b penetrates the fastening hole 330a and is fastened to the structure A. It is characterized in that the masonry connector 100 is fixed to the structure (A).

According to another embodiment of the present invention, the masonry connecting body 100 and the joint plate portion 310 are manufactured by a perforated plate having a plurality of perforated holes 100a and 310a formed thereon and installed to overlap each other, and the joint plate portion 310 is manufactured to overlap each other. is characterized in that the protrusion length on the masonry connector 100 is controlled.

According to another embodiment of the present invention, the connector 200 has one end connected to the masonry connector 100, and a first expanded pipe part 210 whose outer diameter is extended toward the other end, and the first expanded pipe part ( One end is connected to the 210, and it is characterized in that it includes a second expanding tube portion 211 whose outer diameter is reduced toward the other end.

According to another embodiment of the present invention, the rainwater treatment unit (C) is formed at a predetermined position from the ground, collects rainwater, stores rainwater in a storage tank buried underground, and treats it to be used as domestic water. It is characterized in that it further comprises a treatment facility (400).

According to another embodiment of the present invention, the rainwater treatment facility 400 includes a rainwater collecting unit 410 formed at a predetermined height from the ground to collect rainwater, and the rainwater collected from the rainwater collecting unit 410 is the second The first storage unit 420 that is transferred through the first pipe body (P1) and stores the rainwater transferred from the first pipe body (P1) to set the sediment, and the transport of the rainwater stored in the first storage unit 420 is performed. A second second supplying water for living inside and outside the house through the second pipe body P2, receiving and storing the rainwater stored in the first storage unit 420 from the conveyance control unit 430 that controls and the conveyance control unit 430 It characterized in that it includes a storage unit 440 and a control pump 450 for controlling the rainwater stored in the second storage unit 440 to be supplied to the inside and outside of the house through the second pipe body (P2).

According to another embodiment of the present invention, the rainwater collecting unit 410 includes a polygonal-shaped collecting unit 411 for collecting rainwater by forming a predetermined space therein, and a lower side from the uppermost part of the collecting unit 411 . The rainwater collecting part ( 411) Consists of a plurality of through-holes 413 penetrating up and down so as to flow into the interior and a tube body penetrating the lower end of the collecting unit 411, the upper end of which is upper from the lower side of the collecting unit 411 It is characterized in that it includes an even moving part 414 formed in a position spaced apart by a predetermined distance in the direction.

On the other hand, since the description of the technology disclosed in this specification is merely an embodiment for structural or functional description, the scope of the disclosed technology should not be construed as being limited by the embodiment described in the text. That is, since the embodiment may have various changes and may have various forms, it should be understood that the scope of the disclosed technology includes equivalents capable of realizing the technical idea. In addition, since the object or effect presented in the disclosed technology does not mean that a specific embodiment should include all of them or only such effects, it should not be understood that the scope of the disclosed technology is limited thereby.

In addition, the meaning of the terms described in the present invention should be understood as follows. Terms such as “first” and “second” are for distinguishing one component from another, and the scope of rights should not be limited by these terms. For example, a first component may be termed a second component, and similarly a second component may be termed a first component.

Furthermore, when it is mentioned that a certain element is "connected" to another element, it may be directly connected to the other element, but it should be understood that other elements may exist in between. On the other hand, when it is mentioned that a certain element is "directly connected" to another element, it should be understood that the other element does not exist in the middle. On the other hand, other expressions describing the relationship between elements, that is, "between" and "between" or "neighboring to" and "directly adjacent to", etc., should be interpreted similarly.

The singular expression is to be understood to include the plural expression unless the context clearly dictates otherwise, and terms such as "comprises" or "have" refer to the specified feature, number, step, action, component, part or these It is intended to indicate that a combination exists, and it should be understood that it does not preclude the possibility of the existence or addition of one or more other features or numbers, steps, operations, components, parts, or combinations thereof.

The present invention provides an energy circulation type house equipped with a rainwater recycling system, which is easy to assemble and install at the site, improves constructability, and has the effect of reducing construction costs by shortening the construction period.

In addition, it is possible to supply water for living in the house due to the rainwater collection and purification structure, which has the effect of reducing costs by reducing water consumption and reducing water pollution due to resource circulation.

1 is a view showing the overall appearance of an energy circulation type house provided with a rainwater recycling system according to the present invention
Figure 2 is a view showing the brick masonry and connector structure of the energy circulation type house provided with the rainwater recycling system according to the present invention
3 is a view showing a masonry connection body and an outer wall connection body of an energy circulation type house provided with a rainwater recycling system according to the present invention;
4 is a view showing the length adjustment structure of the external wall connector of the energy circulation type house provided with the rainwater recycling system according to the present invention;
5 is a view showing a connector expansion structure of an energy circulation type house provided with a rainwater recycling system according to the present invention;
6 is a view showing the first and second expansion pipe parts of the energy circulation type house provided with the rainwater recycling system according to the present invention;
7 is a view showing another embodiment of an energy circulation type house provided with a rainwater recycling system according to the present invention
8 is a view showing the length adjustment structure of the outer wall connector filled with mortar in the masonry brick of the energy circulation type house provided with the rainwater recycling system according to the present invention;
9 is a view showing the first and second expanded pipe parts filled with mortar of the energy circulation type house provided with the rainwater recycling system according to the present invention;
10 is a flow chart showing the construction sequence of the energy circulation type house provided with the rainwater recycling system according to the present invention
11 is a view showing a rainwater collection unit of an energy circulation type house provided with a rainwater recycling system according to the present invention

Hereinafter, it will be described in more detail with reference to preferred embodiments to which the present invention pertains.

First, FIG. 1 is a view showing an overall conceptual diagram of an energy circulation type house provided with a rainwater recycling system according to the present invention. The present invention according to FIG. 1 is composed of a structure (A), a masonry brick (B) and a rainwater treatment unit (C) as basic components.

First, the structure (A) is a modular structure and constitutes the overall shape of the house, and is composed of various materials such as wood, iron, and concrete. In general, the structure (A) constitutes the inner wall of the house, that is, the internal structure, and includes general house internal facilities such as various electric facilities, water facilities and ventilation facilities, and detailed description thereof will be omitted.

Next, referring to FIG. 2 , the masonry brick (B) is configured to be in close contact with the outer surface of the structure (A), and includes a brick body (10) and a through hole (20). At this time, the through hole 20 is provided with at least two through holes 20 in the longitudinal direction of the brick body (10).

A plurality of the masonry bricks (B) are stacked on top of each other and masonry. At this time, the masonry connector 100 and the masonry connector 100 so that a joint is formed between the masonry brick (B) and the masonry brick (B). ) is formed in plurality on the upper and lower surfaces of the masonry to constitute the connector 200 that is respectively fastened to the through-holes 20 of the masonry upper and lower masonry bricks (B).

In addition, the masonry connector 100 is disposed between the masonry bricks (B) for masonry construction. At this time, the masonry connector 100 is formed in a plate shape to serve as a joint of the structure (A).

In brick masonry, the joints shrink and expand as the bricks change in temperature. At this time, they are constructed to prevent the bricks from being contracted and expanded while they are in contact with each other to prevent damage to the bricks. In general, joint construction proceeds by pouring mortar between bricks. However, when pouring mortar, the quality of the masonry is determined by the skill level of the worker.

When a joint is formed by the masonry connector 100, the interval between the masonry bricks B is evenly spaced, so that the masonry quality is improved by an unskilled worker. This is possible.

In FIG. 2, the connector 200 shows a state in which one is formed in the center of the upper surface of the masonry connector 100 and two on both sides of the lower surface of the masonry connector 100, but the present invention is not limited thereto. It is also possible to form one on the masonry, or to form the same number on the upper and lower surfaces of the masonry connector 100 .

Looking at the construction method using the connector structure for brick masonry according to the energy circulation type house equipped with the rainwater recycling system according to the present invention, first, the masonry brick (B) is installed on the foundation floor in the transverse direction, and then the masonry brick ( B) is installed so that the bottom connector 200 of the masonry connector 100 is fitted to the through hole 20 of the masonry connector. And by fitting the through hole 20 of another masonry brick into the upper surface connector 200 of the masonry connector 100, the adjacent masonry brick (B) and the masonry connector 100 and the connector ( 200) to have an assembly structure that is bound in the longitudinal direction.

In addition, when forming one connector 200 in the center of the upper surface of the masonry connector 100 and two on both sides of the bottom surface of the masonry connector 100 as shown in FIG. 2 , the connector 200 is horizontally adjacent It has an assembly structure that is fastened to the through holes 20 of the masonry brick (B), respectively, and is bound in the transverse direction by the masonry connecting body 100 .

As such, as the masonry brick (B) is assembled and constructed in the longitudinal and transverse directions by the masonry connector 100 and the connector 200, the bonding force is increased with the masonry brick (B) and the masonry connector 100 without using a mortar. In order to secure strong durability against external forces such as typhoons by promoting this is secured

In FIG. 3 , the masonry connector 100 further includes an outer wall connector 300 that extends to one side and is fastened to the structure A including the outer wall of the building.

The outer wall connector 300 includes a joint plate part 310 connected to the masonry connector 100, a fastening plate part 320 extending at a predetermined angle from an end of the joint plate part 310, and the fastening plate part ( It is configured to include an anchor bolt 330b that is fastened to pass through 320 and a fastening hole 330a to which the anchor bolt 330b is coupled.

Here, the joint plate part 310 is integrally formed with the masonry connector 100 as shown in FIG. 2 or is formed separately from the masonry connector 100 as shown in FIG. 4 to be assembled in a prefabricated manner. A fastening plate part 320 mounted to the structure A may be formed at an end of the 310 . In the present invention, the description is not limited to any one.

Accordingly, when masonry bricks (B) are masonry to maintain a constant distance from the structure (A), the masonry connecting body 100 installed between the masonry bricks (B) is formed by the outer wall connecting body 300 to the structure (A) Since it is coupled with the, resistance to external forces such as typhoons and earthquakes is further improved.

In FIG. 4, the masonry connector 100 and the joint plate part 310 are made of a perforated plate on which a plurality of perforated holes 100a and 310a are formed and are installed to overlap each other, so that the joint plate part 310 is a masonry connector 100 ), the protrusion length can be adjusted.

At this time, the joint plate part 310 may be provided to be superimposed on the top or bottom surface of the masonry connector 100, or it may be assembled by engaging with a slide groove and a protrusion, and also by forming an insertion groove on the side of the masonry connector 100 It is also possible to form the joint plate portion 310 by inserting it.

Accordingly, when the masonry brick (B) is masonry to maintain a constant distance from the structure (A), even if the outer wall of the structure (A) is inclined or the protrusions and depressions are formed stepwise, the joint plate portion 310 based on the masonry connecting body 100 ) to adjust the protrusion length of the outer wall connector 300, regardless of the outer wall shape of the structure (A), the vertical direction masonry precision of the wall structure formed by the masonry brick (B) is improved.

In FIG. 5, the connector 200 has one end connected to the masonry connector 100, a first expanded pipe part 210 whose outer diameter is extended toward the other end, and one end connected to the first expanded pipe part 210, , a second expanded tube portion 211 whose outer diameter is reduced toward the other end, an incision line 230 that radially divides the first and second expanded tube portions 210 and 211, and the first and second expanded tube portions 210 ) (211) a plurality of stop grooves (220a, 220b) formed on one inner peripheral surface, and the first and second pipe expansion parts 210 and 211 are moved inside the stop grooves (220a) (220b) A mil piece 240 provided so that the outer diameter size of the first and second pipe expansion parts 210 and 211 is expanded by engagement is further included.

Here, the second expansion pipe part 211 of the connector 200 formed on the bottom surface of the masonry connector 100 is formed to increase in thickness toward the end, and the connector formed on the upper surface of the masonry connector 100 ( The first expanded tube portion 210 of 200 is formed to expand in thickness as it approaches the masonry connector 100 .

In addition, the stop groove 220a of the first expansion pipe part 210 of the connector 200 provided on the upper surface of the masonry connector 100 allows the downward transport of the mill piece 240, but the upward transport is limited. The stop groove 220b is formed in a sawtooth shape with a downward inclined surface so as to be possible, and is formed in the second expanded pipe portion 211 of the connector 200 provided on the bottom surface of the masonry connector 100. It is formed in a sawtooth shape with a downward sloping surface that allows downward feed, but restricts upward feed.

Accordingly, when the connector 200 provided on the bottom of the masonry connector 100 is inserted through the open hole formed in the masonry connector 100 as shown in FIG. 5a, the mill piece 240 is pressed and transported downward. 2 It is firmly fixed in engagement with the through hole 20 by the expansion force of the pipe expansion part 211, and then the masonry bricks (B) are additionally stacked.

In addition, as shown in Fig. 5b, by inserting a push rod through the through hole 20 of the masonry brick (B) to press the mill piece 240 provided in the connector 200 provided on the upper surface of the masonry connection body 100, the mill piece ( 240) is pressed and fixed to the through hole 20 by the expansion force of the first expansion pipe 210 while being transferred downward.

On the other hand, since the expansion size of the connector 200 is adjusted according to the position of the mill piece 240 , the versatility applied to the through-holes 20 of various sizes using a single connector 200 is provided.

For example, the present invention may proceed with a method in which the mortar (M) is not poured, and a method in which the mortar (M) is poured. The present invention will be described without being limited to any one of whether the mortar (M) is poured.

In FIG. 7 , a masonry brick (B) having at least two through holes (20) in the longitudinal direction, a mortar (M) between the masonry brick (B) and the masonry brick (B) at the time of masonry of the masonry brick (B) can be cast.

After constructing the masonry brick (B) on the foundation floor in the transverse direction, the bottom connector 20 of the masonry connector 100 is installed in the through hole 20 of the masonry brick (B) in the transverse direction, and then the masonry brick The bottom connector 200 of the masonry connector 100 is fitted to the through hole 20 of (B), and the mortar (M) is poured. And the masonry brick (B) is laminated on the mortar (M).

At this time, the masonry brick (B) is a masonry brick (B) adjacent to the upper and lower directions by fitting the through hole 20 of the other masonry brick masonry connector 100 to the upper surface connector 200 of the masonry connector 100. ) and the masonry connector 100 and the connector 200 have a control structure that is bound in the longitudinal direction.

As such, as the masonry brick (B) is assembled and constructed in the longitudinal and lateral directions by the masonry connector 100 and the connector 200, the cohesion between the mortar (M) and the masonry brick (B) is increased to prevent typhoons and Strong durability against the same external force is secured.

On the other hand, in FIG. 8, the masonry connecting body 100 and the joint plate part 310 are made of a perforated plate on which a plurality of perforated holes 100a and 310a are formed and are installed to overlap each other, so that the joint plate part 310 is a masonry connection. The protrusion length is adjusted on the sieve 100, but the mortar M poured between the masonry bricks B is introduced into the perforations 100a and 310a, and the masonry connector 100 and the joint plate part 310. It may be provided to fix the position of the.

Accordingly, when the masonry brick (B) is masonry to maintain a constant distance from the structure (A), even if the outer wall of the structure (A) is inclined or the protrusions and depressions are formed stepwise, the joint plate portion 310 based on the masonry connecting body 100 ) to adjust the protrusion length of the outer wall connector 300, regardless of the outer wall shape of the structure A, the vertical masonry precision of the wall structure formed by the masonry brick B is improved, especially When the mortar (M) poured after adjusting the protrusion length of the outer wall connector 300 flows into the perforations 100a and 310a of the masonry connector 100 and the joint plate 310 and hardens, the masonry connector 100 The position adjustment state of the joint plate 310 is simply fixed.

In FIG. 9 , the mortar M may be introduced through the ends of the first and second pipe expansion parts 210 and 211 . Here, the mortar M is injected into the open holes 210a and 211a, and the mortar filling part 250b is formed in the upper region with the mill piece 240 as a boundary, so that the first and second pipe expansion parts 210 and 211 are formed. The expansion position of the is fixed, and a hollow space portion 250a is formed in the lower region with the mill piece 240 as a boundary.

That is, by pressing the push piece 240 by the expansion force of the first and second pipe expansion parts 210 and 211 , the push piece 240 is engaged with the through hole 20 and the connector 200 is engaged with the through hole 20 to be fixed in the open hole When the mortar M is filled through the 210a and 211a, the mortar M is poured and hardened locally in the mortar filling part 250b, which is the upper region with the wheat piece 240 as a boundary, and the mill piece 240 is fixed in position. As the expanded state of the first and second pipe expansion parts 210 and 211 is firmly fixed, resistance to repeated vibration loads such as earthquakes and typhoons is improved.

On the other hand, as the hollow space 250a is formed in the lower region of the connector 200 by the mill piece 240 , when the mortar M is put into the inside of the connector 200 , the mortar by the volume of the space part 250a Since the input amount of (M) is reduced, the consumption of mortar (M) according to the masonry construction of the masonry bricks (B) is reduced, and the total weight of the wall structure formed of the masonry bricks (B) is reduced. the load is reduced.

Figure 10 shows the construction sequence of the energy circulation type house provided with the rainwater recycling system, the step of manufacturing the frame of the steel house constituting the structure (A) (S10), and an electric corrugated pipe inside the structure (A) (S20), constructing a built-in interior so that the electric corrugated pipe is not exposed to the outside (S30), constructing a boiler accelerator and plastering (S40), and on the outer wall of the structure (A) The modular house is constructed through the external finishing construction step (S50) of constructing the masonry wall (B).

The rainwater treatment unit (C) is formed at a predetermined position from the ground, collects rainwater, stores rainwater in a storage tank buried underground, and further includes a rainwater treatment facility 400 that can be treated and used as domestic water. .

1, the rainwater treatment facility 400 is formed at a predetermined height from the ground to collect rainwater collecting unit 410, and the rainwater collected from the rainwater collecting unit 410 includes a first pipe body P1. A first storage unit 420 for storing the rainwater transferred from the first pipe body P1 and precipitating sediment, and a transfer control unit for controlling the transfer of rainwater stored in the first storage unit 420 ( 430) and the second storage unit 440 that receives and stores rainwater stored in the first storage unit 420 from the transfer control unit 430, and supplies water for living inside and outside the house through the second pipe body P2. and a control pump 450 for controlling the rainwater stored in the second storage unit 440 to be supplied to the inside and outside of the house through the second pipe body P2.

At this time, as shown in FIG. 11 , the rainwater collecting unit 410 includes a polygonal-shaped collecting unit 411 for collecting rainwater by forming a predetermined space therein, and from the uppermost part to the lower side of the collecting unit 411 . The rainwater collecting part ( 411) Consists of a plurality of through-holes 413 penetrating up and down so as to flow into the interior and a tube body penetrating the lower end of the collecting unit 411, the upper end of which is upper from the lower side of the collecting unit 411 It is composed of an even moving part 414 formed in a position spaced apart by a predetermined distance in the direction.

That is, the rainwater moving unit 414 is configured such that the rainwater collected inside the collecting unit 411 must exceed a certain amount, but the rainwater is moved to the first pipe body P1, thereby primarily removing the sediment contained in the rainwater. it is possible to do

The rainwater collected through the rainwater collection unit 410 is transferred to the first storage unit 420 through the first pipe body P1 . At this time, since the first pipe body P1 is formed at a predetermined height of the first storage unit 420, the rainwater stored in the first storage unit 420 can secondaryly remove the sediment after a predetermined time. do.

The transfer control unit 430 can be actively opened and closed through the separate power and control device, and it is possible for an operator to manually control it if necessary.

The rainwater transferred to the second storage unit 440 through the transfer control unit 430 is moved to the inside and outside of the house through the second pipe body P2 according to the operation of the control pump 450 and is supplied as living water. Since it is recirculated, it has the advantage of reducing water consumption and minimizing water pollution.

Although the above has been described with reference to the preferred embodiment of the present invention, those skilled in the art can variously modify and change the present invention within the scope without departing from the spirit and scope of the present invention as described in the claims below. You can do what you can do.

A : Structure B : Masonry Brick
C: rainwater treatment section 10: brick body
20: through hole 100: masonry connection body
200: connector 300: external wall connector
400: rainwater treatment facility

Claims (1)

At least two through-holes 20 in the longitudinal direction of the structure (A) of the modular structure constituting the overall shape of the house, the brick body (10) in close contact with the outer surface of the structure (A), and the brick body (10) In an eco-friendly house comprising a masonry brick (B) constructed and constructed of masonry, and a rainwater treatment unit (C) that is buried underground and can collect, store and use external rainwater,
The masonry brick (B) is disposed between the masonry bricks (B) for masonry construction, the masonry connector 100 is formed in the form of a plate and serves as a joint of the structure (A); and the masonry connector 100 At least one on each of the upper and lower surfaces of the adjacent brick body 10, each of which is fitted into the through-hole 20; and the connector 200 extends to one side of the masonry connector 100 and the Including; the outer wall connecting body 300 fastened to the outer wall;
The rainwater treatment unit C is formed at a predetermined position from the ground and collects rainwater collecting unit 410, and the rainwater collected from the rainwater collecting unit 410 is transferred through the first pipe body P1 and transferred The first storage unit 420 for storing the collected rainwater to set the sediment, the transfer control unit 420 for controlling the transfer of the rainwater stored in the first storage unit 420, and the first storage unit from the transfer control unit 420 The rainwater stored in the second storage unit 440 and the second storage unit 440 for receiving and storing the rainwater stored in the 420 and supplying water for living inside and outside the house through the second pipe body P2 is a second pipe body It includes a; rainwater treatment facility 400 consisting of a control pump 450 that controls to be supplied to the inside and outside of the house through (P2);
The connector 200 is
A first expanded pipe part 210 having one end connected to the masonry connector 100 and having an outer diameter expanding toward the other end, and a second expanding pipe part having one end connected to the first expanded pipe 210 and decreasing toward the other end. (211), a cutting line 230 for radially incising the first and second pipe expansion parts 210 and 211, and the first and second pipe expansion parts 210 and 211 are formed on the inner surface of any one of the mil pieces A plurality of stop grooves (220a) and (220b) formed in a sawtooth shape having a downward inclined surface so that the downward transport of the 240 is allowed, but the upward transport is limited, and the first and second pipe expansion parts 210 and 211 It includes a mill piece 240 that is moved inside and engages with the stop grooves 220a and 220b to expand the outer diameter size of the first and second pipe expansion parts 210 and 211,
The connector 200 is a through hole 20 by the expansion force of the second expanding pipe 211 while the push piece 240 is pressed by the push rod inserted through the open hole formed in the masonry connector 100 and transferred downward. The push piece 240 provided in the connector 200 is pressed by the push rod inserted through the through hole 20 of the masonry brick (B) and is fixed to the masonry brick (B) and transferred downward to the expansion force of the first expansion pipe part 210. is engaged and fixed to the through hole 20 by
The mortar (M) is put through the ends of the first and second pipe expansion parts 210 and 211, and the hollow space part 250a and the mill piece 240 are bordered in the lower region with the wheat piece 240 as a boundary. In the upper region of the furnace, mortar (M) is injected into the opening holes (210a) (211a) to include a mortar filling part (250b) for fixing the expansion positions of the first and second pipe expansion parts (210, 211),
The rainwater collection unit 410 is
A polygonal-shaped collecting unit 411 for collecting rainwater by forming a predetermined space therein;
An inclined surface portion 412 formed at a position spaced apart from the uppermost portion of the collecting portion 411 by a predetermined distance in the downward direction, and the upper portion forming an inclined surface in a curved shape,
Between the collecting part 411 and the inclined plane part 412, a plurality of through-holes 413 penetrating up and down so that rainwater flows into the collecting part 411, and
Consisting of a tubular body passing through the lower end of the collecting unit 411, the upper end of the collecting unit 411 includes a moving part 414 that is configured to be spaced apart by a predetermined distance upward from the lower surface of the collecting unit 411. Energy circulation type house equipped with a rainwater recycling system, characterized in that.

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