CN113110358A

CN113110358A - Wisdom building integrated management system based on waste water circulation handles

Info

Publication number: CN113110358A
Application number: CN202110530948.8A
Authority: CN
Inventors: 周文波
Original assignee: Individual
Current assignee: Individual
Priority date: 2021-05-15
Filing date: 2021-05-15
Publication date: 2021-07-13

Abstract

An intelligent building integrated management system based on wastewater circulation treatment comprises a wastewater pipeline splitter, a transfer booster pump, a wastewater sedimentation tank, a solid-liquid separation device, a wastewater collection device consisting of a liquid conveying pipeline and a solid conveying channel, a wastewater treatment device consisting of a distillation device, a water purification pipeline, an incineration chamber and an ash conveying pipeline, a wastewater service device consisting of a refrigeration device, an electric conveying pipeline, a cold air chamber, a cold air conveying pipeline, a water purification booster pump and a water purification pipeline splitter, a controller respectively connected with the water pipeline splitter, the transfer booster pump, the solid-liquid separation device, the solid conveying channel, the distillation device, the incineration chamber, the electric conveying mechanism, the refrigeration device, the electric conveying pipeline, an air supply device, the water purification booster pump and the water purification pipeline splitter, and a server connected with the controller and used for receiving water-saving signals sent by a water management department and forwarding the received water-saving signals to the controller .

Description

Wisdom building integrated management system based on waste water circulation handles

Technical Field

The invention relates to the field of building wastewater treatment, in particular to an intelligent building comprehensive management system based on wastewater circulating treatment.

Background

The treatment and reuse of reclaimed water is an effective win-win method for water conservation and pollution control; the method is applied to domestic sewage and part of industrial sewage in living communities, building communities, hotels, nursing homes, comprehensive buildings and the like. After treatment, the reclaimed water can be used for a variety of purposes. The reclaimed water mainly refers to non-drinking water which can reach a certain water quality standard after urban sewage or domestic sewage is treated and can be reused in a certain range, the water quality is between that of water feeding and water discharging, and the reclaimed water recycling is to recycle the urban sewage as a renewable resource after being treated. Because the urban sewage has stable water quantity and economic capital investment, the reclaimed water reuse is taken as a preferred scheme for solving the problem of water shortage in many countries. Therefore, the reclaimed water recycling work is carried out, and the dual effects of opening sources and reducing pollution are shown.

Therefore, when waste water treatment is carried out, how to combine the recovery and treatment of the building water so as to utilize a sedimentation tank to store the waste water and carry out solid-liquid separation on the waste water, distill and recycle a liquid part and burn a solid part to improve the recycling of the building waste water is a technical problem to be solved.

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 building integrated management system based on wastewater recycling treatment, which can effectively solve the problems in the background art.

The technical scheme is as follows:

the utility model provides an wisdom building integrated management system based on waste water circulation is handled, includes:

the waste water collecting device consists of a waste water pipeline splitter, a transfer booster pump, a waste water sedimentation tank, solid-liquid separation equipment, a liquid conveying pipeline and a solid conveying channel; the waste water pipeline splitter is respectively connected with a non-sanitary waste water discharge pipeline and a transfer hydraulic pump arranged in a building house and is provided with a plurality of electric switch valves and check valves; the transfer hydraulic pump is respectively connected with a water outlet pipeline of the wastewater pipeline diverter and the wastewater sedimentation tank; the wastewater sedimentation tank is arranged in a wastewater treatment chamber at the bottom layer of the building; the solid-liquid separation equipment is arranged outside the bottom end of the wastewater sedimentation tank and is respectively connected with a water outlet of the wastewater sedimentation tank, a liquid conveying pipeline and a solid conveying channel; the liquid conveying pipeline is respectively connected with the solid-liquid separation equipment and the distillation equipment; the solid conveying pipeline is respectively connected with the solid-liquid separation equipment and the incineration chamber and is internally provided with a screw conveyor;

a waste water treatment device consisting of a distillation device, a purified water pipeline, an incineration chamber and an ash conveying pipeline; wherein, the distillation equipment is arranged in a wastewater treatment chamber at the bottom layer of the building and is respectively connected with the liquid conveying pipeline and the purified water pipeline; the purified water pipeline is respectively connected with the distillation equipment and the refrigeration equipment; the incineration chamber is respectively connected with a solid conveying pipeline and an ash conveying pipeline; the ash conveying pipeline is respectively connected with the incineration chamber and a recovery box arranged at the bottom layer of the building, an electric conveying mechanism is arranged in the ash conveying pipeline, and collecting grooves are distributed on the outer surface of the electric conveying mechanism;

the waste water service device consists of refrigeration equipment, an electric conveying pipeline, a cold air chamber, a cold air conveying pipeline, a purified water booster pump and a purified water pipeline diverter; wherein the refrigeration equipment is respectively connected with the water purification pipeline and the electric conveying pipeline; the electric conveying pipeline is respectively connected with the refrigeration equipment and the cold air chamber and is internally provided with a waterproof electric conveying belt; the cold air chamber is respectively connected with the electric conveying pipeline and the cold air conveying pipeline; the cold air conveying pipeline is respectively connected with the cold air chamber and the building ventilation system and is internally provided with an air supply device which extracts air in the cold air chamber and guides the air into the building ventilation system; the purified water booster pump is respectively connected with the purified water pipeline and the purified water pipeline splitter, and an electric switch valve is arranged in the connection area of the purified water booster pump and the purified water pipeline; the water purification pipeline splitter is respectively connected with the water purification booster pump and a water supply pipeline of non-kitchen water arranged in each house of the building, and is provided with a plurality of electric switch valves and check valves;

a controller respectively connected with the water pipeline diverter, the transfer booster pump, the solid-liquid separation equipment, the solid conveying channel, the distillation equipment, the incineration chamber, the electric conveying mechanism, the refrigeration equipment, the electric conveying pipeline, the air supply equipment, the purified water booster pump and the purified water pipeline diverter; and

and the server is connected with the controller and is used for receiving the water saving signal sent by the water consumption management department and forwarding the received water saving signal to the controller.

As a preferred mode of the present invention, the present invention further comprises a water flow calculation unit, wherein the water flow calculation unit comprises a water flow sensor, an information processor and a first display device, the water flow sensor is arranged in the main water supply pipeline, the purified water pipeline and the purified water pipeline splitter of each house of the building and is connected with the controller and the information processor; the first display equipment is arranged in an entrance and exit area of the bottom layer of the building and is connected with the information processor; the information processor is arranged in the area where the first display equipment is located and is respectively connected with the first display equipment and the controller.

As a preferred mode of the present invention, the water flow calculating unit further includes a wastewater calculating module, a water supply calculating module and a drainage calculating module, wherein the wastewater calculating module is internally disposed in the information processor; the water supply calculation module is arranged in the information processor; and the ranking calculation module is respectively connected with the wastewater calculation module and the water supply calculation module.

In a preferred embodiment of the present invention, the water flow calculating unit further includes a second display device, which is disposed inside each house of the building and connected to the information processor.

As a preferred mode of the invention, the building roof drainage system further comprises a residual water collecting device, wherein the residual water collecting device comprises a drainage layer, a drainage port and a rainwater pipeline diverter, and the drainage layer is arranged in the building roof area; the drainage port is arranged at the bottom end of the drainage layer and is respectively connected with the drainage layer and the rainwater pipeline diverter; rainwater pipeline shunt is connected and is connected with the controller with drainage mouth, waste water sedimentation tank and direct supply pipe respectively, and is provided with a plurality of electric switch valves and check valve.

As a preferred mode of the invention, the residual water collecting device further comprises a control knob, a circulating filter and a direct supply pipeline, wherein the control knob is arranged inside the building and connected with the controller; the circulating filter is respectively connected with the rainwater pipeline flow divider, the direct supply pipeline and the solid conveying channel and is connected with the controller; the direct supply pipeline is respectively connected with the circulating filter and a sanitary water pipeline inside the building house.

As a preferred mode of the present invention, the residual water collecting device further includes a dehumidifier, a water conduit, a first water conduit, a hot water transfer storage bin, a second water conduit, a third water conduit, a cold water transfer storage bin, and a fourth water conduit; the dehumidifier is arranged at the top end in the building house, is connected with the water guide pipeline and is connected with the controller; the water guide pipeline is respectively connected with the dehumidifier and the wastewater sedimentation tank; the first water guide pipe is respectively connected with a hot water pipeline inside a house of a building resident and a water inlet of the heat transfer storage bin and is connected with the controller; the hot dump bin is respectively connected with the first water guide pipe and the second water guide pipe and is connected with the controller; the second water guide pipe is respectively connected with a water outlet of the heat transfer storage bin and a hot water pipeline inside a house of a building resident; the third water guide pipeline is respectively connected with a hot water pipeline inside a house of a building resident and a water inlet of the cold transfer storage bin and is connected with the controller; the cold transfer storage bin is connected with the third water guide pipe and the fourth water guide pipe respectively and is connected with the controller; the fourth water guide pipe is respectively connected with a water outlet of the cold transfer storage bin and a cold water pipeline inside a house of a building resident; and a temperature sensor and an electric switch valve are arranged in the first water guide pipe, the second water guide pipe, the third water guide pipe and the fourth water guide pipe.

As a preferred mode of the present invention, the intelligent building integrated management system includes the following steps:

if the server receives a water-saving signal sent by a water consumption management department, the server forwards the water-saving signal to a connected controller, and the controller sends a wastewater collection signal to a connected wastewater pipeline diverter and a transit hydraulic pump according to the water-saving signal;

the waste water pipeline diverter diverts and guides waste water in a non-sanitary waste water discharge pipeline arranged in a building house into a transfer hydraulic pump according to a waste water collecting signal, and the transfer hydraulic pump boosts and conveys the waste water to a connected waste water sedimentation tank according to the waste water collecting signal;

the controller sends solid-liquid conveying signals to the connected solid-liquid separation equipment and the solid conveying channel, the solid-liquid separation equipment carries out solid-liquid separation treatment on the wastewater introduced by the wastewater sedimentation tank according to the solid-liquid conveying signals, introduces liquid into the connected liquid conveying pipeline and introduces solid into the connected solid conveying channel, and the solid conveying channel conveys the solid to the incineration chamber by using a built-in spiral conveyor according to the solid-liquid conveying signals;

the controller sends processing signals to connected distillation equipment and an incineration chamber at intervals of first preset time or preset solid-liquid value, the distillation equipment starts to distill the introduced liquid in real time according to the processing signals and guides the collected distilled water into a connected purified water pipeline and a connected purified water booster pump according to a preset proportion, and the incineration chamber starts to incinerate the introduced solid in real time according to the processing signals;

after the distillation equipment is started for a second preset time and the water-saving signal contains cooling information, the controller sends a freezing signal to the connected freezing equipment and sends a cooling signal to the connected electric conveying equipment and the air supply equipment, the freezing equipment is started to enter an ice making state according to the freezing signal and guides made ice blocks into the connected electric conveying equipment in real time, the electric conveying equipment is started to convey the guided ice blocks into the connected freezing chamber in real time according to the cooling signal, and the air supply equipment is started to enter a cold air conveying state according to the cooling signal;

after the distillation equipment is started for a second preset time and the water saving signal does not contain cooling information, the controller sends a split water supply signal to a connected water purification booster pump and a water purification pipeline diverter, the water purification booster pump is started to enter a boosting conveying state according to the split water supply signal, and the water purification pipeline diverter supplies distilled water to water supply pipelines which are connected with each house of the building and are not used for kitchen according to the split water supply signal;

after the incineration chamber is started for the second preset time, the controller sends an ash conveying signal to the connected electric conveying mechanism, and the electric conveying mechanism is started to enter an ash conveying state according to the ash conveying signal.

As a preferred mode of the present invention, the intelligent building integrated management system further comprises the following working steps:

the controller sends a water flow collecting signal to a connected water flow sensor according to the water saving signal, and the water flow sensor starts to acquire water flow information of a pipeline in real time according to the water flow collecting signal and transmits the collected water flow information to the information processor in real time;

the information processor receives the water flow information in real time, calculates the water flow of each resident of the building in real time through the wastewater calculation module, arranges the calculated water flow of each resident of the building in real time according to a preset sequence through the ranking calculation module, generates ranking information and controls the connected first display equipment to display the calculated ranking information in real time;

the information processor calculates purified water supply information matched with the water flow of each resident of the building in real time through the water supply calculation module and the row calculation module and transmits the purified water supply information to the connection controller in real time;

the controller sends a split water supply signal containing real-time purified water supply information to a connected purified water pipeline splitter, and the purified water pipeline splitter supplies distilled water with matched water flow rate to water supply pipelines of non-kitchen water arranged in various houses of a connected building according to the real-time purified water supply information;

and the information processor controls the connected second display equipment to correspond to the water flow of the resident and the corresponding ranking information in real time.

As a preferable mode of the present invention, the intelligent building integrated management system further includes:

the controller receives a selection signal fed back by a connected control knob in real time according to a water saving signal and sends a humidity control signal to a connected dehumidifier, and the dehumidifier starts to regulate and control the humidity inside each house of the building in real time according to the humidity control signal and guides liquid into a connected wastewater sedimentation tank through a water guide pipeline;

if the building control analyzes that the direct supply signal is contained according to the selection signal, the direct supply signal is sent to the connected rainwater pipeline diverter and the circulating filter matched with the control knob, the rainwater pipeline diverter starts to divert the liquid guided by the drainage port to the circulating filter according to the direct supply signal, the circulating filter starts to filter the liquid according to the direct supply signal, and the filtered water is guided into the sanitary water pipeline inside the connected building house through the direct supply pipeline.

The invention realizes the following beneficial effects:

1. the comprehensive management system for the intelligent buildings collects domestic wastewater of each family of the buildings in real time by using the wastewater pipeline diverter and conveys the domestic wastewater to the wastewater sedimentation tank by using the transfer booster pump, then solid-liquid separation is carried out on the wastewater by using solid-liquid separation equipment, liquid is conveyed to distillation equipment by using a liquid conveying pipeline, solid is conveyed into an incineration chamber by using a solid conveying channel, then the distillation equipment distills the received liquid and guides the collected distilled water into a purified water pipeline, the incineration chamber incinerates the guided solid and drops the incinerated ash into an ash conveying pipeline, then the purified water pipeline guides the distilled water into refrigeration equipment and a purified water booster pump according to a set proportion, and the ash collected by a collecting tank is guided into a recovery tank by using an electric conveying mechanism in the ash conveying pipeline; the liquid introduced into the refrigeration equipment is processed into ice blocks by the refrigeration equipment and is conveyed into a cold air chamber through an electric conveying pipeline, and then the air supply equipment conveys cold air in the cold air chamber to a ventilation system of the building through the cold air conveying pipeline so as to cool each family of the building; the purified water introduced into the purified water booster pump is supplied to a water supply pipeline for non-kitchen water of each family of the building through a purified water pipeline splitter.

2. The comprehensive management system for the intelligent building records the water flow of each household of the building in real time through the water flow sensor, ranks according to the water flow of each household, and then supplies distilled water to each household of the building according to the ranks so as to improve the water-saving consciousness of the household.

3. According to the invention, rainwater and liquid formed after dehumidification by the dehumidifier are collected, and if a resident needs rainwater direct supply, filtered rainwater is supplied to a sanitary water pipeline in the house of the resident by using the rainwater pipeline shunt, the circulating filter and the direct supply pipeline; and the residual unused hot water in the hot water pipeline of the first household is obtained through the first water guide pipe, then the hot water is supplied to the hot water pipeline of the second household needing hot water through the second water guide pipe, meanwhile, the residual cold water in the hot water pipeline of the second household is collected by the third water guide pipe and is compensated to the cold water pipeline of the first household through the fourth water guide pipe, so that the cold water wasted by the hot water released by the faucet is saved, and the hot water remained in the pipeline after the faucet uses the hot water.

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 connection relationship diagram of the intelligent building integrated management system provided by the invention.

FIG. 2 is a schematic view of a wastewater pipeline splitter and a transfer booster pump provided by the present invention.

FIG. 3 is a first schematic view of a wastewater sedimentation tank and a solid-liquid separation device provided by the invention.

FIG. 4 is a second schematic view of the wastewater sedimentation tank and the solid-liquid separation equipment provided by the invention.

FIG. 5 is a first schematic view of an ash transport conduit provided by the present invention.

FIG. 6 is a second schematic view of an ash transport conduit provided by the present invention.

FIG. 7 is a third schematic view of an ash transport conduit provided by the present invention.

Fig. 8 is a schematic diagram of a purified water booster pump and a purified water pipeline splitter according to the present invention.

Fig. 9 is a schematic view of the electric transportation passage and the cold air chamber provided by the present invention.

Fig. 10 is a schematic top view of a current guiding layer provided by the present invention.

Fig. 11 is a schematic view of a drainage layer and a rainwater pipeline diverter provided by the present invention.

Fig. 12 is a schematic view of the hot water piping region provided by the present invention.

Wherein, 1, a waste water collecting device;

2. a wastewater treatment device;

3. a wastewater service device;

4. a controller;

5. a server;

6. a water flow rate calculation unit;

7. a residual water collecting device;

10. a wastewater pipeline diverter;

11. a transfer booster pump;

12. a wastewater sedimentation tank;

13. a solid-liquid separation device;

14. a liquid delivery conduit;

15. a solids transfer passage;

20. a distillation apparatus;

21. a water purification pipeline;

22. an incineration chamber;

23. an ash transfer conduit;

24. collecting tank;

25. an electric conveying mechanism;

30. a refrigeration device;

31. an electric conveying pipeline;

32. a cold air chamber;

33. a cold air delivery duct;

34. an air supply device;

35. a purified water booster pump;

36. a clean water pipeline diverter;

60. a water flow sensor;

61. an information processor;

62. a first display device;

63. a waste water calculation module;

64. a water supply calculation module;

65. a ranking calculation module;

66. a second display device;

70. a drainage layer;

71. a drainage opening;

72. a rainwater pipeline diverter;

73. a control knob;

74. a circulating filter;

76. a dehumidifier;

77. a water guide pipeline;

78. a first water conduit;

79. an electric three-way ball valve;

80. a hot water pipe;

81. a cold water pipe;

82. a hot transfer storage bin;

83. a second water conduit;

84. cold transfer storage;

85. a third water guiding pipe.

Detailed Description

The technical solution in the embodiments of the present invention will be clearly and completely described below with reference to the accompanying drawings in the embodiments of the present invention.

Example one

As shown with reference to fig. 1-9.

Specifically, this embodiment provides an intelligent building integrated management system based on waste water circulation handles, including waste water collection device 1, waste water treatment device 2, waste water service device 3, controller 4 and server 5.

The wastewater collecting device 1 comprises a wastewater pipeline diverter 10, a transfer booster pump 11, a wastewater sedimentation tank 12, a solid-liquid separation device 13, a liquid conveying pipeline 14 and a solid conveying channel 15, wherein the wastewater pipeline diverter 10 is respectively connected with a non-sanitary wastewater discharge pipeline and a transfer hydraulic pump arranged in a building house and is provided with a plurality of electric switch valves and check valves; the transfer hydraulic pump is respectively connected with the water outlet pipeline of the wastewater pipeline diverter 10 and the wastewater sedimentation tank 12; the wastewater sedimentation tank 12 is disposed in a wastewater treatment room at the bottom of a building.

The solid-liquid separation equipment 13 is arranged outside the bottom end of the wastewater sedimentation tank 12 and is respectively connected with a water outlet of the wastewater sedimentation tank 12, a liquid conveying pipeline 14 and a solid conveying channel 15; the liquid conveying pipeline 14 is respectively connected with the solid-liquid separation equipment 13 and the distillation equipment 20; the solid transport duct is connected to the solid-liquid separation device 13 and the incineration chamber 22, respectively, and has a screw conveyor built therein.

Wherein, this waste water pipeline shunt 10 quantity corresponds with the building house number, and every family sets up a waste water pipeline shunt 10, and every waste water pipeline shunt 10 corresponds with the inside non-sanitary water pipeline of building house in proper order, and wherein sanitary water pipeline is the sewage pipes of closestool, and non-sanitary water pipeline includes but not only is limited to washing machine's drainage pipe, kitchen drainage pipe, bathing drainage pipe etc..

The number of the pipelines of the waste water pipeline diverter 10 is consistent with the number of non-sanitary water pipelines in a building house, each pipeline is provided with an electric switch valve and a check valve, the waste water pipeline diverter 10 collects waste water in a drainage pipeline, guides the waste water into a transfer booster pump 11, and then the waste water is pressurized and conveyed into a connected waste water sedimentation tank 12 by the transfer booster pump 11; the number of the intermediate booster pumps 11 corresponds to the number of the wastewater line splitters 10.

The wastewater sedimentation tank 12 is adjusted according to the number of building users and is adjusted by regional water management departments, and the wastewater sedimentation tank 12 is designed in an inverted trapezoid shape; the solid-liquid separation equipment 13 is used for carrying out solid-liquid separation operation on the liquid in the wastewater sedimentation tank 12 in real time; the liquid conveying pipeline 14 is used for conveying liquid after solid-liquid separation to a connected distillation device 20; the screw conveyor in the solid conveying pipeline is synchronously started when the solid-liquid separation equipment 13 is started, and is used for conveying the solid separated by the solid-liquid separation equipment 13 into the connected incineration chamber 22.

The wastewater treatment device 2 comprises a distillation device 20, a clean water pipeline 21, an incineration chamber 22, an ash conveying pipeline 23, a collecting tank 24 and an electric conveying mechanism 25, wherein the distillation device 20 is arranged in the wastewater treatment chamber at the bottom layer of the building and is respectively connected with the liquid conveying pipeline 14 and the clean water pipeline 21; the clean water pipe 21 is connected to the distillation apparatus 20 and the refrigeration apparatus 30, respectively.

The incineration chamber 22 is connected to a solid transfer pipe and an ash transfer pipe 23, respectively; the ash conveying pipeline 23 is respectively connected with the incineration chamber 22 and a recovery box arranged at the bottom layer of the building; the collection grooves 24 are distributed on the surface of a track of the electric conveying mechanism 25; the electric conveyor means 25 are arranged inside the ash conveying pipe 23 and are of a crawler-type conveying design.

Wherein, the volume of the distillation equipment 20 is set by a regional water management department, and the position of a wastewater treatment room of a building is also set by the regional water management department; the distillation apparatus 20 is used for distilling the introduced liquid and collecting and introducing the distilled water into a purified water pipeline 21; the purified water pipe 21 is used to supply the distilled water introduced from the distillation plant 20 to the connected refrigeration plant 30 and the purified water booster pump 35 at a ratio set by the regional water use control.

For example, if the setting is 1:9, 10% of distilled water is supplied to the refrigerating apparatus 30, 90% of distilled water is supplied to the purified water pressurizing pump 35 and pressurized by the purified water pressurizing pump 35 to be supplied to the water supply pipeline of non-kitchen water for each household of the building; the outer layer of the incineration chamber 22 is provided with a heat insulation layer, and the incineration chamber 22 is used for incinerating solid matters after solid-liquid separation; the ash conveying pipeline 23 is arranged at the bottom of the incineration chamber 22 and is used for conveying the ash incinerated in the incineration chamber 22 to a connected recovery box for recovery by a management department of a building area, and the ash can be used for fertilization and the like; the collection groove 24 is distributed on the surface of a conveying crawler belt of an electric conveying mechanism 25 and used for containing ash; this electronic conveying mechanism 25 includes transportation motor and transportation track, and transportation motor drive transportation track is leading-in to the collection tank with the ashes of holding in the collecting vat 24.

The waste water service device 3 comprises a refrigeration device 30, an electric conveying pipeline 31, a cold air chamber 32, a cold air conveying pipeline 33, an air supply device 34, a purified water booster pump 35 and a purified water pipeline diverter 36.

The refrigeration equipment 30 is connected with the clean water pipeline 21 and the electric conveying pipeline 31 respectively; the electric conveying pipeline 31 is respectively connected with the refrigeration equipment 30 and the cold air chamber 32 and is internally provided with a waterproof electric conveying belt; the cold air chamber 32 is connected to the electric transportation duct 31 and the cold air transportation duct 33; the cold air duct 33 is connected to the cold air chamber 32 and the building ventilation system, respectively.

The air supply device 34 is arranged inside the cold air conveying pipeline 33; the purified water booster pump 35 is respectively connected with the purified water pipeline 21 and the purified water pipeline splitter 36, and an electric switch valve is arranged in the connection area of the purified water booster pump 35 and the purified water pipeline 21; the purified water line diverter 36 is connected to the purified water booster pump 35 and a water supply pipeline for non-kitchen water installed in each building, and is provided with a plurality of electric switching valves and check valves.

Wherein the freezer 30 may be an ice maker for making ice cubes and the operation time of the freezer 30 is set by the regional water management department, preferably 5-10 months in this embodiment.

The electric conveying pipeline 31 is internally provided with an electric conveying belt and has a waterproof function, the electric conveying pipeline 31 is externally wrapped with an insulating layer, and the electric conveying pipeline 31 is used for conveying ice blocks manufactured by the refrigeration equipment 30 into a connected cold air chamber 32.

The cold air chamber 32 is used for placing ice cubes, is wrapped with an insulating layer outside and is internally provided with a drainage pipeline; the cool air duct 33 is used to introduce cool air in the cool air chamber 32 into a ventilation system of a building, and includes, but is not limited to, an air intake area of a central air conditioner, a house ventilation fan area, and the like.

The air supply device 34 is arranged in the connecting area of the cold air conveying pipeline 33 and the cold air chamber 32, and is used for accelerating the introduction of the cold air in the cold air chamber 32 into the cold air conveying pipeline 33 and then into the ventilation system of the building through the cold air conveying pipeline 33; the clean water pressurizing pump 35 is for pressurizing and supplying the liquid introduced from the clean water pipe 21 to the connected clean water line splitter 36.

The number of the purified water pipeline diverters 36 corresponds to the number of building households, each household is provided with one purified water pipeline diverter 36, and each purified water pipeline diverter 36 sequentially corresponds to a non-kitchen water pipeline in a building house, wherein the non-kitchen water pipelines comprise but are not limited to a sanitary water supply pipeline, a laundry water supply pipeline and a bathing water supply pipeline; the number of the pipes of the purified water pipe diverter 36 is the same as the number of the non-kitchen water pipes in the building house, and each pipe is provided with an electric switch valve and a check valve.

The controller 4 is installed in a control room planned in the building and is respectively connected with a water pipeline diverter, a transfer booster pump 11, a solid-liquid separation device 13, a solid conveying channel 15, a distillation device 20, an incineration chamber 22, an electric conveying mechanism 25, a refrigeration device 30, an electric conveying pipeline 31, an air supply device 34, a purified water booster pump 35, a purified water pipeline diverter 36 and a server 5.

And a server 5 connected to the controller 4 and receiving a water saving signal transmitted from a water consumption managing department and forwarding the received water saving signal to the controller 4.

The server 5 is arranged in a management department of an area where a building is located and is respectively connected with the controller 4, the fire-fighting center, the alarm center, the first-aid center and an area water management department.

The intelligent building integrated management system comprises the following working steps:

and S1, if the server 5 receives the water saving signal sent by the regional water consumption management department, the server forwards the water saving signal to the connected controller 4, and the controller 4 sends a wastewater collection signal to the connected wastewater pipeline diverter 10 and the relay hydraulic pump according to the water saving signal.

After the wastewater pipeline diverter 10 is started, a non-sanitary wastewater discharge pipeline and a main drainage pipeline in a building house are closed, wastewater discharged by the non-sanitary wastewater discharge pipeline is collected in real time and is guided into a wastewater sedimentation tank 12 through the pressurization of a transfer booster pump 11.

S2, the wastewater pipeline diverter 10 diverts and guides the wastewater in the non-sanitary wastewater discharge pipeline arranged in the building house into the transfer hydraulic pump according to the wastewater collection signal, and the transfer hydraulic pump boosts and conveys the wastewater to the connected wastewater sedimentation tank 12 according to the wastewater collection signal.

S3, the controller 4 sends a solid-liquid transfer signal to the solid-liquid separation device 13 and the solid transfer path 15 connected to each other, the solid-liquid separation device 13 performs solid-liquid separation treatment on the wastewater introduced from the wastewater sedimentation tank 12 based on the solid-liquid transfer signal to introduce the liquid into the liquid transfer line 14 connected to the solid transfer path 15, and the solid transfer path 15 transfers the solid to the incineration chamber 22 by the screw conveyor built in the solid-liquid transfer signal.

S4, the controller 4 sends processing signals to the connected distillation equipment 20 and the incineration chamber 22 every first preset time or solid-liquid preset value, the distillation equipment 20 starts to distill the introduced liquid in real time according to the processing signals and guides the collected distilled water into the connected purified water pipeline 21 and the purified water booster pump 35 according to the preset proportion, and the incineration chamber 22 starts to incinerate the introduced solid in real time according to the processing signals.

Wherein the first preset time is set by a regional water management department, and is preferably 30 minutes in the embodiment; the preset solid-liquid value is set by a regional water management department, and in the embodiment, 2 kilograms of solid and 2 liters of liquid are preferred; the preset ratio is set by regional water use management department, and the ratio of the clean water pipeline 21 to the clean water booster pump 35 is 1:9 in the embodiment.

And S4-1, after the distillation equipment 20 is started for a second preset time and the water saving signal contains temperature reduction information, the controller 4 sends a freezing signal to the connected freezing equipment 30 and sends a temperature reduction signal to the connected electric conveying equipment and the air supply equipment 34, the freezing equipment 30 is started to enter an ice making state according to the freezing signal and guides the made ice blocks into the connected electric conveying equipment in real time, the electric conveying equipment is started to convey the guided ice blocks to the connected freezing chamber in real time according to the temperature reduction signal, and the air supply equipment 34 is started to enter a cold air conveying state according to the temperature reduction signal.

Wherein the second predetermined time is set by the regional water management department, preferably 60 minutes in this embodiment.

S4-2, after the distillation apparatus 20 is started for a second preset time and the water saving signal does not include the temperature lowering information, the controller 4 sends a split water supply signal to the connected clean water booster pump 35 and the clean water line splitter 36, the clean water booster pump 35 is started to enter a boosting delivery state according to the split water supply signal, and the clean water line splitter 36 supplies the distilled water to the non-kitchen water supply pipes installed in the respective connected buildings according to the split water supply signal.

And S4-3, after the incineration chamber 22 is started for a second preset time, the controller 4 sends an ash conveying signal to the connected electric conveying mechanism 25, and the electric conveying mechanism 25 is started to enter an ash conveying state according to the ash conveying signal.

Wherein S4-1, S4-2 and S4-3 are branching steps after S4.

Example two

As shown with reference to fig. 1-9.

The present embodiment is substantially identical to the first embodiment, except that the present embodiment further comprises a water flow calculating unit 6, the water flow calculating unit 6 comprises a water flow sensor 60, an information processor 61 and a first display device 62, the water flow sensor 60 is disposed in each of the pipes of the building house, the purified water pipe 21 and the purified water pipe splitter 36 and connected to the controller 4 and the information processor 61; the first display device 62 is arranged in the entrance and exit area of the building bottom layer and is connected with the information processor 61; the information processor 61 is disposed in an area where the first display device 62 is located and connected to the first display device 62 and the controller 4, respectively.

Wherein, the first display device 62 is used for displaying the water consumption of the building residents, the water consumption of each household and the purified water supply of each household; so as to improve the water-saving consciousness of the user; the water flow sensor 60 is used to obtain the water consumption of the resident and the supply amount of the purified water.

The water flow calculating unit 6 further includes a waste water calculating module 63, a water supply calculating module 64 and a drainage calculating module 65, wherein the waste water calculating module 63 is arranged in the information processor 61; the water supply calculation module 64 is built in the information processor 61; the ranking calculation module 65 is connected to the waste water calculation module 63 and the water supply calculation module 64, respectively.

The waste water calculating module 63 is used for calculating the water consumption of the residents; the water supply calculation module 64 is used to calculate the clean water supply for the household water usage.

Wherein, the water flow calculating unit 6 further comprises a second display device 66, and the second display device 66 is arranged inside each house of the building and connected with the information processor 61.

Wherein, the number of the second display devices 66 is consistent with the number of the building users, and is used for displaying the water consumption, ranking and pure water supply of the residents.

The intelligent building integrated management system further comprises the following working steps:

s100, the controller 4 sends a water flow collecting signal to the connected water flow sensor 60 according to the water saving signal, and the water flow sensor 60 starts to acquire water flow information of the pipeline in real time according to the water flow collecting signal and transmits the collected water flow information to the information processor 61 in real time.

S101, the information processor 61 receives the water flow information in real time, calculates the water flow of each resident of the building in real time through the waste water calculation module 63, arranges the calculated water flow of each resident of the building in real time according to a preset sequence through the ranking calculation module 65, generates ranking information and controls the connected first display device 62 to display the calculated ranking information in real time.

The preset sequence is set by a regional water consumption management department, and is preferably arranged according to the water consumption of a user in the embodiment, namely the front row with low water consumption is arranged, and the rear row with high water consumption is arranged; the household with the least water consumption per day obtains the most distilled water, and the household with the most water consumption per day obtains the least distilled water, so that the water-saving consciousness of the household is improved.

And S102, the information processor 61 calculates purified water supply information matched with the water flow of each resident in the building in real time through the water supply calculation module 64 and the drainage calculation module 65 and transmits the purified water supply information to the connection controller 4 in real time.

The purified water is supplied in percentage, for example, 50 households, the distilled water amount generated per day is 5 tons, and the ranking list and the corresponding purified water supply amount are as follows without being supplied to the refrigeration equipment 30:

ranking	Supply quantity of purified water (kilogram)
		1	500
2	420
		3	380
4	345
		5	295
6	255
		7	225
8	187
		9	165
10	155

11-20 is decreasing by 5 kg (i.e. 11 is 120 kg, 20 is 75 kg), 21-30 is decreasing by 3 kg (i.e. 21 is 72 kg, 30 is 45 kg), 31-40 is decreasing by 2 kg (i.e. 31 is 43 kg, 40 is 27 kg), 41-50 is decreasing by 1 kg (i.e. 41 is 26 kg, 50 is 18 kg).

S103, the controller 4 sends the split water supply signal containing the real-time purified water supply information to the connected purified water pipeline splitter 36, and the purified water pipeline splitter 36 supplies distilled water with a flow rate matching with the water flow rate to the water supply pipelines of non-kitchen water installed in the connected buildings according to the real-time purified water supply information.

Wherein, the distilled water with the matched water flow is supplied, namely, the corresponding purified water quantity is supplied to each household, when the corresponding purified water quantity is supplied, the purified water pipeline diverter 36 is closed, and the building water supply system is communicated with the water supply pipeline of the non-kitchen water; for example, the first resident who is ranked is able to shut off the building water supply system and the water supply pipeline of the non-kitchen water for the resident when the daily supply amount is 500 kg of purified water, and then supply the purified water to the water supply pipeline of the non-kitchen water for the resident in real time, and when the resident runs out 500 kg of purified water, the water purification pipeline diverter 36 is shut off and connects the building water supply system and the water supply pipeline of the non-kitchen water; wherein the supply of clean water to the households is referenced to the ranking of the day before.

And S104, the information processor 61 controls the connected second display equipment 66 to correspond to the water flow of the resident and the corresponding row information in real time.

EXAMPLE III

Referring to fig. 1, fig. 3-4, and fig. 10-12.

The present embodiment is substantially the same as the second embodiment, except that the present embodiment further comprises a residual water collecting device 7, the residual water collecting device 7 comprises a drainage layer 70, a drainage port 71 and a rainwater pipeline diverter 72, the drainage layer 70 is placed in the building balcony area; the drainage port 71 is arranged at the bottom end of the drainage layer 70 and is respectively connected with the drainage layer 70 and the rainwater pipeline diverter 72; the rainwater pipeline diverter 72 is connected to the drainage port 71, the wastewater sedimentation tank 12, and the direct supply pipeline, is connected to the controller 4, and is provided with a plurality of electric switching valves and check valves.

The bottom end of the drainage layer 70 is provided with a hydraulic telescopic mechanism which can adjust the drainage angle so as to guide the collected rainwater to the drainage port 71; the rainwater pipeline diverter 72 guides rainwater at the drainage port 71 into the wastewater sedimentation tank 12 and/or the direct supply pipeline.

As a preferable mode of the present invention, the residual water collecting device 7 further comprises a control knob 73, a circulation filter 74 and a direct supply pipe, wherein the control knob 73 is arranged inside the building and connected with the controller 4; the circulation filter 74 is connected to the rainwater line diverter 72, the direct supply pipe, and the solids transfer passage 15, respectively, and to the controller 4; the direct supply pipe is connected to the circulation filter 74 and the sanitary water pipe inside the building house, respectively.

Wherein, the control knob 73 has two options, one is used for supplying water for a building water supply system, and the other is used for supplying water for filtering rainwater; the sanitary water pipeline is a water supply pipeline for sanitary appliances such as a closestool, a squatting pan, a urinal and the like; the number of the direct supply pipelines is consistent with that of the sanitary water pipelines of all residents in the building.

In a preferred embodiment of the present invention, the residual water collecting device 7 further includes a dehumidifier 76, a water conduit 77, a first water conduit 78, an electric three-way ball valve 79, a hot water pipe 80, a cold water pipe 81, a hot water dump bin 82, a second water conduit 83, a cold water dump bin 84, and a third water conduit 85, and the dehumidifier 76 is disposed at the top end inside the building, connected to the water conduit 77, and connected to the controller 4.

The water conduit 77 is connected to the dehumidifier 76 and the wastewater sedimentation tank 12; the first water guide pipe 78 is respectively connected with a hot water pipeline inside a building of a building resident and the electric three-way ball valve 79 and is connected with the controller 4; the electric three-way ball valve 79 has a water inlet connected to the first water conduit 78 and a water outlet connected to the hot water pipe 80 and the cold water pipe 81, respectively, and the electric three-way ball valve 79 is connected to the controller 4.

The hot water pipe 80 is respectively connected with the electric three-way ball valve 79 and the hot dump bin 82; the cold water pipe 81 is respectively connected with the electric three-way ball valve 79 and the cold transfer storage bin 84; the hot water transfer bin 82 is connected with the hot water pipe 80 and the second water guide pipe 83 respectively and connected with the controller 4; the second water guiding pipe 83 is connected to the water outlet of the heat storage bin 82 and a hot water pipeline inside the house of the building.

The cold transfer storage 84 is connected to the cold water pipe 81 and the third water conduit 85, respectively, and is connected to the controller 4; the third water guide pipe 85 is respectively connected with a water outlet of the cold transfer storage bin 84 and a cold water pipeline inside a house of a building resident; the first water conduit 78, the second water conduit 83, and the third water conduit 85 have a temperature sensor and an electric on/off valve inside.

The dehumidifier 76 is arranged inside the house of each household of the building, and one household can have more than one dehumidifier or only one dehumidifier; the water inlet of the first water guiding pipe 78 is connected with the middle area of the hot water pipeline, and an electric switch valve, a water flow sensor 60 and a temperature sensor are arranged at the connecting position of the first water guiding pipe 78 and the hot water pipeline; the water outlet of the second water guiding pipe 83 is connected with the water outlet area of the hot water pipeline, and an electric switch valve, a water flow sensor 60 and a temperature sensor are arranged at the connecting position of the second water guiding pipe 83 and the hot water pipeline.

The water inlet of the hot water pipe 80 is connected with the water outlet of the electric three-way ball valve 79, and the water outlet is connected with the hot transfer storage bin 82; the water inlet of the cold water pipe 81 is connected with the water outlet of the electric three-way ball valve 79, and the water outlet is connected with the cold transfer storage bin 84; the electric three-way ball valve 79 is provided with a temperature sensor and a water flow sensor 60 therein, and introduces hot water into the hot water pipe 80 and cold water into the cold water pipe 81 according to the water temperature.

The water outlet of the third water guide pipe 85 is connected with the middle area of the cold water pipeline, and an electric switch valve, a water flow sensor 60 and a temperature sensor are arranged at the connecting position of the third water guide pipe 85 and the cold water pipeline; the hot water pipeline is connected with the hot water outlet of the water heater, a water flow sensor 60 is arranged in the hot water pipeline, and the cold water pipeline is a tap water pipeline in the house.

s1000, the controller 4 receives the selection signal fed back by the connected control knob 73 in real time according to the water saving signal and sends a humidity control signal to the connected dehumidifier 76, and the dehumidifier 76 starts to regulate and control the humidity inside each house of the building in real time according to the humidity control signal and guides the liquid into the connected wastewater sedimentation tank 12 through the water guide pipeline 77.

The residual liquid after dehumidification by the dehumidifier 76 is introduced into the wastewater sedimentation tank 12 through a water guide pipe, and a check valve is disposed in the water guide pipe.

And S1001, if the building control analyzes that the direct supply signal is contained according to the selection signal, sending a direct supply signal to the connected rainwater pipeline diverter 72 and the circulating filter 74 matched with the control knob 73, wherein the rainwater pipeline diverter 72 starts to divert the liquid introduced by the drainage port 71 to the circulating filter 74 according to the direct supply signal, the circulating filter 74 starts to filter the liquid according to the direct supply signal, and the filtered water is introduced to a sanitary water pipeline inside the connected building house through the direct supply pipeline.

When a user needs rainwater direct supply, the rainwater pipeline diverter 72 is controlled to open the direct supply pipeline of the user so as to guide the filtered rainwater into the sanitary water pipeline of the user.

and S20, the controller 4 sends an identification signal to the connected water flow sensor 60 according to the water saving signal, the water flow sensor 60 starts to acquire water flow information in the pipeline in real time according to the identification signal, and feeds back a heat transfer signal to the controller 4 after recognizing that water flows and stops in the hot water pipeline of the first resident.

Wherein, the heat dump signal contains the number information of the hot water pipeline.

S21, the controller 4 sends hot water drainage signals to the first water guide pipe 78 and the electric three-way ball valve 79 which are connected with the corresponding hot water pipeline according to the hot water transfer signals, the first water guide pipe 78 opens to guide the residual hot water in the hot water pipeline into the connected electric three-way ball valve 79 according to the hot water drainage signals, and then the electric three-way ball valve 79 guides the hot water into the connected hot water pipe 80 according to the hot water drainage signals, so that the hot water pipe 80 guides the hot water into the connected hot water transfer bin 82.

Wherein the water flow sensor 60 of the first water conduit 78 records the water flow information of the hot water pipe flowing into the first water conduit 78.

S22, when the water flow sensor 60 recognizes that there is water flowing in the hot water pipe of the second household, it feeds back a heat supply signal to the controller 4, and the controller 4 sends a heat supply signal to the second water conduit 83 connected to the corresponding hot water pipe according to the heat supply signal and sends a cold dump signal to the first water conduit 78 and the electric three-way ball valve 79 connected to the corresponding hot water pipe.

Wherein, the heat supply signal contains the number information of the corresponding hot water pipeline.

S23, the second water conduit 83 opens the hot water in the hot water dump bin 82 to the hot water pipe until the hot water reaches the inlet of the hot water pipe according to the hot water supply signal, the first water conduit 78 opens the cold water in the hot water pipe to the electric three-way ball valve 79 according to the cold dump signal, and the electric three-way ball valve 79 guides the cold water left in the hot water pipe to the cold water pipe 81 according to the cold dump signal, so that the cold water pipe 81 guides the cold water to the cold dump bin 84.

Wherein, the water flow sensor 60 arranged in the second water guide pipe 83 records the water flow information entering the hot water pipeline in real time, and the water flow sensor 60 arranged in the cold water records the water flow information entering the cold water pipe 81 in real time; when the temperature sensor arranged in the cold water pipe 81 recognizes that the water temperature reaches 30 ℃, the electric three-way ball valve 79 automatically enters a closed state, and when the electric three-way ball valve 79 is automatically closed, the first water guide pipe 78 and the second water guide pipe 83 are automatically closed through the electric switch valve.

S24, after the first water conduit 78 and the second water conduit 83 are closed, the controller 4 sends a water supply signal containing the water flow information recorded by the water flow sensor 60 built in the second water conduit 83 to the third water conduit 85 corresponding to the first user, and the third water conduit 85 opens the cold water pipeline for supplying the cold water with the corresponding water flow in the cold dump bin 84 to the first user according to the water supply signal.

The hot water which is remained and not used in the hot water pipeline of the first household is obtained, then the hot water is supplied to the hot water pipeline of the second household needing hot water, and meanwhile, the cold water remained in the hot water pipeline of the second household is compensated to the cold water pipeline of the first household, so that the cold water wasted by the hot water discharged by the faucet is saved, and the hot water remained in the pipeline after the faucet uses the hot water.

For convenience of description, the dimensions of the various features shown in the drawings are not necessarily drawn to scale. Techniques, methods, and apparatus known to those of ordinary skill in the relevant art may not be discussed in detail but are intended to be part of the specification where appropriate.

Spatially relative terms, such as "disposed above … …," "disposed above … …," "disposed above … …, above," and the like, may be used herein for ease of description to describe the spatial relationship of one device or feature to another device or feature as illustrated in the figures. It will be understood that the spatially relative terms are intended to encompass different orientations of the device in use or operation in addition to the orientation depicted in the figures. For example, if a device in the figures is turned over, devices described as "above" or "on" other devices or configurations would then be oriented "below" or "under" the other devices or configurations. Thus, the exemplary term "disposed above … …" can include both an orientation of "disposed above … …" and "disposed below … …". The device may be otherwise variously positioned and the spatially relative descriptors used herein interpreted accordingly.

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. The utility model provides an wisdom building integrated management system based on waste water circulation handles which characterized in that includes:

2. The intelligent building integrated management system based on wastewater recycling treatment as claimed in claim 1, further comprising a water flow calculating unit, wherein the water flow calculating unit comprises a water flow sensor, an information processor and a first display device, the water flow sensor is arranged in a total water supply pipeline, a purified water pipeline and a purified water pipeline splitter of each house of the building and is connected with the controller and the information processor; the first display equipment is arranged in an entrance and exit area of the bottom layer of the building and is connected with the information processor; the information processor is arranged in the area where the first display equipment is located and is respectively connected with the first display equipment and the controller.

3. The intelligent building integrated management system based on wastewater recycling treatment as claimed in claim 2, wherein the water flow calculating unit further comprises a wastewater calculating module, a water supply calculating module and a drainage calculating module, the wastewater calculating module is arranged inside the information processor; the water supply calculation module is arranged in the information processor; and the ranking calculation module is respectively connected with the wastewater calculation module and the water supply calculation module.

4. The comprehensive management system for intelligent buildings based on wastewater recycling treatment as claimed in claim 3, wherein the water flow calculating unit further comprises a second display device, the second display device is disposed inside each house of the building and connected with the information processor.

5. The intelligent building integrated management system based on wastewater recycling treatment as claimed in claim 1, further comprising a residual water collecting device, wherein the residual water collecting device comprises a drainage layer, a drainage port and a rainwater pipeline diverter, and the drainage layer is placed in a building balcony area; the drainage port is arranged at the bottom end of the drainage layer and is respectively connected with the drainage layer and the rainwater pipeline diverter; rainwater pipeline shunt is connected and is connected with the controller with drainage mouth, waste water sedimentation tank and direct supply pipe respectively, and is provided with a plurality of electric switch valves and check valve.

6. The intelligent building integrated management system based on wastewater recycling treatment as claimed in claim 5, wherein the residual water collecting device further comprises a control knob, a circulating filter and a direct supply pipeline, the control knob is arranged inside the building house and connected with the controller; the circulating filter is respectively connected with the rainwater pipeline flow divider, the direct supply pipeline and the solid conveying channel and is connected with the controller; the direct supply pipeline is respectively connected with the circulating filter and a sanitary water pipeline inside the building house.

7. The intelligent building integrated management system based on wastewater recycling treatment as recited in claim 6, wherein the surplus water collecting device further comprises a dehumidifier, a water conduit, a first water conduit, a hot transfer storage bin, a second water conduit, a third water conduit, a cold transfer storage bin and a fourth water conduit; the dehumidifier is arranged at the top end in the building house, is connected with the water guide pipeline and is connected with the controller; the water guide pipeline is respectively connected with the dehumidifier and the wastewater sedimentation tank; the first water guide pipe is respectively connected with a hot water pipeline inside a house of a building resident and a water inlet of the heat transfer storage bin and is connected with the controller; the hot dump bin is respectively connected with the first water guide pipe and the second water guide pipe and is connected with the controller; the second water guide pipe is respectively connected with a water outlet of the heat transfer storage bin and a hot water pipeline inside a house of a building resident; the third water guide pipeline is respectively connected with a hot water pipeline inside a house of a building resident and a water inlet of the cold transfer storage bin and is connected with the controller; the cold transfer storage bin is connected with the third water guide pipe and the fourth water guide pipe respectively and is connected with the controller; the fourth water guide pipe is respectively connected with a water outlet of the cold transfer storage bin and a cold water pipeline inside a house of a building resident; and a temperature sensor and an electric switch valve are arranged in the first water guide pipe, the second water guide pipe, the third water guide pipe and the fourth water guide pipe.

8. The intelligent building integrated management system based on wastewater recycling treatment as claimed in claim 1, wherein the intelligent building integrated management system comprises the following working steps:

9. The comprehensive intelligent building management system based on wastewater recycling treatment as claimed in claim 4, wherein the comprehensive intelligent building management system further comprises the following working steps:

10. The intelligent building integrated management system based on wastewater recycling treatment as claimed in claim 7, further comprising the following steps: