CN210261443U

CN210261443U - Efficient water-saving resource recycling system

Info

Publication number: CN210261443U
Application number: CN201920433661.1U
Authority: CN
Inventors: 宋志远
Original assignee: Individual
Current assignee: Individual
Priority date: 2019-04-02
Filing date: 2019-04-02
Publication date: 2020-04-07
Anticipated expiration: 2029-04-02
Also published as: WO2020200144A1

Abstract

The utility model discloses a high-efficient water conservation resource cyclic utilization system, it includes collecting system (10), foaming system (12), receives dirty system (15), allotment system (16), fermentation cylinder (17), natural pond liquid production system (18) and marsh gas production system (19), and foaming system (12) link to each other with the import pipeline of collecting system (10), and the import of receiving dirty system (15) links to each other with the sewage outlet of collecting system (10), the import of allotment system (16) links to each other with the outlet conduit who receives dirty system (15), and the import of fermentation cylinder (17) links to each other with the outlet conduit of allotment system (16), and natural pond liquid production system (18) links to each other with the natural pond liquid outlet conduit of fermentation cylinder (17), and marsh gas production system (19) links to each other with the marsh gas outlet of fermentation cylinder (17). The utility model discloses utilize the vacuum suction to flush the lavatory, reduce water wasting of resources, reduce chemical fertilizer's use, the cooperation that utilizes foam shutoff and amortization chamber in-process of flushing the lavatory is used, reduces the noise that the toilet production is flushed.

Description

Efficient water-saving resource recycling system

Technical Field

The utility model relates to a towards lavatory system technical field, especially a high-efficient water conservation resource cyclic utilization system.

Background

China is a typical country with relatively short water resources, and the daily toilet flushing water consumption of cities in the whole country is very large, so that the maximization of the toilet flushing water conservation is necessary to be realized; in recent years, dozens of technologies for saving water for flushing toilet are generated by means of introduction or independent research and development in China, but most unpractical technologies are gradually eliminated along with the change of market, and the technology with the best effect at present is a vacuum flushing water-saving technology. The existing vacuum toilet can achieve the purpose of environmental protection and water saving, but is difficult to flush cleanly in the toilet flushing process, can generate huge noise in the toilet flushing process, and still has great defects because the excrement after the toilet flushing is not utilized in the later period.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to overcome prior art's shortcoming, provide a high-efficient water conservation resource cyclic utilization system.

The purpose of the utility model is realized through the following technical scheme: the utility model provides a high-efficient water conservation resource cyclic utilization system, it includes collection system, foaming system, receives dirty system, allotment system, fermentation cylinder, natural pond liquid production system and marsh gas production system, the foaming system links to each other with collection system's inlet pipeline, it links to each other with collection system's sewage outlet to receive dirty system's import, allotment system's import links to each other with the outlet pipeline who receives dirty system, the import of fermentation cylinder links to each other with allotment system's outlet pipeline, natural pond liquid production system links to each other with fermentation cylinder's natural pond liquid outlet pipeline, marsh gas production system links to each other with fermentation cylinder's marsh gas outlet.

The collecting system comprises a toilet tool, wherein a flushing ring is arranged on the toilet tool, an inlet of the toilet tool is connected with a foaming system, a sewage discharge hole of the toilet tool is connected with a silencing cavity, an outlet of the silencing cavity is connected with a sewage receiving system through a sewage discharge pipe, a vacuum interface valve is installed on the sewage discharge pipe, and one side of the sewage discharge pipe is connected with a kitchen waste pipe.

The foaming system comprises an air pump, a tap water pipe, a foaming liquid tank, a tee joint, a vacuum generator and a foaming head, wherein the air pump is connected with the vacuum generator through an air pipe, an electromagnetic air valve is arranged on the air pipe, the foaming liquid tank is connected with the tap water pipe through a foaming liquid pipe and is connected to the vacuum generator through the tee joint, a one-way valve is arranged on the foaming liquid pipe, an electromagnetic water valve is arranged on the tap water pipe, and the foaming head is connected with the vacuum generator and is connected into the toilet tool through a pipeline.

Receive dirty system including receiving dirty jar, vacuum pump, sewage pump and vacuum meter, the vacuum pump passes through the vacuum tube and links to each other with the top of receiving dirty jar, the sewage pump passes through the sewage pipe and links to each other with the export of receiving dirty jar, the upper and lower both sides of receiving dirty jar are equipped with liquid level switch and lower liquid level switch respectively, go up liquid level switch and lower liquid level switch and be connected with the sewage pump electricity respectively, be equipped with the vacuum meter on receiving dirty jar, the vacuum meter is connected with the vacuum pump electricity.

The blending system comprises a blending tank and a submerged pump, wherein an inlet of the blending tank is connected with a sewage pump through a pipeline, and the submerged pump is arranged in the blending tank and is connected with the fermentation tank through a pipeline.

The biogas slurry production system comprises a solid-liquid mixing tank, a solid-liquid separator and a biogas slurry storage tank, wherein the solid-liquid mixing tank is connected with a biogas slurry outlet of the fermentation tank, the solid-liquid separator is connected with the solid-liquid mixing tank, the biogas slurry storage tank is connected with a liquid phase outlet of the solid-liquid separator, and a solid phase outlet of the solid-liquid separator is connected to an organic fertilizer production workshop.

The biogas production system comprises a gas-water separator, a desulfurizing tower and a gas storage tank, wherein the gas-water separator is connected with a gas outlet of the fermentation tank, the desulfurizing tower is connected with the gas-water separator, and the gas storage tank is connected with the desulfurizing tower.

The device also comprises an electric control system, wherein the electric control system comprises an electric cabinet and an inductor, and the inductor is electrically connected with the collecting system and the foaming system respectively.

The tap water pipe is connected with a tap water outlet, the tap water outlet is also connected with a flushing pipe, the flushing pipe is connected with a flushing ring on the toilet, and a flushing valve is arranged on the flushing pipe.

The utility model has the advantages of it is following: the vacuum suction is utilized to flush the toilet, so that the waste of water resources is reduced; the foam plugging and the silencing cavity are used in a matched manner in the toilet flushing process, so that the noise generated by toilet flushing is reduced; the sewage after flushing the toilet is directly conveyed to the methane station for treatment, so that the pressure for treating the urban sewage is reduced, and meanwhile, the sewage is reasonably utilized.

Drawings

Fig. 1 is a schematic structural view of the present invention;

FIG. 2 is a schematic structural view of a squatting pan;

FIG. 3 is a schematic structural view of a toilet bowl;

in the figure: 10-collection system, 101-toilet, 102-flush valve, 103-flush ring, 104-sound-deadening chamber, 105-vacuum interface valve, 11-electric control system, 111-electric control box, 112-inductor, 12-foaming system, 121-air pump, 1211-electromagnetic air valve, 122-tap water pipe, 1221-electromagnetic water valve, 123-foaming liquid tank, 1231-one-way valve, 124-three-way, 125-vacuum generator, 126-head, 13-tap water outlet, 14-kitchen waste pipe, 15-sewage-receiving system, foaming 151-sewage-receiving tank, 152-vacuum pump, 1521-vacuum meter, 153-sewage pump, 1531-upper liquid level switch, 1532-lower liquid level switch, 16-blending system, 161-blending tank, 162-a submerged pump, 17-a fermentation tank, 18-a biogas slurry production system, 181-a solid-liquid mixing tank, 182-a solid-liquid separator, 183-a biogas slurry storage tank, 19-a biogas production system, 191-a gas-water separator, 192-a desulfurizing tower, 193-a gas storage tank and 20-an organic fertilizer production workshop.

Detailed Description

The invention will be further described with reference to the accompanying drawings, but the scope of the invention is not limited to the following description.

As shown in fig. 1, the efficient water-saving resource recycling system comprises a collection system 10, a foaming system 12, a sewage receiving system 15, a blending system 16, a fermentation tank 17, a biogas slurry production system 18 and a biogas production system 19, wherein the foaming system 12 is connected with an inlet pipeline of the collection system 10, an inlet of the sewage receiving system 15 is connected with a sewage outlet of the collection system 10, an inlet of the blending system 16 is connected with an outlet pipeline of the sewage receiving system 15, an inlet of the fermentation tank 17 is connected with an outlet pipeline of the blending system 16, the biogas slurry production system 18 is connected with a biogas slurry outlet pipeline of the fermentation tank 17, and the biogas production system 19 is connected with a biogas outlet of the fermentation tank 17.

The collecting system 10 comprises a toilet tool 101, a flushing ring 103 is arranged on the toilet tool 101, an inlet of the toilet tool 101 is connected with a foaming system 12, a sewage discharge hole of the toilet tool 101 is connected with a silencing cavity 104, an outlet of the silencing cavity 104 is connected with a sewage receiving system 15 through a sewage discharge pipe, a vacuum interface valve 105 is installed on the sewage discharge pipe, and one side of the sewage discharge pipe is connected with a kitchen waste pipe 14.

The foaming system 12 comprises an air pump 121, a tap water pipe 122, a foaming liquid tank 123, a tee joint 124, a vacuum generator 125 and a foaming head 126, wherein the air pump 121 is connected with the vacuum generator 125 through an air pipe, an electromagnetic air valve 1211 is arranged on the air pipe, the foaming liquid tank 123 is connected with the tap water pipe 122 through a foaming liquid pipe and is connected to the vacuum generator 125 through the tee joint 124, a one-way valve 1231 is arranged on the foaming liquid pipe, an electromagnetic 122water valve 1 is arranged on the tap water pipe 122, and the foaming head 126 is connected with the vacuum generator 125 and is connected to the interior of the toilet tool 101 through a pipeline. During foaming, the one-way valve 1231, the electromagnetic water valve 1221 and the electromagnetic air valve 1211 are simultaneously opened, so that the environment-friendly foaming liquid, tap water and air enter the vacuum generator 125 to be mixed, and then enter the foaming head 126 to generate foam.

The sewage receiving system 15 comprises a sewage receiving tank 151, a vacuum pump 152, a sewage pump 153 and a vacuum meter 1521, wherein the vacuum pump 152 is connected with the top of the sewage receiving tank 151 through a vacuum tube, the sewage pump 153 is connected with an outlet of the sewage receiving tank 151 through a sewage tube, an upper liquid level switch 1531 and a lower liquid level switch 1532 are respectively arranged on the upper side and the lower side of the sewage receiving tank 151, the upper liquid level switch 1531 and the lower liquid level switch 1532 are respectively and electrically connected with the sewage pump 153, the sewage receiving tank 151 is provided with the vacuum meter 1521, and the vacuum meter 1521 is electrically connected with the vacuum pump 152. When the liquid level in the sewage tank 151 reaches the maximum liquid level alarm value, the upper liquid level switch 1531 controls the sewage pump 153 to be turned on to prevent sewage from being sucked into the vacuum pump 152, and when the liquid level in the sewage tank 151 reaches the minimum liquid level alarm value, the lower liquid level switch 1532 controls the sewage pump 153 to be turned off to prevent gas from entering the sewage pump 153.

The blending system 16 comprises a blending tank 161 and a submerged pump 162, wherein an inlet of the blending tank 161 is connected with the sewage pump 153 through a pipeline, and the submerged pump 162 is arranged in the blending tank 161 and connected with the fermentation tank 17 through a pipeline.

The biogas slurry production system 18 comprises a solid-liquid mixing tank 181, a solid-liquid separator 182 and a biogas slurry storage tank 183, wherein the solid-liquid mixing tank 181 is connected with a biogas slurry outlet of the fermentation tank 17, the solid-liquid separator 182 is connected with the solid-liquid mixing tank 181, the biogas slurry storage tank 183 is connected with a liquid phase outlet of the solid-liquid separator 182, and the solid phase outlet of the solid-liquid separator 182 is connected to the organic fertilizer production workshop 20. The separated biogas slurry is conveyed to a biogas slurry storage tank 183 and is directly used for field vegetable irrigation; the biogas residues are conveyed to an organic fertilizer production workshop 20 to be used as raw materials of organic compost.

The biogas production system 19 comprises a gas-water separator 191, a desulfurizing tower 192 and a gas storage tank 193, wherein the gas-water separator 191 is connected with a gas outlet of the fermentation tank 17, the desulfurizing tower 192 is connected with the gas-water separator 191, and the gas storage tank 193 is connected with the desulfurizing tower 192.

Further, the device further comprises an electric control system 11, wherein the electric control system 11 comprises an electric control box 111 and a sensor 112, and the sensor 112 is electrically connected with the collecting system 10 and the foaming system 12 respectively.

The tap water pipe 122 is connected with the tap water outlet 13, and the tap water outlet is also connected with a flushing pipe, the flushing pipe is connected with a flushing ring 103 on the toilet 101, and a flushing valve 102 is arranged on the flushing pipe.

The working process of the utility model is as follows: when the toilet is in use, the sensor 112 detects a human body, the electromagnetic air valve 1211 is opened, vacuum is generated in the vacuum generator 125, the environment-friendly foaming liquid enters the mixing pipeline through the one-way valve 1231, the electromagnetic water valve 1221 is opened, tap water enters the mixing pipeline according to a proportion, the environment-friendly foaming liquid, tap water and gas are mixed and then enter the foaming head 126 to generate foam, and then enter the toilet 101 to form plugging foam, after the use is finished, the sensor 112 detects that the human body leaves, the electromagnetic water valve 102 is opened, a small amount of tap water is sprayed at a high speed through the small spraying holes on the flushing ring 103, dirt on the wall of the toilet 101 is flushed into the bottom pit, then the vacuum interface valve 105 is opened to suck sewage into the sewage discharge pipe, after the sewage is completely sucked, partial foam floating on the water surface is reserved in the toilet 101 to plug the pipeline, meanwhile, due to the silencing effect of the silencing cavity 104, the sucked sewage firstly enters, then the sewage is conveyed to a blending tank 161 from a sewage accommodating tank 151 through a sewage pump 153, and then is conveyed to the fermentation tank 17 through a submerged pump 162, and the fermented methane is conveyed to a gas storage tank 193; conveying the biogas slurry to a biogas storage pool for irrigating vegetables in the field; the biogas residues are conveyed to an organic fertilizer production workshop 20 to be used as raw materials of organic compost.

The foregoing is merely a preferred embodiment of the invention and is not intended to limit the invention in any way. The technical solutions of the present invention can be used by anyone skilled in the art to make many possible variations and modifications to the technical solution of the present invention, or to modify equivalent embodiments with equivalent variations, without departing from the scope of the technical solution of the present invention. Therefore, any modification, equivalent change and modification of the above embodiments according to the present invention are all within the protection scope of the present invention.

Claims

1. A high-efficient water conservation resource cyclic utilization system which characterized in that: the biogas slurry fermentation system comprises a collection system (10), a foaming system (12), a sewage receiving system (15), a blending system (16), a fermentation tank (17), a biogas slurry production system (18) and a biogas production system (19), wherein the foaming system (12) is connected with an inlet pipeline of the collection system (10), an inlet of the sewage receiving system (15) is connected with a sewage outlet of the collection system (10), an inlet of the blending system (16) is connected with an outlet pipeline of the sewage receiving system (15), an inlet of the fermentation tank (17) is connected with an outlet pipeline of the blending system (16), the biogas slurry production system (18) is connected with a biogas slurry outlet pipeline of the fermentation tank (17), and the biogas production system (19) is connected with a biogas outlet of the fermentation tank (17).

2. The system for recycling efficient water-saving resources according to claim 1, wherein: collecting system (10) is including lavatory utensil (101), be equipped with towards water ring (103) on lavatory utensil (101), it sprays the aperture to have on washing water ring (103), and the import and the foaming system (12) of lavatory utensil (101) link to each other, and the blowdown hole of lavatory utensil (101) is connected with amortization cavity (104), and the export of amortization cavity (104) passes through the blow off pipe and links to each other with receiving dirty system (15), install vacuum interface valve (105) on the blow off pipe, one side of blow off pipe even has kitchen garbage pipe (14).

3. The system for recycling efficient water-saving resources according to claim 2, wherein: the foaming system (12) comprises an air pump (121), a tap water pipe (122), a foaming liquid tank (123), a tee joint (124), a vacuum generator (125) and a foaming head (126), wherein the air pump (121) is connected with the vacuum generator (125) through an air pipe, an electromagnetic air valve (1211) is arranged on the air pipe, the foaming liquid tank (123) is an environment-friendly foaming liquid tank, the foaming liquid tank (123) is connected with the tap water pipe (122) through a foaming liquid pipe and is connected to the vacuum generator (125) through the tee joint (124), a one-way valve (1231) is arranged on the foaming liquid pipe, an electromagnetic water valve (1221) is arranged on the tap water pipe (122), and the foaming head (126) is connected with the vacuum generator (125) and is connected into the toilet tool (101) through a pipeline.

4. The system for recycling efficient water-saving resources according to claim 1, wherein: receive dirty system (15) including receiving dirty jar (151), vacuum pump (152), sewage pump (153) and vacuum meter (1521), vacuum pump (152) link to each other through the top of vacuum tube with receiving dirty jar (151), sewage pump (153) are passed through the sewer pipe and are linked to each other with the export of receiving dirty jar (151), the upper and lower both sides of receiving dirty jar (151) are equipped with liquid level switch (1531) and lower liquid level switch (1532) respectively, go up liquid level switch (1531) and lower liquid level switch (1532) and be connected with sewage pump (153) electricity respectively, be equipped with vacuum meter (1521) on receiving dirty jar (151), vacuum meter (1521) is connected with vacuum pump (152) electricity.

5. The system for recycling efficient water-saving resources of claim 4, wherein: the blending system (16) comprises a blending tank (161) and a submerged pump (162), wherein an inlet of the blending tank (161) is connected with a sewage pump (153) through a pipeline, and the submerged pump (162) is arranged in the blending tank (161) and is connected with the fermentation tank (17) through a pipeline.

6. The system for recycling efficient water-saving resources according to claim 1, wherein: the biogas slurry production system (18) comprises a solid-liquid mixing tank (181), a solid-liquid separator (182) and a biogas slurry storage tank (183), wherein the solid-liquid mixing tank (181) is connected with a biogas slurry outlet of the fermentation tank (17), the solid-liquid separator (182) is connected with the solid-liquid mixing tank (181), the biogas slurry storage tank (183) is connected with a liquid phase outlet of the solid-liquid separator (182), and a solid phase outlet of the solid-liquid separator (182) is connected to an organic fertilizer production workshop (20).

7. The system for recycling efficient water-saving resources according to claim 1, wherein: the biogas production system (19) comprises a gas-water separator (191), a desulfurizing tower (192) and a gas storage tank (193), wherein the gas-water separator (191) is connected with a gas outlet of the fermentation tank (17), the desulfurizing tower (192) is connected with the gas-water separator (191), and the gas storage tank (193) is connected with the desulfurizing tower (192).

8. The system for recycling efficient water-saving resources according to claim 1, wherein: the device is characterized by further comprising an electric control system (11), wherein the electric control system (11) comprises an electric cabinet (111) and a sensor (112), and the sensor (112) is electrically connected with the collecting system (10) and the foaming system (12) respectively.

9. The system for recycling efficient water-saving resources of claim 3, wherein: the tap water pipe (122) is connected with a tap water outlet (13), the tap water outlet (13) is also connected with a flushing pipe, the flushing pipe is connected with a flushing ring (103) on the toilet (101), and a flushing valve (102) is arranged on the flushing pipe.