CN210636504U

CN210636504U - Water saving system

Info

Publication number: CN210636504U
Application number: CN201921335055.2U
Authority: CN
Inventors: 不公告发明人
Original assignee: Individual
Current assignee: Individual
Priority date: 2019-08-16
Filing date: 2019-08-16
Publication date: 2020-05-29
Anticipated expiration: 2029-08-16

Abstract

The utility model provides a water saving system, include water tank 3 and locate secondary water delivery subassembly, water supply subassembly and running water intake assembly on the water tank 3, secondary water delivery subassembly intercommunication produces equipment 2 and water tank 3 of secondary water, and water supply subassembly connects the equipment 12 that uses the secondary water, and running water intake assembly intercommunication running water pipe, this system use at each floor reconfiguration of building, through the concerted action of each subassembly, equipment, can priority storage and supply the secondary water, just adjust when the secondary water yield is not enough and use the running water to supply, practice thrift the running water by a wide margin.

Description

Water saving system

Technical Field

The invention belongs to the field of environmental protection and energy conservation, and particularly relates to a water saving system.

Background

In daily life, toilets in families and public places are basically flushed by directly using tap water, and a large amount of water is consumed. A large amount of water which can be used for the second time and a large amount of rainwater and the like are generated when people wash hands (or wash faces, bathe and the like), the water can be used for the second time after being simply filtered, but the water can be directly drained without being used, so that great water resource waste is caused, and certain pressure is caused on the reasonable utilization of water supply energy and the environmental protection.

Disclosure of Invention

The invention aims to overcome the defects of the prior art and provides a water-saving system which can preferentially store and provide secondary water, and when the secondary water is insufficient, tap water is used for supplement, so that the aim of greatly saving the tap water is fulfilled.

The purpose of the invention is realized by the following technical scheme: the utility model provides a water saving system, includes water tank 3 and locates secondary water delivery subassembly, running water on the water tank 3 advance water subassembly and water supply assembly, secondary water delivery subassembly intercommunication produces equipment 2 and the water tank 3 of secondary water, and the running water advances water subassembly intercommunication running water pipe and water tank 3, and water supply assembly connects water tank 3 and uses the equipment 12 of secondary water.

Furthermore, secondary water delivery subassembly, running water intake subassembly and water supply subassembly use with fortune water subassembly and drainage subassembly integration cooperation.

Further, the secondary water using and delivering assembly comprises a water delivering pipe 4, a first switch 14, a fourth switch 17 and a filtering device 19, wherein the water delivering pipe 4 is communicated with the device 2 for generating secondary water and the water tank 3, the first switch 14, the fourth switch 17 and the filtering device 19 are arranged on the water delivering pipe 4 and are sequentially arranged from top to bottom, the first switch 14 is positioned on the upper floor, and the fourth switch 17 is positioned on the next floor;

preferably, the tap water inlet assembly comprises a tap water inlet pipe 5 and a floating water shutoff valve 20, the floating water shutoff valve 20 is arranged at the lower end of the tap water inlet pipe 5 and is connected with the lower end of the tap water inlet pipe in a matching manner, and the tap water inlet pipe 5 is communicated with a tap water pipe;

preferably, the water supply assembly is composed of a water supply pipe 11, the water supply pipe 11 is connected to the water tank 3 and is connected to a device 12 using secondary water;

preferably, the water transporting assembly comprises a main water transporting pipe 6, an overflow pipe 7, an auxiliary water transporting pipe 8, a third switch 16, a fifth switch 18 and a filtering device 19, the main water transporting pipe 6 is connected with the water transporting pipe 4 and the overflow pipe 7 of the next floor, the overflow pipe 7 is connected to the upper part of the water tank 3 of the floor and communicated with the top of the water tank 3 of the next floor, the auxiliary water transporting pipe 8 is connected with the overflow pipe 7 and the main water transporting pipe 6 of the same floor, the third switch 16, the fifth switch 18 and the filtering device 19 are arranged on the overflow pipe 7 and sequentially arranged from top to bottom, the third switch 16 is positioned on the upper floor, the fifth switch 18 is positioned next to the lower floor, and the position of the third switch 16 is slightly lower than the joint of the auxiliary water transporting pipe 8 and the overflow pipe 7;

preferably, the drainage assembly comprises a drainage pipe 9, a sewage discharge pipe 10, a secondary drainage pipe 13 and a second switch 15, the drainage pipe 9 is connected with the water delivery pipe 4 and the sewage discharge pipe 10, the secondary drainage pipe 13 is connected with the equipment 12 using secondary water and the sewage discharge pipe 10, and the second switch 15 is positioned on the drainage pipe 9 and close to one end of the water delivery pipe 4.

Further, the water saving system comprises a water conveying assembly, wherein the water conveying assembly comprises a water conveying pipe 4, a first switch 14, a fourth switch 17 and a filtering device 19, the water conveying pipe 4 is connected with a device 2 for generating secondary water and a water tank 3, the first switch 14, the fourth switch 17 and the filtering device 19 are arranged on the water conveying pipe 4 and are sequentially arranged from top to bottom, the first switch 14 is positioned on the upper floor, and the fourth switch 17 is positioned on the next floor;

preferably, the water transporting assembly is composed of an overflow pipe 7, and the overflow pipe 7 is connected to the upper part of the water tank 3 of the floor and communicated with the top of the water tank 3 of the next floor;

preferably, the drainage component comprises a drainage pipe 9, a sewage discharge pipe 10 and a secondary drainage pipe 13, wherein the drainage pipe 9 is connected with the water delivery pipe 4 and the sewage discharge pipe 10, and the secondary drainage pipe 13 is connected with equipment 12 for using secondary water and the sewage discharge pipe 10;

preferably, the running water inlet assembly comprises a running water inlet pipe 5 and a floating water closing valve 20, the floating water closing valve 20 is arranged at the lower end of the running water inlet pipe 5 and is in matched connection with the running water inlet pipe, and the running water inlet pipe 5 is communicated with a running water pipe.

Compared with the prior art, the invention has the beneficial effects that: through the water tank, secondary water delivery subassembly, water supply assembly, fortune water subassembly, drainage subassembly and running water subassembly that intakes, and from the top down use at each floor reconfiguration, when last floor produced (carried) secondary water, get into this floor water tank along delivery subassembly through secondary water self action of gravity, later provide its use through water supply assembly according to the demand of water equipment, then directly arrange through drainage subassembly when quality of water is not good should not carry out secondary use, then provide next floor water tank through fortune water subassembly when the water source is surplus, then transport to next floor again through fortune water subassembly when next floor does not use (or forbid next floor to use), then fill up to the water tank through running water subassembly that intakes when the secondary water volume is not enough, reach the purpose of practicing thrift the running water by a wide margin.

Drawings

Fig. 1 is a schematic diagram of the present invention repeatedly deployed in each floor of a building (the next floor may be prohibited from being used or the next floor may be actively stopped).

Fig. 2 is a schematic view (simplified type) of the present invention repeatedly disposed in each floor of a building.

Fig. 3 is a schematic view of the water tank of the present invention and components and equipment disposed thereon.

In the figure, 1-floor slab, 2-equipment for generating secondary water, 3-water tank, 4-water conveying pipe, 5-tap water inlet pipe, 6-main water conveying pipe, 7-overflow pipe, 8-auxiliary water conveying pipe, 9-water discharging pipe, 10-sewage discharging pipe, 11-water supplying pipe, 12-equipment for using secondary water, 13-secondary water discharging pipe, 14-first switch, 15-second switch, 16-third switch, 17-fourth switch, 18-fifth switch, 19-filtering equipment and 20-floating water closing valve.

Detailed Description

The technical solutions of the present invention will be described clearly and completely with reference to the following embodiments, and it should be understood that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be obtained by a person skilled in the art without inventive effort based on the embodiments of the present invention, are within the scope of the present invention.

Referring to fig. 1-3, the present invention provides the following technical solutions: a water-saving system comprises a water tank 3, and a secondary water delivery assembly, a tap water inlet assembly and a water supply assembly which are arranged on the water tank 3, and are integrated and matched with a water delivery assembly and a water discharge assembly for use;

preferably, the secondary water delivery assembly comprises a water delivery pipe 4, a first switch 14, a fourth switch 17 and a filtering device 19, the water delivery pipe 4 is connected with the device 2 for generating secondary water and the water tank 3, the first switch 14, the fourth switch 17 and the filtering device 19 are arranged on the water delivery pipe 4 and are sequentially arranged from top to bottom, the first switch 14 is positioned on the upper floor, the fourth switch 17 is positioned on the next floor, when the device 2 for generating secondary water uses tap water, the secondary water is generated, the secondary water flows along the water delivery pipe 4, is filtered into clean water through the filtering device 19 after passing through the first switch 14 and the fourth switch 17, and then enters the water tank 3 for storage and standby;

preferably, the water supply assembly is composed of a water supply pipe 11, the water supply pipe 11 is connected to the water tank 3 and is communicated to the device 12 using the secondary water, and when the secondary water is needed, the secondary water is introduced from the water tank 3 to the device 12 using the secondary water through the water supply pipe 11 by gravity for use;

preferably, the water transporting assembly comprises a main water transporting pipe 6, an overflow pipe 7, an auxiliary water transporting pipe 8, a third switch 16, a fifth switch 18 and a filtering device 19, wherein the overflow pipe 7 is connected to the upper part of the water tank 3 of the floor and communicated with the top of the water tank 3 of the next floor, when the secondary water of the floor is surplus, the surplus secondary water is transported from the water tank of the floor to the water tank of the next floor through the overflow pipe 7 for storage and standby, and if the water of the lower floor is surplus, the water is transported to the next floor step by step; the main water conveying pipe 6 is connected with the water conveying pipe 4 and the overflow pipe 7 of the next floor, the auxiliary water conveying pipe 8 is connected with the overflow pipe 7 and the main water conveying pipe 6 of the same floor, the third switch 16, the fifth switch 18 and the filtering equipment 19 are arranged on the overflow pipe 7 and are sequentially arranged from top to bottom, the third switch 16 is positioned on the upper floor, the fifth switch 18 is positioned on the next floor, the third switch 16 is slightly lower than the interface between the auxiliary water conveying pipe 8 and the overflow pipe 7, if the secondary water is forbidden to be used by the next floor, the first switch 14, the second switch 15 and the third switch 16 are closed, the secondary water generated by the floor is ensured to be blocked when being conveyed to the first switch 14 and the second switch 15 through the water conveying pipe 4, the main water conveying pipe 6 of the bypass is conveyed to the next floor through the overflow pipe 7 of the next floor, the third switch 16 is closed, and the residual secondary water in the water tank 3 of the floor is ensured to be blocked when reaching the third switch 16, the bypass auxiliary water conveying pipe 8 conveys surplus secondary water to the next floor through the main water conveying pipe 6 and the overflow pipe 7 of the next floor; if the next floor does not use the secondary water of the upper floor actively, the fourth switch 17 and the fifth switch 18 are closed, so that the secondary water generated by the equipment 2 on the upper floor and the surplus secondary water in the water tank 3 are both transported to the next floor by bypassing the main water transporting pipe 6 through the overflow pipe 7; the position of the first switch 14 is slightly lower than the interface of the main water conveying pipe 6 and the water conveying pipe 4, and is also slightly lower than the interface of the drain pipe 9 and the water conveying pipe 4; the position of the second switch 15 is slightly lower than the interface of the main water conveying pipe 6 and the water conveying pipe 4, the middle part of the main water conveying pipe 6 is higher than the interface of the main water conveying pipe 6 and the water conveying pipe 4, and the middle part of the auxiliary water conveying pipe 8 is higher than the interface of the auxiliary water conveying pipe 8 and the overflow pipe 7, so that water is prevented from overflowing from the main (auxiliary) water conveying pipe when the transfer is not actively carried out;

preferably, the drainage assembly comprises a drainage pipe 9, a drainage pipe 10, a secondary drainage pipe 13 and a second switch 15, the drainage pipe 9 is connected with the water conveying pipe 4 and the drainage pipe 10, the second switch 15 is positioned on the drainage pipe 9 and close to one end of the water conveying pipe 4, after running water is used by the floor equipment 2, if secondary water which is not suitable for reuse is generated, the first switch 14 is closed, the second switch 15 is opened, and the secondary water which is not used is directly drained from the drainage pipe 9 to the drainage pipe 10; the middle part of the main water conveying pipe 6 is higher than the interface of the main water conveying pipe and the water conveying pipe 4 so as to ensure that secondary water which is not suitable for reuse is discharged to a sewage discharge pipe 10 through a water discharge pipe 9 and is discharged; the interface of the water discharge pipe 9 and the water delivery pipe 4 is obviously higher than the interface of the water discharge pipe and the sewage discharge pipe 10, so that the smoothness of discharging the secondary water which is not suitable for use is ensured; the secondary drainage pipe 13 is connected with the equipment 12 using the secondary water and the sewage discharge pipe 10, and discharges sewage generated by the equipment 12 using the secondary water;

preferably, the tap water inlet assembly comprises a tap water inlet pipe 5 and a floating water shut-off valve 20, the tap water inlet pipe 5 is communicated with a tap water pipe, the floating water shut-off valve 20 is arranged at the lower end of the tap water inlet pipe 5 and is in matched connection with the lower end of the tap water inlet pipe 5, when insufficient secondary water supply is obtained in the water tank 3, the water level gradually drops, the floating water shut-off valve 20 also drops along with the water level under the action of gravity, and when the water tank reaches a certain position, the tap water inlet pipe 5 is opened to fill tap water into the water tank 3 so as to make up for; when the water level in the water tank 3 rises, the floating water-closing valve 20 also moves upwards along with the buoyancy supporting action of the rising water level, and when the water level reaches a certain position, the tap water inlet pipe 5 is closed, and the tap water is stopped from being filled into the water tank 3.

Further, the water saving system comprises a water tank 3, and a secondary water delivery assembly, a water supply assembly, a water delivery assembly, a water drainage assembly and a tap water inlet assembly which are arranged on the water tank 3, wherein the water delivery assembly comprises a water delivery pipe 4, a first switch 14, a fourth switch 17 and a filtering device 19, the water delivery pipe 4 is connected with a device 2 for generating secondary water and the water tank 3, the first switch 14, the fourth switch 17 and the filtering device 19 are arranged on the water delivery pipe 4 in sequence from top to bottom, the first switch 14 is positioned on the upper floor, the fourth switch 17 is positioned on the next floor, when the device 2 for generating secondary water generates secondary water after tap water is used, the secondary water flows along the water delivery pipe 4, and is filtered into clear water through the first switch 14 and the fourth switch 17 and then enters the water tank 3 through the filtering device 19 to be stored for later use;

preferably, the water supply assembly is composed of a water supply pipe 11, the water supply pipe 11 is connected to the lower part of the water tank 3 and is communicated to the device 12 using the secondary water, when the secondary water is needed, the secondary water is fed into the device 12 using the secondary water from the water tank 3 through the water supply pipe 11 by gravity for use;

preferably, the water transporting assembly is composed of an overflow pipe 7, the overflow pipe 7 is connected to the upper part of the floor water tank 3 and communicated with the top of the next floor water tank 3, when the floor secondary water is surplus, the surplus secondary water is transported from the floor water tank to the next floor water tank through the overflow pipe 7 for storage and standby, and if the floor is surplus, the surplus secondary water is transported to the next floor step by step;

preferably, the drainage component comprises a drainage pipe 9, a drainage pipe 10 and a secondary drainage pipe 13, the drainage pipe 9 is connected with the water delivery pipe 4 and the drainage pipe 10, the secondary drainage pipe 13 is connected with the equipment 12 using secondary water and the drainage pipe 10, when the secondary water which is not suitable for being used again is generated after the equipment 2 on the floor uses tap water, the first switch 14 is closed, so that the secondary water which is not used can be directly drained from the drainage pipe 9 to the drainage pipe 10; the middle part of the water discharge pipe 9 is higher than the interface of the water discharge pipe and the water delivery pipe 4, so that the usable secondary water can be conveyed to avoid overflowing from the interface; the secondary drainage pipe 13 is connected with the water using equipment 12 and the sewage discharge pipe 10, and discharges sewage generated after the water using equipment uses secondary water;

Further, the water saving system is characterized in that the water tanks, and a secondary water delivery assembly, a water supply assembly, a water delivery assembly, a water discharging assembly and a tap water inlet assembly which are arranged on the water tank 3 are arranged on other floors of the building in a repeated mode, so that secondary water generated by the previous floor can be input into the water tank of the next floor to be stored for later use, and is discharged from an overflow pipe of the water tank of the bottommost floor under the condition that all the water tanks are filled floor by floor from top to bottom, and the service efficiency of the secondary water is improved.

The foregoing is illustrative of the preferred embodiments of this invention, and it is to be understood that the invention is not limited to the precise form disclosed herein and that various other combinations, modifications, and environments may be resorted to, falling within the scope of the concept as disclosed herein, either as described above or as apparent to those skilled in the relevant art. And that modifications and variations may be effected by those skilled in the art without departing from the spirit and scope of the invention as defined by the appended claims.

Claims

1. A water conservation system characterized by: including water tank (3) and locate secondary water delivery subassembly, running water on water tank (3) are intake subassembly and water supply assembly, secondary water delivery subassembly intercommunication produces equipment (2) and water tank (3) of secondary water, and running water is intake subassembly intercommunication running water pipe and water tank (3), water supply assembly intercommunication water tank (3) and use equipment (12) of secondary water.

2. A water conservation system according to claim 1 wherein: the secondary water-using water delivery assembly, the tap water inlet assembly and the water supply assembly are integrally matched with the water conveying assembly and the water drainage assembly.

3. A water conservation system according to claim 2 wherein: the secondary water using and conveying assembly comprises a water conveying pipe (4), a first switch (14), a fourth switch (17) and a filtering device (19), wherein the water conveying pipe (4) is connected with a device (2) for generating secondary water using and a water tank (3), the first switch (14), the fourth switch (17) and the filtering device (19) are arranged on the water conveying pipe (4) and are sequentially arranged from top to bottom, the first switch (14) is positioned on an upper floor, and the fourth switch (17) is positioned on a next floor;

the tap water inlet assembly comprises a tap water inlet pipe (5) and a floating water closing valve (20), the floating water closing valve (20) is arranged at the lower end of the tap water inlet pipe (5) and is connected with the lower end of the tap water inlet pipe in a matching mode, and the tap water inlet pipe (5) is communicated with a tap water pipe;

the water supply assembly is composed of a water supply pipe (11), and the water supply pipe (11) is connected to the water tank (3) and communicated to equipment (12) using secondary water;

the water transporting assembly comprises a main water transporting pipe (6), an overflow pipe (7), an auxiliary water transporting pipe (8), a third switch (16), a fifth switch (18) and filtering equipment (19), wherein the main water transporting pipe (6) is connected with a water transporting pipe (4) and an overflow pipe (7) of the next floor, the overflow pipe (7) is connected to the upper part of a water tank (3) of the floor and communicated with the top of the water tank (3) of the next floor, the auxiliary water transporting pipe (8) is connected with the overflow pipe (7) and the main water transporting pipe (6) of the same floor, the third switch (16), the fifth switch (18) and the filtering equipment (19) are arranged on the overflow pipe (7) and sequentially arranged from top to bottom, the third switch (16) is positioned on the upper floor, the fifth switch (18) is positioned next to the next floor, and the position of the third switch (16) is slightly lower than a joint of the auxiliary water transporting pipe (8) and the overflow pipe (7);

the drainage assembly comprises a drainage pipe (9), a drainage pipe (10), a secondary drainage pipe (13) and a second switch (15), the drainage pipe (9) is connected with the water delivery pipe (4) and the drainage pipe (10), the secondary drainage pipe (13) is connected with equipment (12) using secondary water and the drainage pipe (10), and the second switch (15) is located on the drainage pipe (9) and is close to one end of the water delivery pipe (4).

4. A water conservation system according to claim 2 wherein: the secondary water using and conveying assembly comprises a water conveying pipe (4), a first switch (14), a fourth switch (17) and a filtering device (19), wherein the water conveying pipe (4) is connected with a device (2) for generating secondary water using and a water tank (3), the first switch (14), the fourth switch (17) and the filtering device (19) are arranged on the water conveying pipe (4) and are sequentially arranged from top to bottom, the first switch (14) is positioned on the upper floor, and the fourth switch (17) is positioned on the next floor;

the water supply assembly is composed of a water supply pipe (11), and the water supply pipe (11) is connected to the water tank (3) and communicated to a device (12) using secondary water;

the water conveying assembly is composed of an overflow pipe (7), and the overflow pipe (7) is connected to the upper part of the water tank (3) of the floor and communicated with the top of the water tank (3) of the next floor;

the drainage component comprises a drainage pipe (9), a drainage pipe (10) and a secondary drainage pipe (13), the drainage pipe (9) is connected with the water delivery pipe (4) and the drainage pipe (10), and the secondary drainage pipe (13) is connected with equipment (12) using secondary water and the drainage pipe (10);

the running water inlet assembly comprises a running water inlet pipe (5) and a floating water closing valve (20), the floating water closing valve (20) is arranged at the lower end of the running water inlet pipe (5) and is connected with the lower end of the running water inlet pipe in a matched mode, and the running water inlet pipe (5) is communicated with a running water pipe.