CN210419300U - Waste water recovery system capable of saving electric energy - Google Patents

Abstract

The utility model discloses a waste water recovery system for saving electric energy, which comprises a water collecting device, a waste water receiving device and a pumping device; the water pumping device comprises a shell, a linkage wheel and a pump; the linkage wheel is connected with an impeller of the pump; a working chamber is formed in the shell, and the linkage wheel is positioned in the working chamber of the shell; the shell is also provided with a liquid inlet channel, and the liquid inlet channel comprises a liquid inlet section and an injection section; the first end of the spraying section faces the linkage wheel and is communicated with the working chamber; the second end of the spraying section is communicated with the liquid inlet section; the cross section area of the spraying section is smaller than that of the liquid inlet section; the water inlet end of the pump is communicated with the waste water receiving device, and the water outlet end of the pump is communicated with the water collecting device. The utility model discloses in can retrieving the closestool water tank with the waste water in the life, can play environmental protection water conservation effect, moreover, reducible this waste water recovery system's cost to can save the electric energy.

Description

Waste water recovery system capable of saving electric energy

Technical Field

The utility model relates to a waste water recovery system who saves electric energy.

Background

In order to save water resources, waste water (such as washing waste water in life) is usually recovered by utilizing a waste water recovery system at present, the conventional waste water recovery system generally comprises a pump, an impeller of the pump is connected with a motor during working, and the impeller is driven to rotate by electrifying the motor so as to pump water during working of the pump. However, in the existing wastewater recovery system, in order to drive the impeller of the pump to rotate, a motor must be configured, and the cost of the motor is high, so that the cost of the wastewater recovery system is high, and in the working process of the motor, more electric energy needs to be consumed, so that the industrial requirements cannot be met.

SUMMERY OF THE UTILITY MODEL

In order to overcome the defects of the prior art, the utility model aims to provide a waste water recovery system who saves electric energy, it is through adopting water-collecting device, waste water receiving device and pumping device's combination design to through the combination design with pumping device adoption casing, linkage wheel and pump, need not to adopt under the condition of motor alright drive the impeller rotation of pump, reducible this waste water recovery system's cost, and can save the electric energy.

The purpose of the utility model is realized by adopting the following technical scheme:

a waste water recovery system for saving electric energy comprises a water collecting device, a waste water receiving device and a water pumping device; the water pumping device comprises a shell, a linkage wheel and a pump; the linkage wheel is connected with an impeller of the pump, and the central axis of the linkage wheel is superposed with the central axis of the impeller; a working chamber is formed in the shell, and the linkage wheel is positioned in the working chamber of the shell; the shell is also provided with a liquid inlet channel, and the liquid inlet channel is used for pushing liquid for driving the linkage wheel to rotate to flow through; the liquid inlet channel comprises a liquid inlet section and an injection section; one end of the injection section is formed into a first end, and the other end of the injection section is formed into a second end; the first end of the spraying section faces the linkage wheel and is communicated with the working chamber; the second end of the spraying section is communicated with the liquid inlet section; the cross section area of the spraying section is smaller than that of the liquid inlet section; the water inlet end of the pump is communicated with the waste water receiving device, and the water outlet end of the pump is communicated with the water collecting device.

The waste water receiving device comprises a filtering pipeline and a water storage component; and a filtering device is arranged in the filtering pipeline, and the water inlet ends of the filtering pipeline and the pump are respectively communicated with the water storage component.

The water storage part is a water storage tank, a water inlet is formed in the upper end of the water storage tank, a water outlet is formed in the lower end of the water storage tank, the filtering pipeline is communicated with the water inlet of the water storage tank, and the water inlet end of the pump is communicated with the water outlet of the water storage tank.

The water collecting device is a water collecting tank which is a toilet water tank.

The extending track of the spraying section is vertical to the central axis of the linkage wheel.

The shell is also provided with a liquid outlet channel communicated with the working chamber.

The liquid outlet channel is communicated with a flushing system of the closestool through a liquid discharge pipeline.

The linkage wheel is connected with the rotating shaft of the impeller.

The linkage wheel comprises a hub fixedly sleeved on the rotating shaft and a plurality of blades circumferentially arranged on the hub, wherein bearing surfaces are arranged on the blades and used for bearing the injection of the liquid.

The liquid for pushing the linkage wheel to rotate is water; the impeller of the pump is located outside the working chamber.

Compared with the prior art, the beneficial effects of the utility model reside in that: the utility model provides a waste water recovery system which can save electric energy, through adopting the combination design of the water collecting device, the waste water receiving device and the water pumping device, and through adopting the shell, the linkage wheel and the pump to the water pumping device, the impeller of the pump can be driven to rotate under the condition of not needing to adopt the motor, the cost of the waste water recovery system can be reduced, and the electric energy can be saved; moreover, the service life of the device can be prolonged, and the safety performance is improved; meanwhile, the waste water recovery system can recover the washing waste water in life into the water tank of the closestool, and can play a role in environmental protection and water saving.

Drawings

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

FIG. 2 is a schematic structural view of a water pumping device;

FIG. 3 is a top view of the water pumping device;

FIG. 4 is a sectional view taken along line A-A of FIG. 3;

FIG. 5 is a sectional view taken along line B-B of FIG. 3;

in the figure: 10. a water pumping device; 11. a working chamber; 12. a main housing; 13. a liquid inlet pipeline; 14. a liquid outlet pipeline; 15. a housing; 20. a linkage wheel; 21. a hub; 22. a blade; 23. a pressure bearing face; 30. a pump; 31. an impeller; 32. a rotating shaft; 33. a water inlet end; 34. a water outlet end; 40. a liquid inlet channel; 41. a liquid inlet section; 42. a spraying section; 50. a liquid outlet channel; 51. a communication port; 60. An end cap; 61. an internal part; 62. an annular groove; 63. a support portion; 70. a wastewater receiving device; 71. a filtration pipeline; 72. a water storage part; 80. a water collection device; 91. a first communicating pipe; 92. a second communicating conduit; 93. a third communicating pipe; 94. a liquid discharge conduit; 95. a washbasin.

Detailed Description

The present invention will be further described with reference to the accompanying drawings and the detailed description, and it should be noted that the embodiments or technical features described below can be arbitrarily combined to form a new embodiment without conflict.

As shown in fig. 1 to 5, an electric energy saving wastewater recycling system includes a water collecting device 80, a wastewater receiving device 70, and a water pumping device 10; the water pumping device 10 comprises a shell 15, a linkage wheel 20 and a pump 30; the linkage wheel 20 is connected with an impeller 31 of the pump 30, and the central axis of the linkage wheel 20 is superposed with the central axis of the impeller 31; a working chamber 11 is formed in the shell 15, and the linkage wheel 20 is positioned in the working chamber 11 of the shell 15; the shell 15 is also provided with a liquid inlet channel 40, and the liquid inlet channel 40 is used for pushing liquid which is used for pushing the linkage wheel 20 to rotate to flow through; the liquid inlet channel 40 comprises a liquid inlet section 41 and an injection section 42; one end of the injection section 42 is formed as a first end, and the other end is formed as a second end; the first end of the injection section 42 faces the linkage wheel 20 and is communicated with the working chamber 11; the second end of the injection section 42 is communicated with the liquid inlet section 41; the cross-sectional area of the injection section 42 is smaller than that of the liquid inlet section 41; the water inlet end 33 of the pump 30 is communicated with the waste water receiving device 70, and the water outlet end 34 is communicated with the water collecting device 80. In particular, the impeller 31 of the pump 30 is located outside the working chamber 11.

When the waste water collecting device is used, liquid can flow in through the liquid inlet channel 40, and is sprayed towards the linkage wheel 20 through the first end of the spraying section 42 to push the linkage wheel 20 to rotate, the impeller 31 of the pump 30 is driven to rotate through the linkage wheel 20, the pump 30 can work, and at the moment, the pump 30 can suck waste water flowing out of the waste water receiving device 70 into the water collecting device 80 for storage. And because the cross sectional area of the injection section 42 is smaller than the cross sectional area of the liquid inlet section 41, when the liquid flows into the injection section 42 from the liquid inlet section 41, the water pressure can be increased, so that the thrust on the impeller 31 can be increased, and the impeller 31 can be more effectively pushed to rotate, therefore, the utility model provides a waste water recovery system, which can be used for supplying the liquid to flow through by adopting the combined design of the water collecting device 80, the waste water receiving device 70 and the water pumping device 10, and by adopting the shell 15, the linkage wheel 20 and the pump 30 as the water pumping device 10, and by arranging the working chamber 11 and the liquid inlet channel 40 on the shell 15, so that the linkage wheel 20 can be pushed to rotate by the pressure of the liquid, and the impeller 31 of the pump 30 can be driven to rotate by the linkage wheel 20, therefore, the utility model can drive the impeller 31 of the pump 30 to rotate without adopting a motor, and can save the cost of the motor, thereby reducing the cost of the pumping device 10, saving electric energy, prolonging the service life thereof and improving the safety performance.

The waste water receiving device 70 comprises a filtering pipeline 71 and a water storage component 72; a filtering device is arranged in the filtering pipeline 71, and the filtering pipeline 71 and the water inlet end 33 of the pump 30 are respectively communicated with the water storage component 72. When in use, the waste water can flow into the water storage part 72 after being filtered by the filtering pipeline 71. By adopting the combined design of the filtering pipeline 71 and the water storage part 72, the waste water receiving device 70 can filter out the dirty solid matters in the waste water by using the filtering pipeline 71 and then flow into the water storage part 72, thereby preventing the dirty solid matters from accompanying the waste water in the water storage part 72. In actual use, the filtering pipe 71 is connected to the water outlet of the sanitary washbasin 95, so that the washing wastewater flowing out from the water outlet of the sanitary washbasin 95 can be stored in the water storage part 72 through the filtering pipe 71.

Any filtering device available on the market can be used as the filtering device in the filtering pipeline 71 as long as the filtering function can be achieved. In the embodiment, the filtering device is 40-80 meshes. Specifically, the water storage part 72 is a water storage tank, a water inlet is arranged at the upper end of the water storage tank, a water outlet is arranged at the lower end of the water storage tank, the filtering pipeline 71 is communicated with the water inlet of the water storage tank, and the water inlet end 33 of the pump 30 is communicated with the water outlet of the water storage tank.

The water collecting device 80 is a water collecting tank. In this embodiment, the water collecting tank is a toilet water tank, so that waste water can be stored by the toilet water tank for flushing, and an environment-friendly and water-saving effect can be achieved.

Specifically, the water storage tank is communicated with the water inlet end 33 of the pump 30 through a first communicating pipeline 91, and the water outlet end 34 of the pump 30 is communicated with the water collecting device 80 through a third communicating pipeline 93, so that the connection is convenient.

Specifically, the extending track of the injection section 42 is perpendicular to the central axis of the linkage wheel 20.

The housing 15 is further provided with a liquid outlet channel 50 communicated with the working chamber 11, and the liquid flowing into the working chamber 11 through the liquid inlet channel 40 can flow out through the liquid outlet channel 50. Specifically, the housing 15 is provided with a communication port 51, and the liquid outlet channel 50 is communicated with the working chamber 11 through the communication port 51. The liquid outlet channel 50 is communicated with a flushing system of the toilet through a liquid discharge pipeline 94, so that liquid which pushes the linkage wheel 20 to rotate can flow to the flushing system of the toilet through the liquid discharge pipeline 94 to flush the toilet.

Preferably, the shell 15 comprises a main shell 12, a liquid inlet pipeline 13 arranged on the main shell 12, and a liquid outlet pipeline 14 arranged on the main shell 12; the liquid inlet section 41 is formed on the liquid inlet pipeline 13, and the liquid outlet channel 50 is formed on the liquid outlet pipeline 14. The shell 15 is designed by combining the main shell 12, the liquid inlet pipeline 13 and the liquid outlet pipeline 14, so that the liquid inlet section 41 and the liquid outlet channel 50 can be conveniently manufactured and formed, and the cost is further reduced.

Wherein, the liquid for driving the linkage wheel 20 to rotate can adopt water, toilet cleaner and the like. In this embodiment, the liquid for pushing the linkage wheel 20 to rotate is water, and the liquid inlet pipe 13 is connected to a second communicating pipe 92, so as to introduce tap water into the liquid inlet pipe 13 through the second communicating pipe 92. The drain line 94 is connected to the drain line 14.

The liquid inlet pipeline 13 is provided with a first external thread, and the liquid outlet pipeline 14 is provided with a second external thread. By adopting the above structure, the liquid inlet pipe 13 and the liquid outlet pipe 14 can be conveniently connected with the second communicating pipe 92 and the liquid discharge pipe 94 by screw threads.

Preferably, the housing 15 further includes an end cap 60 fixed to the main shell 12, and the end cap 60 and the main shell 12 enclose the working chamber 11. By adopting the structure, the working chamber 11 can be conveniently manufactured and formed.

Specifically, a sealing ring is further in sealing fit between the main shell 12 and the end cover 60, so that the sealing performance between the main shell 12 and the end cover 60 can be improved. Preferably, a concave position is arranged on the end portion of the main shell 12, the end cover 60 comprises an inner portion 61 located in the concave position, an annular groove 62 with a circular extending track is further arranged on the inner portion 61, the sealing ring is embedded in the annular groove 62, and by adopting the above structure, the sealing effect can be ensured, and the stability of the installation of the sealing ring can be improved.

Preferably, the end cap 60 further includes a support portion 63, the interior portion 61 is disposed on the support portion 63, and the support portion 63 abuts against an end surface of the main housing 12. Specifically, the supporting portion 63 is fixed to the main casing 12 through a connecting member, a first through hole is formed in the supporting portion 63, a second through hole is formed in the main casing 12, the connecting member includes a bolt and a nut, and the bolt is inserted into the first through hole and the second through hole and is in threaded connection with the nut. By adopting the above structure, the end cap 60 and the main housing 12 can be conveniently disassembled.

The linkage wheel 20 is connected with a rotating shaft 32 of the impeller 31. Preferably, the linkage wheel 20 includes a hub 21 fixedly sleeved on the rotating shaft 32, and a plurality of blades 22 circumferentially arranged on the hub 21, pressure bearing faces 23 are provided on the blades 22, the pressure bearing faces 23 are used for bearing the liquid, and when in use, the liquid flowing in from the liquid inlet channel 40 is sprayed towards the pressure bearing faces 23 of the blades 22, so as to push the linkage wheel 20. Specifically, the rotating shaft 32 of the impeller 31 has a connecting section inserted in the working chamber 11, and the hub 21 of the linkage wheel 20 is fixedly sleeved on the connecting section of the rotating shaft 32.

The above embodiments are only preferred embodiments of the present invention, and the protection scope of the present invention cannot be limited thereby, and any insubstantial changes and substitutions made by those skilled in the art based on the present invention are all within the protection scope of the present invention.

Claims (10)

1. The utility model provides a waste water recovery system who saves electric energy which characterized in that: comprises a water collecting device, a waste water receiving device and a water pumping device; the water pumping device comprises a shell, a linkage wheel and a pump; the linkage wheel is connected with an impeller of the pump, and the central axis of the linkage wheel is superposed with the central axis of the impeller; a working chamber is formed in the shell, and the linkage wheel is positioned in the working chamber of the shell; the shell is also provided with a liquid inlet channel, and the liquid inlet channel is used for pushing liquid for driving the linkage wheel to rotate to flow through; the liquid inlet channel comprises a liquid inlet section and an injection section; one end of the injection section is formed into a first end, and the other end of the injection section is formed into a second end; the first end of the spraying section faces the linkage wheel and is communicated with the working chamber; the second end of the spraying section is communicated with the liquid inlet section; the cross section area of the spraying section is smaller than that of the liquid inlet section; the water inlet end of the pump is communicated with the waste water receiving device, and the water outlet end of the pump is communicated with the water collecting device.

2. The electric energy saving wastewater reclamation system as recited in claim 1, wherein: the waste water receiving device comprises a filtering pipeline and a water storage component; and a filtering device is arranged in the filtering pipeline, and the water inlet ends of the filtering pipeline and the pump are respectively communicated with the water storage component.

3. The electric energy saving wastewater reclamation system as recited in claim 2, wherein: the water storage part is a water storage tank, a water inlet is formed in the upper end of the water storage tank, a water outlet is formed in the lower end of the water storage tank, the filtering pipeline is communicated with the water inlet of the water storage tank, and the water inlet end of the pump is communicated with the water outlet of the water storage tank.

4. The electric energy saving wastewater reclamation system as recited in claim 1, wherein: the water collecting device is a water collecting tank which is a toilet water tank.

5. The electric energy saving wastewater reclamation system as recited in claim 1, wherein: the extending track of the spraying section is vertical to the central axis of the linkage wheel.

6. The electric energy saving wastewater reclamation system as recited in claim 1, wherein: the shell is also provided with a liquid outlet channel communicated with the working chamber.

7. The electric energy saving wastewater reclamation system as recited in claim 6, wherein: the liquid outlet channel is communicated with a flushing system of the closestool through a liquid discharge pipeline.

8. The electric energy saving wastewater reclamation system as recited in claim 1, wherein: the linkage wheel is connected with the rotating shaft of the impeller.

9. The electric energy saving wastewater reclamation system as recited in claim 8, wherein: the linkage wheel comprises a hub fixedly sleeved on the rotating shaft and a plurality of blades circumferentially arranged on the hub, wherein bearing surfaces are arranged on the blades and used for bearing the injection of the liquid.

10. The electric energy saving wastewater reclamation system as recited in claim 1, wherein: the liquid for pushing the linkage wheel to rotate is water; the impeller of the pump is located outside the working chamber.

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