CN114382171A - Energy-saving environment-friendly house building - Google Patents

Abstract

The invention relates to the field of environment-friendly buildings, in particular to an energy-saving environment-friendly house building which comprises a building body and a rainwater collecting device arranged at the top of the building body, wherein a water storage chamber with a hollow interior is arranged in a floor slab corresponding to each floor of the building body, the water storage chamber is communicated with the rainwater collecting device, and the water storage chamber is also communicated with water using equipment in each user. This application has the advantage that can improve environmental protection building rainwater memory space.

Description

Energy-saving environment-friendly house building

Technical Field

The invention relates to the field of environment-friendly buildings, in particular to an energy-saving environment-friendly house building.

Background

The environment-friendly building is a building which can save resources (energy, land, water and materials) to the maximum extent, protect the environment and reduce pollution, provide healthy, applicable and efficient use space for people and harmoniously coexist with nature in the whole life cycle of the building.

At present, most of environment-friendly buildings are provided with a rainwater collecting device and a water drum on the roof, and collected rainwater is purified and filtered and then stored in the water drum. When the environment-friendly building has a water cut-off condition, the rainwater in the water cylinder can be used in an emergency.

However, because the bearing capacity and the arrangement space of the roof are limited, the number of the water cylinders is usually small, so that the storage amount of rainwater is small, and when more users exist in the environment-friendly building, the water amount of the rainwater in the water cylinders can not meet the requirement of emergency use of the users, so that the environment-friendly building has obvious defects.

Disclosure of Invention

In order to improve the rainwater storage capacity of the environment-friendly building, the application provides an energy-saving environment-friendly house building.

The application provides an energy-concerving and environment-protective type housing construction adopts following technical scheme:

the energy-saving environment-friendly house building comprises a building body, a rainwater collecting device and a water cylinder, wherein the rainwater collecting device and the water cylinder are arranged at the top of the building body, a hollow water storage chamber is arranged in a floor slab corresponding to each floor of the building body, the water storage chamber is communicated with the rainwater collecting device, and the water storage chamber is further communicated with water utilization equipment in each user.

By adopting the technical scheme, during rainfall, the rainwater collecting device firstly stores rainwater in the water cylinder. When the water drum is full of rainwater, the rainwater collecting device stores rainwater in each water storage chamber. This application is through setting up a plurality of aqua storage chambers in the building body to this has improved the holistic rainwater memory space of environmental protection building, ensures to store the rainwater of sufficient volume and supplies the user to use for emergency.

Optionally, the water outlet end of the rainwater collection device is communicated with a water distribution assembly, the water distribution assembly comprises a water distribution tank which is arranged in a hollow manner and is communicated with the rainwater collection device, a water delivery pipe is communicated between the water distribution tank and each water storage chamber, a control valve is arranged on each water delivery pipe, and the control valves are electrically connected to a control system.

Through adopting above-mentioned technical scheme, control system opens the control valve to rainwater in this distribution tank can flow into corresponding storage chamber through the raceway. The water distribution assembly can uniformly distribute rainwater flowing into each water storage chamber, and the possibility that rainwater is unevenly distributed to cause no water to be available to individual users is reduced.

Optionally, each water storage chamber is communicated with a drain pipe, the drain pipe is communicated with the outer wall of the building body, a drain valve electrically connected to the control system is arranged on the drain pipe, an annular overflow cavity is formed in the inner circumference of the vertical side wall of the water storage chamber, the overflow cavity is communicated with the inner cavity of the water storage chamber and the communication position of the overflow cavity is close to the top wall of the inner cavity of the water storage chamber, and the water delivery pipe is communicated with the overflow cavity.

Through adopting above-mentioned technical scheme, control system opens the drain valve at first to this deteriorated rainwater in the drainage storage chamber, then fresh rainwater passes through the raceway and flows into the overflow intracavity, and the fresh rainwater of overflow intracavity is gone up and is washed down remaining deteriorated rainwater on the vertical inner wall of storage chamber. When all the rainwater in the water storage chamber is drained, the control system closes the drain valve, and therefore the water storage chamber can be used for storing fresh rainwater.

Optionally, a plurality of through holes are formed in the side wall of the water storage chamber, one end of each through hole is communicated with the inner wall of the water storage chamber, the other end of each through hole is communicated with the bottom wall of the overflow cavity, and the through holes are inclined downwards along the direction close to the center of the water storage chamber.

Through adopting above-mentioned technical scheme, when the water distribution subassembly stopped the water distribution, the rainwater of overflow intracavity can be through the through-hole all flow in the water storage chamber to this has reduced the rainwater and has stored for a long time and rotten in the overflow intracavity, is not convenient for by the possibility that fresh rainwater washed off.

Optionally, a plurality of the through-holes are arranged circumferentially around the central line of the water storage chamber, and the bottom wall of the overflow cavity is arched upwards in the middle between two adjacent through-holes in the circumferential direction.

Through adopting above-mentioned technical scheme, the setting of hunch plays the effect of assembling and water conservancy diversion to the rainwater that this can make the overflow intracavity flows into the water storage chamber through the through-hole more comprehensively.

Optionally, the cross section of the water storage chamber is circular, an electric slider is vertically arranged at the central position of the inner cavity of the water storage chamber, the electric slider is electrically connected to a control system, two rotary drums are sleeved on the slider of the electric slider in a rotating manner, spiral deflection grooves are formed in the inner side walls of the two rotary drums, the spiral directions of the two deflection grooves are opposite, two protrusions are connected to the slider of the electric slider, one protrusion corresponds to one deflection groove and is in sliding fit with the deflection groove, two water scraping plates are respectively connected to the outer side walls of the two rotary drums, and the water scraping plates are respectively attached to the bottom wall and the vertical inner wall of the water storage chamber.

Through adopting above-mentioned technical scheme, before scraping water, two wiper blades all are located one side of electric slider back to the drain pipe and hug closely each other. The control system controls the sliding block of the electric sliding block to slide downwards, the sliding block drives the protrusions to slide in the corresponding deflection grooves, the rotary drum is stressed to drive the water scraping plates to rotate, and the rotating directions of the two water scraping plates are opposite. The wiper blade pivoted in-process can be scraped remaining rainwater on the water storage chamber inner wall down. The two water scraping plates are matched, and residual rainwater in the water storage chamber can be completely gathered between the two water scraping plates. When two scraping plates all rotate to one side that electronic slider is towards the drain pipe and when leaching each other, can scrape into the drain pipe with the rainwater is whole just to this improves the completeness that the indoor rotten rainwater of water storage was clear away. After that, the control system controls the slide block of the electric slide block to ascend, the slide block drives the rotary drum to ascend, and the two water scraping plates rotate under the action of gravity and automatically reset.

Optionally, two of the wiper blades are provided with magnetic blocks for repelling like poles.

By adopting the technical scheme, the repulsion force between the two magnetic blocks can assist in pushing the water scraping plate to rotate so as to realize automatic reset.

Optionally, an accommodating groove is formed in the wiper blade, and the magnetic block is embedded in the accommodating groove.

Through adopting above-mentioned technical scheme, the magnetism piece is located the holding tank completely to this when two wiper blade rotate to two extreme position, the homoenergetic is hugged closely each other, is favorable to improving the effect of scraping to rotten rainwater.

In summary, the present application includes at least one of the following beneficial technical effects:

1. the plurality of water storage chambers are arranged in the building body, so that the integral rainwater storage capacity of the environment-friendly building is improved, and sufficient rainwater is ensured to be stored for emergency use of users;

2. the control system controls the two water scraping plates in the water storage chamber to rotate mutually so as to scrape off rainwater on the side wall and the bottom wall of the inner cavity of the water storage chamber, and further improves the completeness of removing deteriorated rainwater.

Drawings

Fig. 1 is a schematic structural diagram of an embodiment of the present application.

Fig. 2 is a top view of an embodiment of the present application.

Fig. 3 is a sectional view taken along the line a-a in fig. 2.

Fig. 4 is a sectional view showing the connection relationship among the water storage chamber, the water pipe and the water discharge pipe in the embodiment of the present application.

Fig. 5 is a sectional view of the wiper blade in the initial wiping position in the embodiment of the present application.

Fig. 6 is an exploded view showing the connection relationship between the wiper blade, the slider, and the slide bar in the embodiment of the present application.

FIG. 7 is a cross-sectional view of the drum in an embodiment of the present application.

Fig. 8 is a sectional view of the wiper blade in the wiper terminal position in the embodiment of the present application.

Description of reference numerals: 1. a building body; 2. a rainwater collection device; 3. a water cylinder; 4. a water storage chamber; 41. an overflow chamber; 42. a through hole; 51. a water distribution tank; 52. a water delivery pipe; 53. a control valve; 6. a drain pipe; 7. a drain valve; 81. a slider; 82. a slide bar; 83. a rotating drum; 831. a deflection slot; 84. a protrusion; 85. a wiper blade; 851. accommodating grooves; 9. a magnetic block.

Detailed Description

The present application is described in further detail below with reference to figures 1-8.

The embodiment of the application discloses an energy-saving environment-friendly house building. Referring to fig. 1, 2 and 3, the energy-saving environment-friendly house building comprises a building body 1, a rainwater collecting device 2 and a water drum 3, wherein the rainwater collecting device 2 is arranged at the top of the building body 1, and the device in the prior art is directly adopted by the rainwater collecting device 2.

The water drum 3 is communicated with the rainwater collecting device 2, and when the rainwater collecting device 2 falls into the rain, the rainwater can be collected in the water drum 3.

In addition, a water storage chamber 4 with a hollow inner part is uniformly cast in a horizontal floor slab corresponding to each floor of the building body 1, the cross section of the water storage chamber 4 is arranged in a circular shape, each water storage chamber 4 is communicated with the rainwater collecting device 2, the water storage chamber 4 is also communicated with water using equipment in each user, and the water storage chamber 4 is made of metal materials.

When 3 collection of a water section of thick bamboo are full of the rainwater, rainwater collection device 2 carries the rainwater of collecting to each reservoir chamber 4 in, when the environmental protection building takes place to cut off the water supply, the user can use the rainwater in reservoir chamber 4 and the water section of thick bamboo 3.

Through foretell mode, set up a plurality of aqua storage chambers 4 that are used for storing the rainwater in addition in building body 1, and then improved the holistic rainwater water storage capacity of environmental protection building, ensure to satisfy user's emergency use demand in the environmental protection building.

Referring to fig. 1, 2 and 3, the water outlet end of the rainwater collection device 2 is communicated with a water distribution assembly, the water distribution assembly comprises a water distribution tank 51 placed at the top of the building 1, the water distribution tank 51 is hollow and communicated with the rainwater collection device 2, a water delivery pipe 52 is communicated between the water distribution tank 51 and each water storage chamber 4, each water delivery pipe 52 is provided with a control valve 53, and the control valves 53 are electrically connected to a control system.

Referring to fig. 1, 2 and 3, the rainwater collecting device 2 delivers the collected rainwater to the water distribution tank 51, and under the control of the control system, the corresponding control valve 53 is opened, and the rainwater flows into the corresponding water storage chamber 4 through the water delivery pipe 52.

The water distribution assembly can distribute rainwater to the water storage chambers 4 uniformly, and each user can use rainwater in the corresponding water storage chamber 4.

Referring to fig. 3, 4 and 5, after rainwater is stored in the water storage chambers 4 for a long time, the water quality of the rainwater may be reduced, so that each water storage chamber 4 is communicated with a drain pipe 6, the drain pipe 6 is communicated with the outer wall of the building 1, the communication part of the drain pipe 6 and the water storage chambers 4 is close to the bottom wall of the water storage chambers 4, and the drain pipe 6 is provided with a drain valve 7 electrically connected to a control system.

Referring to fig. 3, 4 and 5, the control system opens the drain valve 7 so that rainwater in the storage chamber 4 can be drained through the drain pipe 6, whereby the storage chamber 4 can store fresh rainwater again.

Referring to fig. 3, 4 and 5, when the deteriorated rainwater in the storage chamber 4 is discharged, the deteriorated rainwater may remain on the bottom wall and the vertical sidewall of the inner cavity of the storage chamber 4.

Therefore, a ring-shaped overflow cavity 41 is formed in the inner periphery of the vertical side wall of the water storage chamber 4, the overflow cavity 41 is communicated with the inner cavity of the water storage chamber 4, the communication position is close to the top wall of the inner cavity of the water storage chamber 4, and the water conveying pipe 52 is communicated with the overflow cavity 41.

Referring to fig. 3, 4 and 5, the water distribution assembly conveys fresh rainwater into the overflow cavity 41, the fresh rainwater in the overflow cavity 41 overflows from the communication part between the fresh rainwater and the inner wall of the water storage chamber 4, the overflowed fresh rainwater flows down from the vertical inner wall of the water storage chamber 4, and the deteriorated rainwater remained on the bottom wall of the water storage chamber 4 is brought out of the water storage chamber 4.

Through the setting of above-mentioned overflow chamber 41, can clear away the rotten rainwater of remaining in the vertical inner wall of reservoir chamber 4 and diapire, reduced the possibility that the rotten rainwater of remaining mixes in fresh rainwater and is stored in reservoir chamber 4.

Referring to fig. 3, 4 and 5, when the distribution assembly distributes rainwater, a portion of the rainwater may be stored in the overflow chamber 41, and after a long time, the rainwater in the overflow chamber 41 may be deteriorated, and the deteriorated rainwater in the overflow chamber 41 may not be easily removed by fresh rainwater,

in order to solve the above problem, a plurality of through holes 42 are formed in the side wall of the water storage chamber 4, and the plurality of through holes 42 are uniformly arranged in the circumferential direction around the center line of the water storage chamber 4. One end of the through hole 42 is communicated with the inner wall of the water storage chamber 4, the other end is communicated with the bottom wall of the overflow cavity 41, and the through hole 42 is inclined downwards along the direction close to the center of the water storage chamber 4.

When the water distribution assembly stops supplying water into the water storage chamber 4, the rainwater in the overflow cavity 41 flows into the water storage chamber 4 through the through hole 42, so that the fresh rainwater can relatively comprehensively take the deteriorated rainwater out of the water storage chamber 4.

Because the aperture of the through hole 42 is small and the water distribution flow of the water distribution assembly is large, the fresh rainwater in the overflow cavity 41 can overflow from the top of the overflow cavity and the through hole 42, and the influence of the fresh rainwater on removing the deteriorated rainwater on the vertical inner wall of the water storage chamber 4 is avoided.

Referring to fig. 3, 4 and 5, when the bottom wall of the overflow chamber 41 is horizontal, part of the rainwater drops may be difficult to flow into the reservoir chamber 4 from the through holes 42, and for this reason, the bottom wall of the overflow chamber 41 is arched upward with respect to an intermediate position between two circumferentially adjacent through holes 42.

The arching arrangement has the functions of gathering and guiding rainwater, so that the rainwater in the overflow cavity 41 can flow into the water storage chamber 4 through the through hole 42 more comprehensively.

Referring to fig. 5, 6 and 7, a water wiping component for wiping off rainwater on the bottom wall of the inner cavity of the water storage chamber 4 is further arranged in the water storage chamber 4, the water wiping component comprises an electric slider arranged at the central position in the water storage chamber 4, and the electric slider is vertically arranged and electrically connected to a control system.

The electric sliding block directly adopts the prior art, and mainly comprises a sliding rod 82 and a sliding block 81 sliding on the sliding rod 82, wherein under the action of a control system, the sliding block 81 can slide back and forth on the sliding rod 82, and the sliding block 81 cannot rotate relative to the sliding rod 82.

Referring to fig. 5, 6 and 7, the wiper assembly further includes two rotating cylinders 83 rotatably sleeved on the sliding block 81, the two rotating cylinders 83 are distributed up and down, the inner side walls of the two rotating cylinders 83 are respectively provided with a spiral deflecting groove 831, and the spiral directions of the two deflecting grooves 831 are opposite.

Referring to fig. 5, 6 and 7, two protrusions 84 are integrally formed on the outer side wall of the slider 81, and one protrusion 84 corresponds to and is slidably fitted with one deflection groove 831. The outer side walls of the two rotary drums 83 are fixedly connected with a water scraping plate 85 respectively, and the water scraping plate 85 is tightly attached to the bottom wall and the vertical inner wall of the water storage chamber 4 respectively.

Referring to fig. 5, 6 and 7, before wiping starts, the two wiper blades 85 are located on the side of the electric slider facing away from the drain pipe 6 and are in close contact with each other.

Under the control of the control system, the slider 81 first drives the protrusion 84 to slide downward, the protrusion 84 slides in the corresponding deflection groove 831, the rotating cylinder 83 is forced to rotate, thereby driving the corresponding wiper blade 85 to rotate, the wiper blade 85 rotates from the side of the electric slider back to the drain pipe 6 to the side facing the drain pipe 6, and the rotation directions of the two wiper blades 85 are opposite.

The wiper blade 85 can wipe down the deteriorated rainwater on the inner wall of the water storage chamber 4 in the process of rotating. The two wiper blades 85 are matched, so that all the deteriorated rainwater remained in the water storage chamber 4 can be collected between the two wiper blades 85.

Referring to fig. 6, 7 and 8, when the two wiper blades 85 are rotated to the side of the electric slider facing the drain pipe 6 and tightly attached to each other, deteriorated rainwater remained in the water storage chamber 4 can be completely drained through the drain pipe 6, so that the wiper assembly improves the completeness of drainage of deteriorated rainwater.

Thereafter, the slide block 81 moves upwards in the opposite direction, so that the wiper blade 85 is driven by the drum 83 to move upwards, and the wiper blade 85 automatically rotates to the side of the electric slide block facing away from the drain pipe 6 under the action of gravity.

Referring to fig. 5, 6 and 7, the two wiper blades 85 are provided with magnetic blocks 9 with like poles repelling each other, and the two magnetic blocks 9 repel each other, so that the repelling force can assist the wiper blades 85 to reset.

Referring to fig. 5, 6 and 7, the wiper blade 85 is provided with an accommodating groove 851, the magnetic block 9 is embedded in the accommodating groove 851, and the two wiper blades 85 can be tightly attached to each other when rotating to two limit positions due to the arrangement of the accommodating groove 851, which is beneficial to improving the completeness of wiping off the deteriorated rainwater.

The implementation principle of the energy-saving environment-friendly house building in the embodiment of the application is as follows:

during rainfall, the rainwater collecting device 2 fills the collected rainwater into the water drum 3, and then sends the rainwater into the water distribution tank 51. The control system controls the opening and closing of each control valve 53, so that fresh rainwater in the water distribution tank 51 can flow into each corresponding water storage chamber 4.

When fresh rainwater is distributed, the control system opens the drain valve 7 first, so that the original deteriorated rainwater in the water storage chamber 4 is drained through the drain pipe 6. Fresh rainwater flows into the overflow cavity 41 from the water conveying pipe 52 and then flows out from the top of the overflow cavity 41 and the through hole 42, and deteriorated rainwater on the vertical inner wall of the water storage chamber 4 can be washed down when flowing out.

After the control valve 53 is closed and the electric slider is started, the slider 81 first drives the protrusion 84 to slide downwards, the protrusion 84 slides in the corresponding deflection groove 831, the rotary drum 83 is forced to rotate, thereby driving the corresponding wiper blade 85 to rotate, the wiper blade 85 rotates from the side of the electric slider back to the drain pipe 6 to the side facing the drain pipe 6, and the rotation directions of the two wiper blades 85 are opposite. The wiper blade 85 can wipe down the deteriorated rainwater on the inner wall of the water storage chamber 4 in the process of rotating. The two wiper blades 85 are matched, so that all the deteriorated rainwater remained in the water storage chamber 4 can be collected between the two wiper blades 85. When the two water scraping plates 85 are rotated to one side of the electric slider facing the drain pipe 6 and tightly attached to the side, the deteriorated rainwater remained in the water storage chamber 4 can be completely discharged through the drain pipe 6.

After which the drain valve 7 is closed and the control valve 53 is re-opened, the water dispensing assembly is able to store fresh rainwater in the reservoir 4 after the deteriorated rainwater has been removed. When the environmental protection building breaks off water, the user can use the rainwater stored in the water storage chamber 4 and the water drum 3 in an emergency.

The above embodiments are preferred embodiments of the present application, and the protection scope of the present application is not limited by the above embodiments, so: all equivalent changes made according to the structure, shape and principle of the present application shall be covered by the protection scope of the present application.

Claims (8)

1. An energy-saving environment-friendly house building is characterized in that: including building body (1), setting be in rainwater collection device (2) and a water drum (3) at building body (1) top, all be provided with inside hollow reservoir chamber (4) in the floor that every floor of building body (1) corresponds, reservoir chamber (4) communicate in rainwater collection device (2), reservoir chamber (4) still communicate with the water consumption equipment in every user.

2. The energy-saving environment-friendly house building according to claim 1, characterized in that: the rainwater collecting device is characterized in that a water outlet end of the rainwater collecting device (2) is communicated with a water distribution assembly, the water distribution assembly comprises a water distribution tank (51) which is arranged in a hollow mode and communicated with the rainwater collecting device (2), a water conveying pipe (52) is communicated between the water distribution tank (51) and each water storage chamber (4), a control valve (53) is arranged on each water conveying pipe (52), and the control valve (53) is electrically connected to a control system.

3. The energy-saving environment-friendly house building according to claim 2, characterized in that: every reservoir chamber (4) all communicates with each other there is drain pipe (6), drain pipe (6) with building body (1) outer wall communicates with each other, be provided with on drain pipe (6) and connect in control system's drain valve (7), the internal periphery of the vertical lateral wall of reservoir chamber (4) is opened there is overflow chamber (41) that is the loop type, overflow chamber (41) with the inner chamber of reservoir chamber (4) communicates with each other and the position that communicates with each other is close to the roof of reservoir chamber (4) inner chamber, raceway (52) with overflow chamber (41) communicate with each other.

4. An energy-saving environment-friendly house building according to claim 3, characterized in that: a plurality of through holes (42) are formed in the side wall of the water storage chamber (4), one end of each through hole (42) is communicated with the inner wall of the water storage chamber (4), the other end of each through hole is communicated with the bottom wall of the overflow cavity (41), and the through holes (42) are inclined downwards along the direction close to the center of the water storage chamber (4).

5. The energy-saving environment-friendly house building according to claim 4, characterized in that: a plurality of through-holes (42) set up around the central line circumference of reservoir chamber (4), overflow chamber (41) diapire relative circumference two adjacent intermediate position between through-hole (42) upwards arches.

6. The energy-saving environment-friendly house building according to claim 1, characterized in that: the transversal circular setting of personally submitting of aqua storage chamber (4), the vertical electronic slider that is provided with of central point of aqua storage chamber (4) inner chamber position, electronic slider electricity is connected in control system, it is equipped with two rotary drums (83) to rotate the cover on electronic slider's slider (81), two all open on the inside wall of rotary drum (83) and be spiral type deflection groove (831), two the spiral opposite direction of deflection groove (831), electronic slider be connected with two arch (84) on slider (81), one arch (84) correspond one deflection groove (831) and rather than sliding fit, two be connected with a wiper blade (85) on the lateral wall of rotary drum (83) respectively, wiper blade (85) with the diapire and the vertical inner wall of aqua storage chamber (4) are hugged closely respectively.

7. The energy-saving environment-friendly house building according to claim 6, characterized in that: the two water scraping plates (85) are respectively provided with a magnetic block (9) with the same polarity repelling each other.

8. The energy-saving environment-friendly house building according to claim 7, characterized in that: the water scraping plate (85) is provided with an accommodating groove (851), and the magnetic block (9) is embedded in the accommodating groove (851).

Images