CN112267522A

CN112267522A - Intelligent rainwater utilization method and system based on circulating filtration

Info

Publication number: CN112267522A
Application number: CN202010955713.9A
Authority: CN
Inventors: 范丽
Original assignee: Taicang Biaomi Sponge City Technology Co ltd
Current assignee: Taicang Biaomi Sponge City Technology Co ltd
Priority date: 2020-09-11
Filing date: 2020-09-11
Publication date: 2021-01-26

Abstract

An intelligent rainwater utilization method and system based on circulation filtration comprises the following steps: controlling an outdoor camera to take an outdoor image and analyze whether rainfall occurs in a building area, if so, controlling a rotating mechanism to drive a collecting plate to rotate to form a rainwater collecting area and analyze whether the rainfall in the building area stops, if so, controlling the rotating mechanism to drive the collecting plate to rotate and reset and controlling a heater to enter a heating state, controlling a collecting port to open and controlling a filtering purifier to filter and purify liquid in a purifying box, controlling a delivery pump to deliver the liquid in the purifying box into a water delivery pipeline and controlling a first pressure sensor of a water receiving platform to acquire pressure information, controlling a water delivery port corresponding to the water receiving platform with pressure to open to deliver the liquid in the water delivery pipeline into a water storage tank and controlling an ultrasonic sensor to acquire liquid level height information of the water storage tank, and when the liquid level in the water storage tank is identified to exceed the preset height, the corresponding water delivery port is controlled to be closed, and the prompting lamp is controlled to enter a prompting state.

Description

Intelligent rainwater utilization method and system based on circulating filtration

Technical Field

The invention relates to the field of building rainwater utilization, in particular to an intelligent rainwater utilization method and system based on circulating filtration.

Background

Due to the increase of population and the shortage of water resources, the utilization of the water resources is more and more valued by people; moreover, as the earth pollution is more and more serious, less and less clean water sources exist, and the water shortage phenomenon also commonly exists in the world; with the acceleration of the urbanization process, the water consumption for landscape water, road washing, greening, car washing and the like in the city is rapidly increased, so that the originally short water resource is more lacked. Rainwater is used as a clean water source, and under normal conditions, a lot of rainwater is directly discharged to a sewer to flow out, so that resources are greatly wasted, and flood disasters are easily caused;

therefore, how to combine building rainwater collection and distillation for automatically collect rainwater in rainy weather and collect and obtain the pure water through heating distillation after the rainfall stops, then supply the pure water secondary filtration that the cell-phone was obtained to each floor of building, it is the problem that needs to solve at present to supply the user to connect through the chamber of catchmenting and get the pure water use.

Disclosure of Invention

The purpose of the invention is as follows: in order to overcome the defects in the background art, the embodiment of the invention provides an intelligent rainwater utilization method based on circulating filtration and a system thereof, which can effectively solve the problems related to the background art.

The technical scheme is as follows:

an intelligent rainwater utilization method based on circulation filtration, comprising the following steps:

s1, controlling an outdoor camera arranged at the top of the building to start to capture outdoor images in real time according to a monitoring instruction sent by a rainwater management department and analyzing whether rainfall occurs in the building area in real time according to the outdoor images;

s2, if yes, controlling a rotating mechanism arranged at the top of a rainwater collection shed of the building rooftop to drive a connected collection plate to rotate and expand to form a rainwater collection area, and analyzing whether rainfall of the building area stops in real time according to outdoor images;

s3, if yes, controlling the collecting plate which is in driving connection with the rotating mechanism to rotate and reset and controlling a heater which is arranged at the bottom end of a water storage tank in the rainwater collecting shed to start to enter a heating state;

s4, controlling a collecting opening arranged at the bottom end of the inner wall of the rainwater collecting shed to be opened and controlling a filtering purifier arranged at the outer position of a purifying box in the building to be started to filter and purify liquid in the purifying box in real time;

s5, controlling a delivery pump connected with the filtering purifier to start to deliver the liquid in the purifying box into a water delivery pipeline and controlling first pressure sensors arranged at the positions of water receiving platforms of water receiving cavities in each floor of the building to start to acquire pressure information in real time;

s6, controlling a water delivery port corresponding to the water receiving platform with pressure to open, conveying liquid in the connected water conveying pipeline into a water storage tank placed in the water receiving platform, and controlling an ultrasonic sensor arranged at the front end of the water delivery port to start to acquire liquid level height information of the water storage tank in real time;

and S7, when the liquid level in the water storage tank is identified to exceed a first preset height, controlling a water delivery port corresponding to the water storage tank to be closed and controlling a prompting lamp arranged at a position of a water receiving platform corresponding to the water delivery port to be started to enter a prompting state.

As a preferred mode of the present invention, after S5, the method further includes the steps of:

s50, if the water receiving platform is identified to have no pressure, controlling a second pressure sensor arranged in a water receiving opening below a water receiving cavity where the water receiving platform is located to start to acquire pressure information in real time, and analyzing whether a water receiving pipe is inserted into the water receiving opening in real time according to the pressure information;

s51, if yes, controlling the water receiving port to be opened to supply liquid in the water delivery pipeline into the inserted water receiving pipe and controlling a water flow sensor arranged at the connecting position of the water receiving port and the water delivery pipeline to be started to acquire water flow information of the water receiving port in real time;

s52, analyzing whether the water pipeline has preset time lower than preset water flow or not in real time according to the water flow information;

and S53, if yes, controlling the water receiving port to be closed and controlling the water flow sensor to be closed.

As a preferred mode of the present invention, after S3, the method further includes the steps of:

s30, controlling a first liquid level sensor arranged in the water storage tank to start to acquire first liquid level information in real time and analyzing whether liquid in the water storage tank is lower than a second preset height in real time according to the first liquid level information;

s31, if yes, controlling the heater in the water storage tank to stop heating and controlling a second liquid level sensor arranged in the water purification tank to start to acquire second liquid level information in real time;

and S32, controlling an electronic display screen arranged at the outer wall of the water receiving cavity to display the water storage capacity information of the water purifying tank in real time.

As a preferred mode of the present invention, the method further comprises the steps of:

s100, receiving state information of a replacement button arranged on the outer surface of the water receiving cavity in real time and analyzing whether the replacement button is in a pressed state or not in real time according to the state information;

s101, if yes, controlling an electric switch valve arranged in a water receiving cavity where the replacement button is located and corresponding to a water conveying pipeline to be closed, and controlling a replacement box corresponding to the water conveying pipeline to be opened;

s102, after the pressing state of the replacement button is identified to be released, controlling an electric switch valve in a water receiving cavity corresponding to the replacement button to be opened and controlling a replacement box corresponding to the water conveying pipeline to be closed.

As a preferable mode of the present invention, after the water receiving platform is provided with the water storage tank, the method further comprises the following steps:

s500, controlling a telescopic mechanism corresponding to the water receiving platform with pressure to drive a water delivery port to stretch out and insert into a water storage tank of the water receiving platform, and controlling the water delivery port to open to deliver liquid in a connected water delivery pipeline into the water storage tank after the water delivery port is stretched out;

s501, controlling an ultrasonic sensor arranged at the front end of a water delivery port to start to acquire liquid level height information of the water storage tank in real time, and controlling the water delivery port corresponding to the water storage tank to be completely contracted and closed through a telescopic mechanism after recognizing that the liquid level height in the water storage tank exceeds a preset height.

An intelligent rainwater utilization system based on circulation filtration uses an intelligent rainwater utilization method based on circulation filtration, and comprises a collecting and evaporating device, a conveying device, a service device and a building controller;

the collecting and evaporating device comprises an outdoor camera, a rainwater collecting shed, a rotating mechanism, a collecting plate, a water storage tank, a heater, a collecting port and a first liquid level sensor, wherein the outdoor camera is arranged at the top of the building and used for shooting an environment image around the building; the rainwater collecting shed is arranged in the building rooftop area; the rotating mechanism is arranged at the top end of the rainwater collecting shed, is connected with the collecting plate and is used for driving the connected collecting plate to rotate; the collecting plate is connected with the rotating mechanism and is used for collecting rainwater after rotating or sealing the rainwater collecting shed; the water storage tank is arranged inside the rainwater collecting shed and used for storing rainwater; the heater is arranged at the bottom end position of the water storage tank and used for heating the water storage tank; the collecting port is arranged on the ground position of the inner wall of the rainwater collecting shed and is used for collecting distilled water; the first liquid level sensor is arranged at the inner position of the water storage tank and used for acquiring the liquid level height in the water storage tank;

the conveying device comprises a purification box, a filtering purifier, a water conveying pump, a water conveying pipeline, a water receiving cavity, a water receiving platform, a water receiving port, a water flow sensor, a second liquid level sensor and an electronic display screen, wherein the purification box is arranged at the position inside the building and used for storing collected distilled water; the filtering purifier is arranged at the position outside the purifying box and is used for filtering and purifying liquid in the purifying box; the water delivery pump is connected with the filtering purifier through a hose and is connected with a water delivery pipeline and used for guiding the liquid filtered and purified by the filtering purifier into the water delivery pipeline; the water conveying pipeline is respectively connected with the water conveying pump and the water receiving cavity; the water receiving cavity is arranged at the inner position of each floor of the building and is used for supplying filtered and purified liquid; the water receiving platform is arranged in the middle of the water receiving cavity and used for placing the water storage tank; the water receiving port is arranged at the lower end of the water receiving cavity and is connected with a water conveying pipeline connected with the water receiving cavity; the water flow sensor is arranged at the connecting position of the water receiving port and the water conveying pipeline and used for acquiring water flow information conveyed to the water receiving port by the water conveying pipeline; the second liquid level sensor is arranged at the inner position of the purification box and used for acquiring the liquid level height in the purification box; the electronic display screen is arranged on the outer surface of the water receiving cavity and used for displaying information;

the service device comprises a first pressure sensor, a telescopic mechanism, a water delivery port, an ultrasonic sensor, a prompting lamp, a second pressure sensor, a replacement button, a replacement box and an electric switch valve, wherein the first pressure sensor is arranged at the position of the water receiving platform and used for acquiring pressure information of the water receiving platform; the telescopic mechanism is arranged in the water receiving cavity, is connected with the water delivery port and is used for driving the connected water delivery port to stretch; the water delivery port is arranged at the position of the water receiving cavity above the water receiving platform, is respectively connected with the telescopic mechanism and the water delivery pipeline and is used for supplying liquid; the ultrasonic sensor is arranged at the front end of the water delivery port and used for acquiring the height information of the liquid in the water storage tank corresponding to the water delivery port; the prompting lamp is arranged at the position of the water receiving platform and used for providing a prompting function; the second pressure sensor is arranged at the position of the water receiving port and used for acquiring information of an object collided by the water receiving port; the replacement button is arranged at the outer position of the water receiving cavity; the replacing box is arranged at the outer position of the water conveying pipeline above the water receiving cavity; the electric switch valve is arranged at the inner position of the water conveying pipeline above the water receiving cavity;

the building controller sets up in the place position of building rainwater management department planning, the building controller includes:

the wireless module is used for being wirelessly connected with an outdoor camera, a rotating mechanism, a heater, a collecting port, a first liquid level sensor, a filtering purifier, a water delivery pump, a water receiving port, a water flow sensor, a second liquid level sensor, an electronic display screen, a first pressure sensor, a telescopic mechanism, a water delivery port, an ultrasonic sensor, a prompt lamp, a second pressure sensor, a replacing button, a replacing box, an electric switch valve, a rainwater management department and the Internet respectively;

the outdoor shooting module is used for controlling the starting or closing of the outdoor camera;

the information analysis module is used for processing and analyzing the information according to the specified information;

the collecting and rotating module is used for controlling the rotating mechanism to execute the set rotating operation of the collecting plate according to the set steps;

the water storage heating module is used for controlling the heater to be started or closed;

the collecting switch module is used for controlling the opening or closing of the collecting port;

the filtering and purifying module is used for controlling the starting or the closing of the filtering and purifying device;

the purification conveying module is used for controlling the starting or closing of the conveying pump;

the first pressure module is used for controlling the first pressure sensor to be started or closed;

the water delivery switch module is used for controlling the opening or closing of the water delivery port;

the ultrasonic identification module is used for controlling the starting or the closing of the ultrasonic sensor;

and the water receiving prompt module is used for controlling the start or the close of the prompt lamp.

As a preferable mode of the present invention, the building controller further includes:

the second pressure module is used for controlling the second pressure sensor to be started or closed;

the water receiving switch module is used for controlling the opening or closing of the water receiving port;

and the water flow identification module is used for controlling the water flow sensor to be started or closed.

the first liquid level module is used for controlling the first liquid level sensor to be started or closed;

the second liquid level module is used for controlling the second liquid level sensor to be started or closed;

and the electronic display module is used for controlling the electronic display screen to display the specified information.

the information receiving module is used for receiving information;

the electric switch module is used for controlling the opening or closing of the electric switch valve;

and the box body switch module is used for controlling the replacement box to be opened or closed.

and the water delivery telescopic module is used for controlling the telescopic mechanism to execute the set water delivery port telescopic operation according to the set steps.

The invention realizes the following beneficial effects:

1. after the intelligent rainwater utilization system is started, monitoring weather information of an area where a building is located in real time, controlling a collecting plate of a rainwater collecting shed to rotate and expand to form a rainwater collecting area after rainfall is identified, heating a water storage tank in the rainwater collecting shed and collecting heated liquid after the rainfall stops, and filtering and supplying the collected liquid to each water receiving cavity area of the building so that a building user can receive purified water supplied by a water receiving cavity by using the water storage tank; when the liquid in the water storage tank is lower than a second preset height, controlling the heater to stop heating and controlling an electronic display screen of the water receiving cavity to display the liquid capacity information of the water purifying tank in real time; when a user places the water storage tank on the water receiving platform, the water delivery port corresponding to the water receiving cavity extends out of the water storage tank to supply purified water.

2. After a water receiving pipe is inserted into the water receiving port area of the water receiving cavity, the water receiving port is opened to supply liquid to the water receiving pipe, and the water receiving port is controlled to be closed after the preset time is shorter than the preset water flow.

3. And when a replacing button of the water receiving cavity is pressed, the corresponding replacing box is controlled to be opened so that the user can replace the corresponding filter pipe.

Drawings

The accompanying drawings, which are incorporated in and constitute a part of this specification, illustrate embodiments consistent with the present disclosure and together with the description, serve to explain the principles of the disclosure.

FIG. 1 is a flow chart of an intelligent rain water utilization method according to one embodiment of the present invention;

fig. 2 is a flow chart of a water receiving port water supply method according to one example of the present invention;

FIG. 3 is a flow chart of a heating stop method provided by one example of the present invention;

FIG. 4 is a flow chart of a method of replacing a bin switch according to one embodiment of the present invention;

fig. 5 is a flow chart of a water delivery port expansion and contraction control method provided by one example of the invention;

fig. 6 is a connection relationship diagram of an intelligent rainwater utilization system according to an example of the present invention;

fig. 7 is a first schematic view of an area in which a rain water collecting shed is located according to an example of the present invention;

FIG. 8 is a second schematic view of an area in which a rain water collecting canopy is provided according to an example of the present invention;

FIG. 9 is a schematic partial sectional view showing an area where a fresh water tank is provided according to an example of the present invention;

fig. 10 is a schematic view of an area where a water receiving chamber is provided according to an example of the present invention.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments.

Example one

Referring to fig. 1, 3, and 5-10.

Specifically, the embodiment provides an intelligent rainwater utilization method based on circulation filtration, and the method includes the following steps:

in S1, specifically, after the information receiving module 58 included in the building controller 4 receives the monitoring instruction sent by the rainwater management department maintaining the long connection relationship, the outdoor capturing module 41 included in the building controller 4 controls the outdoor camera 10 disposed at the top position of the building to start capturing an outdoor image in real time, where the outdoor image is an environmental image of the top area of the building captured by the outdoor camera 10, and after the outdoor camera 10 is started, the information analyzing module 42 included in the building controller 4 analyzes whether rainfall occurs in the building area in real time according to the outdoor image.

In S2, specifically, after the information analysis module 42 analyzes that rainfall occurs in the building area, the collection rotation module 43 included in the building controller 4 controls the rotation mechanism 12 disposed at the top of the rainwater collection shed 11 on the building rooftop to drive the connected collection plate 13 to rotate and expand to form a rainwater collection area, so as to collect rainwater in real time and guide the rainwater into the water storage tank 14 of the rainwater collection shed 11, and meanwhile, the information analysis module 42 analyzes whether the rainfall in the building area has stopped in real time according to the outdoor image.

In S3, specifically, after the information analysis module 42 analyzes that the rainfall in the building area has stopped, the collection rotation module 43 controls the collection plate 13 connected to the rotation mechanism 12 to rotate and reset, and the water storage heating module 44 included in the building controller 4 controls the heater 15 disposed at the bottom end of the water storage tank 14 inside the rainwater collection shed 11 to start to enter a heating state, so as to heat the rainwater in the water storage tank 14 to a boiling state in real time.

In S4, specifically, after the heater 15 is activated, the collection switch module 45 included in the building controller 4 controls the collection port 16 disposed at the bottom end of the inner wall of the rainwater collection shed 11 to be opened, so as to collect the liquid dripping after evaporation in real time, and after more than 15% of the liquid exists in the purification box 20, the filtration and purification module 46 included in the building controller 4 controls the filtration and purification module 21 disposed at the position outside the purification box 20 inside the building to be activated, so as to filter and purify the liquid in the purification box 20 in real time, and introduce the purified water after filtration and purification into the delivery pump.

In S5, specifically, after the filtration purifier 21 is started, the purification delivery module 47 included in the building controller 4 controls the delivery pump connected to the filtration purifier 21 to start to deliver the received purified water into the water delivery pipe 23, and the first pressure module 48 included in the building controller 4 controls the first pressure sensor 30 disposed at the position of the water receiving platform 25 of the water receiving cavity 24 in each floor of the building to start to obtain the pressure information in real time.

In S6, specifically after the first pressure platform is started, the water delivery switch module 49 included in the building controller 4 controls the water delivery port 32 corresponding to the water receiving platform 25 with pressure to open and deliver the liquid in the connected water delivery pipeline 23 to the water storage tank where the water receiving platform 25 is placed, and the ultrasonic identification module 50 included in the building controller 4 controls the ultrasonic sensor 33 arranged at the front end of the water delivery port 32 to start to acquire the liquid level height information of the water storage tank in real time.

In S7, specifically, after the ultrasonic sensor 33 is started, the information analysis module 42 analyzes whether the liquid level height in the water storage tank exceeds a first preset height in real time according to the liquid level height information of the water storage tank, where the first preset height is set to be 90% higher than the total height inside the water storage tank; after the information analysis module 42 analyzes that the liquid level in the water storage tank exceeds a first preset level, the water delivery switch module 49 controls the water delivery port 32 corresponding to the water storage tank to be closed, and meanwhile, the water receiving prompt module 51 included in the building controller 4 controls the prompt lamp 34 arranged at the position of the water receiving platform 25 corresponding to the water delivery port 32 to be started to enter a prompt state so as to prompt surrounding users that the water storage tank is fully loaded and timely taken.

in S30, specifically, after the heater 15 is started to heat the water storage tank 14, the first liquid level module 55 included in the building controller 4 controls the first liquid level sensor 17 disposed inside the water storage tank 14 to start to obtain first liquid level information in real time, and after the first liquid level sensor 17 is started, the information analysis module 42 analyzes whether the liquid in the water storage tank 14 is lower than a second preset height in real time according to the first liquid level information, where the second preset height is a height of the liquid in the water storage tank 14 lower than 15% of the total height of the water storage tank 14.

In S31, specifically, after the information analysis module 42 analyzes that the liquid level inside the water storage tank 14 is lower than a second preset level, the water storage heating module 44 controls the heater 15 inside the water storage tank 14 to stop heating, and the second liquid level module 56 included in the building controller 4 controls the second liquid level sensor 28 disposed inside the purified water tank to start to obtain second liquid level information in real time;

in S32, specifically, after the second liquid level sensor 28 is started, the electronic display module 57 included in the building control module controls the electronic display screen 29 disposed on the outer wall of the water receiving cavity 24 to display the water storage amount information of the purified water tank in real time according to the second liquid level information.

As a preferred mode of the present invention, after the water receiving platform 25 is placed with the water storage tank, the method further comprises the following steps:

in S500, specifically, after the water storage tank is placed on the water receiving platform 25, the water delivery expansion module 61 included in the building controller 4 controls the expansion mechanism 31 corresponding to the water receiving platform 25 with pressure to drive the water delivery port 32 to extend and insert into the water storage tank of the water receiving platform 25, and after the water delivery port 32 is completely extended, the water delivery switch module 49 controls the water delivery port 32 to open and deliver the liquid in the connected water delivery pipeline 23 into the water storage tank.

In S50, specifically, after the water delivery port 32 is opened, the ultrasonic identification module 50 included in the building controller 4 controls the ultrasonic sensor 33 arranged at the front end of the water delivery port 32 to start to obtain the liquid level height information of the water storage tank in real time, after the ultrasonic sensor 33 is started, the information analysis module 42 analyzes whether the liquid level height in the water storage tank exceeds a first preset height in real time according to the liquid level height information of the water storage tank, after the information analysis module 42 analyzes that the liquid level in the water storage tank exceeds the first preset height, the water delivery switch module 49 controls the water delivery port 32 corresponding to the water storage tank to be closed, and meanwhile, the water delivery expansion module 61 controls the expansion mechanism 31 corresponding to the water receiving platform 25 with pressure to drive the water delivery port 32 to be completely contracted and reset.

Example two

Referring to fig. 2, fig. 6, fig. 10.

Specifically, this embodiment is substantially the same as the first embodiment, except that in this embodiment, after S5, the method further includes the following steps:

in S50, specifically after the information analysis module 42 analyzes that there is no pressure on the water receiving platform 25, the second pressure module 52 included in the building controller 4 controls the second pressure sensor 35 disposed inside the water receiving port 26 below the water receiving chamber 24 where the water receiving platform 25 is located to start to obtain pressure information in real time, and after the second pressure sensor 35 is started, the information analysis module 42 analyzes whether the water receiving port 26 has a water receiving pipe inserted therein in real time according to the pressure information, that is, whether a user has inserted the water receiving pipe into the water receiving port 26 is analyzed, so that the area of the water receiving port 26 is abutted to object pressure.

In S51, specifically, after the information analysis module 42 analyzes that the water receiving opening 26 is inserted into the water receiving pipe, the water receiving switch module 53 included in the building controller 4 controls the water receiving opening 26 to be opened so as to supply the liquid inside the water delivery pipe 23 into the inserted water receiving pipe, and the water flow identification module 54 included in the building controller 4 controls the water flow sensor 27 disposed at the connection position of the water receiving opening 26 and the water delivery pipe 23 to start to acquire the water flow information of the water receiving opening 26 in real time.

In S52, specifically after the water flow sensor 27 is started, the information analysis module 42 analyzes whether the water pipeline 23 has a preset time lower than a preset water flow in real time according to the water flow information, where the preset time is set by a rainwater management department, and is preferably 10 minutes in this embodiment; the preset water flow rate is preferably 1 liter/min in this embodiment.

In S53, specifically, after the information analysis module 42 analyzes that the preset time of the water pipeline 23 is shorter than the preset water flow, the water receiving switch module 53 controls the water receiving opening 26 to be closed, and the water flow identification module 54 controls the water flow sensor 27 to be closed.

EXAMPLE III

Referring to fig. 4, 6, 10.

Specifically, the present embodiment is substantially the same as the first embodiment, and the difference is that in the present embodiment, the method further includes the following steps:

in S100, the information receiving module 58 included in the building controller 4 receives the status information of the replacement button 36 disposed at the outer surface of the water receiving chamber 24 in real time, and the information analyzing module 42 analyzes whether the replacement button 36 is pressed in real time according to the status information.

In S101, specifically, after the information analysis module 42 analyzes that the replacement button 36 is in the pressed state, the electric switch module 59 included in the building controller 4 controls the electric switch valve 38 disposed in the water receiving cavity 24 where the replacement button 36 is located, corresponding to the water pipe 23, to be closed, and the box switch module 60 included in the building controller 4 controls the replacement box 37 corresponding to the water pipe 23 to be opened, so that the user can take out the filter pipe inside the replacement box 37 and replace the filter pipe with a new filter pipe.

In S102, specifically, after the replacement box 37 is opened, the information analysis module 42 analyzes whether the replacement button 36 has a press release state in real time, and after the information analysis module 42 analyzes that the replacement button 36 has a press release state, the box switch module 60 controls the replacement box 37 corresponding to the water pipe 23 to be closed, and simultaneously the electric switch module 59 controls the electric switch valve 38 in the water pipe 23 corresponding to the water receiving cavity 24 where the replacement button 36 is located to be opened.

Example four

As shown with reference to fig. 6-10.

Specifically, the embodiment provides an intelligent rainwater utilization system based on circulation filtration, and an intelligent rainwater utilization method based on circulation filtration is used, and comprises a collecting and evaporating device 1, a conveying device 2, a service device 3 and a building controller 4;

the collecting and evaporating device 1 comprises an outdoor camera 10, a rainwater collecting shed 11, a rotating mechanism 12, a collecting plate 13, a water storage tank 14, a heater 15, a collecting port 16 and a first liquid level sensor 17, wherein the outdoor camera 10 is arranged at the top of a building and used for shooting an environment image around the building; the rainwater collection shed 11 is arranged in a building rooftop area; the rotating mechanism 12 is arranged at the top end of the rainwater collecting shed 11, is connected with the collecting plate 13 and is used for driving the connected collecting plate 13 to rotate; the collecting plate 13 is connected with the rotating mechanism 12 and is used for collecting rainwater after rotating or sealing the rainwater collecting shed 11; the water storage tank 14 is arranged inside the rainwater collecting shed 11 and used for storing rainwater; the heater 15 is arranged at the bottom end of the water storage tank 14 and used for heating the water storage tank 14; the collecting port 16 is arranged on the ground position of the inner wall of the rainwater collecting shed 11 and is used for collecting distilled water; the first liquid level sensor 17 is arranged at the inner position of the water storage tank 14 and is used for acquiring the liquid level height in the water storage tank 14;

the conveying device 2 comprises a purification box 20, a filtering purifier 21, a water conveying pump 22, a water conveying pipeline 23, a water receiving cavity 24, a water receiving platform 25, a water receiving port 26, a water flow sensor 27, a second liquid level sensor 28 and an electronic display screen 29, wherein the purification box 20 is arranged at the position inside the building and used for storing collected distilled water; the filtering purifier 21 is arranged at an external position of the purifying box 20 and is used for filtering and purifying the liquid in the purifying box 20; the water delivery pump 22 is connected with the filtering purifier 21 through a hose and is connected with the water delivery pipeline 23, and is used for guiding the liquid filtered and purified by the filtering purifier 21 into the water delivery pipeline 23; the water conveying pipeline 23 is respectively connected with the water conveying pump 22 and the water receiving cavity 24; the water receiving cavity 24 is arranged at the inner position of each floor of the building and is used for supplying filtered and purified liquid; the water receiving platform 25 is arranged in the middle of the water receiving cavity 24 and used for placing a water storage tank; the water receiving port 26 is arranged at the lower end of the water receiving cavity 24 and is connected with the water conveying pipeline 23 connected with the water receiving cavity 24; the water flow sensor 27 is arranged at the connection position of the water receiving opening 26 and the water pipeline 23, and is used for acquiring water flow information transmitted to the water receiving opening 26 by the water pipeline 23; the second liquid level sensor 28 is disposed at an internal position of the purification box 20, and is configured to obtain a liquid level height in the purification box 20; the electronic display screen 29 is arranged at the outer surface of the water receiving cavity 24 and is used for displaying information;

the service device 3 comprises a first pressure sensor 30, a telescopic mechanism 31, a water delivery port 32, an ultrasonic sensor 33, a prompting lamp 34, a second pressure sensor 35, a replacement button 36, a replacement box 37 and an electric switch valve 38, wherein the first pressure sensor 30 is arranged at the position of the water receiving platform 25 and used for acquiring pressure information of the water receiving platform 25; the telescopic mechanism 31 is arranged in the water receiving cavity 24, is connected with the water delivery port 32 and is used for driving the connected water delivery port 32 to stretch; the water delivery port 32 is arranged at the position of the water receiving cavity 24 above the water receiving platform 25, is respectively connected with the telescopic mechanism 31 and the water delivery pipeline 23, and is used for supplying liquid; the ultrasonic sensor 33 is arranged at the front end of the water delivery port 32 and is used for acquiring the height information of the liquid in the water storage tank corresponding to the water delivery port 32; the prompting lamp 34 is arranged at the position of the water receiving platform 25 and used for providing a prompting function; the second pressure sensor 35 is arranged at the position of the water receiving port 26 and is used for acquiring information of an object collided by the water receiving port 26; the replacement button 36 is arranged at a position outside the water receiving cavity 24; the replacing box 37 is arranged at the outer position of the water conveying pipeline 23 above the water receiving cavity 24; the electric switch valve 38 is arranged at the inner position of the water conveying pipeline 23 above the water receiving cavity 24;

wherein, the water pipe 23 position in the change case 37 with you has placed the filter tube, and the filter tube is used for carrying out the secondary purification for water pipe 23 carries the liquid to water receiving chamber 24 to make the pure water can directly drink.

Building controller 4 sets up in the place position of building rainwater management department planning, building controller 4 includes:

the wireless module 40 is used for being wirelessly connected with the outdoor camera 10, the rotating mechanism 12, the heater 15, the collecting port 16, the first liquid level sensor 17, the filtering purifier 21, the water delivery pump 22, the water receiving port 26, the water flow sensor 27, the second liquid level sensor 28, the electronic display screen 29, the first pressure sensor 30, the telescopic mechanism 31, the water delivery port 32, the ultrasonic sensor 33, the prompting lamp 34, the second pressure sensor 35, the replacing button 36, the replacing box 37, the electric switch valve 38, the rainwater management department and the internet respectively;

an outdoor shooting module 41 for controlling the outdoor camera 10 to start or close;

an information analysis module 42 for processing and analyzing information according to the specified information;

a collection rotating module 43 for controlling the rotating mechanism 12 to perform the set rotation operation of the collection plate 13 according to the set steps;

the water storage heating module 44 is used for controlling the heater 15 to be started or closed;

a collection switch module 45 for controlling the opening and closing of the collection port 16;

the filtering and purifying module 46 is used for controlling the filter purifier 21 to be started or closed;

a purge delivery module 47 for controlling the delivery pump to start or stop;

a first pressure module 48 for controlling the first pressure sensor 30 to turn on or off;

the water delivery switch module 49 is used for controlling the opening or closing of the water delivery port 32;

the ultrasonic identification module 50 is used for controlling the ultrasonic sensor 33 to be started or closed;

and the water receiving prompt module 51 is used for controlling the prompt lamp 34 to be started or closed.

As a preferred aspect of the present invention, the building controller 4 further includes:

a second pressure module 52 for controlling the second pressure sensor 35 to turn on or off;

the water receiving switch module 53 is used for controlling the opening or closing of the water receiving port 26;

and the water flow identification module 54 is used for controlling the water flow sensor 27 to be started or closed.

a first liquid level module 55 for controlling the first liquid level sensor 17 to be turned on or off;

a second level module 56 for controlling the second level sensor 28 to turn on or off;

and an electronic display module 57 for controlling the electronic display screen 29 to display the specified information.

an information receiving module 58 for receiving information;

an electric switch module 59 for controlling the opening or closing of the electric switch valve 38;

and a box body switch module 60 for controlling the opening or closing of the replacement box 37.

and the water delivery telescopic module 61 is used for controlling the telescopic mechanism 31 to execute the set telescopic operation of the water delivery port 32 according to the set steps.

It should be understood that, in the fourth embodiment, the specific implementation process of each module described above may correspond to the description of the above method embodiments (the first to the third embodiments), and is not described in detail here.

The system provided in the fourth embodiment is only illustrated by dividing the functional modules, and in practical applications, the above-mentioned functions may be distributed by different functional modules according to needs, that is, the internal structure of the system is divided into different functional modules to complete all or part of the functions described above.

The above embodiments are merely illustrative of the technical ideas and features of the present invention, and are intended to enable those skilled in the art to understand the contents of the present invention and implement the present invention, and not to limit the scope of the present invention. All equivalent changes or modifications made according to the spirit of the present invention should be covered within the protection scope of the present invention.

Claims

1. An intelligent rainwater utilization method based on circulating filtration is characterized by comprising the following steps:

2. The intelligent rainwater utilization method based on circulation filtering according to claim 1, wherein after S5, the method further comprises the following steps:

3. The intelligent rainwater utilization method based on circulation filtering according to claim 1, wherein after S3, the method further comprises the following steps:

4. The intelligent rainwater utilization method based on circulation filtering according to claim 1, characterized in that the method further comprises the following steps:

5. The intelligent rainwater utilization method based on circulation filtration according to claim 1, wherein after the water storage tank is placed on the water receiving platform, the method further comprises the following steps:

6. An intelligent rainwater utilization system based on circulation filtration, which uses the intelligent rainwater utilization method based on circulation filtration of any one of claims 1-5, and comprises a collection evaporation device, a conveying device, a service device and a building controller, and is characterized in that:

7. The intelligent rainwater utilization system based on circulation filtering according to claim 6, wherein said building controller further comprises:

8. The intelligent rainwater utilization system based on circulation filtering according to claim 6, wherein said building controller further comprises:

9. The intelligent rainwater utilization system based on circulation filtering according to claim 6, wherein said building controller further comprises:

the information receiving module is used for receiving information;

10. The intelligent rainwater utilization system based on circulation filtering according to claim 6, wherein said building controller further comprises: