CN215857971U - Whole house water supply system - Google Patents

Abstract

The utility model provides a whole-house water supply system, which comprises: a water supply device, an electrolysis device, a water using device and a control device; the water supply device is positioned at the water supply front end of the whole house water supply system and is used for supplying water to the whole house; the electrolysis device is connected with the water supply device and electrolyzes to obtain acidic water and alkaline water; the water using device is positioned at the water supply tail end of the whole house water supply system and is connected with the pipeline of the electrolysis device; the control device is used for controlling the acidic water or the alkaline water generated by the electrolysis device to be selectively guided to the corresponding water using device. According to the technical scheme, the water utilization device positioned at the water supply tail end of the whole house water supply system can be provided with the acidic water or the alkaline water according to the requirement of domestic water, so that the purpose of improving the life quality of a user is achieved.

Description

Whole house water supply system

Technical Field

The utility model relates to the technical field of whole-house water supply, in particular to a whole-house water supply system.

Background

Water is closely related to human life, and our bodies and household water-related appliances are in contact with water every day. The quality of water is related to the physical health of each family member, so to speak, the good water is good life, and the quality of life is indistinguishable from the quality of daily water.

At present, domestic water is generally supplied by directly using tap water as a whole house, the domestic water mainly comprises drinking, cooking, bathing, washing and the like, but the tap water directly used as the whole house water supply brings much inconvenience to our life and reduces life quality, for example: the tap water is directly guided to a tap or a water heater to clean the skin of the human body, so that the skin is not smooth and fine any more, and is yellow and withered; tap water is directly guided to a dish washer to wash bowls and chopsticks or is guided to a washing machine to wash clothes, and stains and oil stains are difficult to remove.

SUMMERY OF THE UTILITY MODEL

In view of the above-mentioned drawbacks and deficiencies of the prior art, the present invention provides a whole-house water supply system, which can provide acidic water or alkaline water for a water consuming device located at a water supply end of the whole-house water supply system according to domestic water requirements, so as to improve the quality of life of users.

In order to achieve the above object, the present invention provides a whole house water supply system, wherein the whole house water supply system comprises: a water supply device, an electrolysis device, a water using device and a control device; the water supply device is positioned at the water supply front end of the whole house water supply system and is used for supplying water to the whole house; the electrolysis device is connected with the water supply device and electrolyzes to obtain acidic water and alkaline water; the water using device is positioned at the water supply tail end of the whole house water supply system and is connected with the pipeline of the electrolysis device; the control device is used for controlling the acidic water or the alkaline water generated by the electrolysis device to be selectively guided to the corresponding water using device.

In an embodiment of the present invention, the water using device includes at least one of a washing machine, a dishwasher, a water heater, and a faucet.

In an embodiment of the present invention, the control device includes a control main board and an electromagnetic valve electrically connected to the control main board, the electromagnetic valve has a first outlet end, a second outlet end and two inlet ends, the two inlet ends are respectively connected to the acidic water outlet end and the alkaline water outlet end of the electrolysis device in a one-to-one correspondence manner, the water using device is connected to the first outlet end, and the control main board is configured to control and select one of the acidic water and the alkaline water to be guided to the water using device from the first outlet end and the other to be discharged from the second outlet end.

In an embodiment of the utility model, the water supply device comprises a tap water pipe for introducing tap water and a water purifier connected with the tap water pipe, and a wastewater outlet end of the water purifier is connected with the electrolysis device so as to guide wastewater filtered by the water purifier to the electrolysis device.

In the embodiment of the utility model, the tap water pipe is also connected with an electrolysis device, and the electrolysis device is used for mixing the waste water and the tap water to obtain mixed water and electrolyzing the mixed water to obtain acidic water and alkaline water.

In an embodiment of the utility model, the whole-house water supply system further comprises a toilet tank and a first valve arranged between the waste water outlet end and the toilet tank, and the first valve is used for guiding the waste water to the toilet tank.

In an embodiment of the utility model, the toilet tank is further connected to a control device for controlling one of the sour water and the alkaline water not directed to the water using device to be directed to the toilet tank.

In the embodiment of the utility model, the tap water pipe is also respectively connected with the water using device and the toilet water tank.

In the embodiment of the utility model, the whole-house water supply system further comprises a TDS detection device, the TDS detection device is arranged between the water supply device and the electrolysis device and is electrically connected with the control mainboard, the TDS detection device is used for performing TDS detection on water supply entering the electrolysis device and feeding a TDS detection result back to the control mainboard, and the control mainboard is used for performing voltage control on the electrolysis device according to the TDS detection result.

In the embodiment of the utility model, the whole-house water supply system further comprises a PH detection device, the PH detection device is arranged between the electrolysis device and the water utilization device and is electrically connected with the control mainboard, the PH detection device is used for detecting the PH value of the acidic water or the alkaline water guided to the water utilization device and feeding the PH value detection result back to the control mainboard, and the control mainboard is used for carrying out voltage control on the electrolysis device according to the PH value detection result.

Through the technical scheme, the whole-house water supply system provided by the embodiment of the utility model has the following beneficial effects:

the water supply device is provided with the electrolysis device and the control device, so that the water supply of the water supply device is electrolyzed by the electrolysis device to obtain the acidic water and the alkaline water, and the acidic water or the alkaline water generated by the electrolysis device is selectively guided to the corresponding water using device by the control device according to the water using requirement, namely the water using device positioned at the water supply tail end of the whole house water supply system can guide the acidic water or the alkaline water as the domestic water, when the acidic water is applied to a tap or a water heater, the skin and the hair of a human body can be effectively protected, when the alkaline water is applied to a dish washing machine or a washing machine, the removing capability of stains and oil stains can be obviously improved, and the purpose of improving the life quality of a user can be achieved.

Additional features and advantages of the utility model will be set forth in the detailed description which follows.

Drawings

The accompanying drawings, which are included to provide an understanding of the utility model and are incorporated in and constitute a part of this specification, illustrate embodiments of the utility model and together with the description serve to explain the utility model without limiting the utility model. In the drawings:

FIG. 1 is a schematic diagram of the control of a whole-house water supply system according to an embodiment of the present invention;

FIG. 2 is a schematic diagram of a full house water supply system according to an embodiment of the present invention;

FIG. 3 is a schematic diagram of a washing machine as a water-consuming device in a water supply system for a whole house according to an embodiment of the present invention;

FIG. 4 is a schematic view of a dishwasher in a water supply system for a whole house according to an embodiment of the present invention;

FIG. 5 is a schematic diagram of a water heater as a water consuming device in a whole-house water supply system according to an embodiment of the present invention;

FIG. 6 is a schematic view of a faucet as a water consuming device in a whole house water supply system according to an embodiment of the present invention;

fig. 7 is another schematic view of a whole house water supply system according to an embodiment of the present invention.

Description of the reference numerals

1 Water supply installation 11 tap water pipe

12 water purifier 2 electrolyzer

3 control device 31 controls the main board

32 solenoid valve 4 water using device

41 washing machine and 42 dish washer

43 water heater 44 tap

5 6 TDS detection device of closestool water tank

7 PH detection device 81 first valve

82 second valve 83 third valve

84 fourth valve 85 fifth valve

86 sixth valve 87 seventh valve

88 eighth valve 89 ninth valve

Detailed Description

The following detailed description of specific embodiments of the utility model refers to the accompanying drawings. It should be understood that the specific embodiments described herein are merely illustrative and explanatory of the utility model and are not restrictive thereof.

At present, domestic water is generally supplied by directly using tap water as a whole house, the domestic water mainly comprises drinking, cooking, bathing, washing and the like, but the tap water directly used as the whole house water supply brings much inconvenience to our life and reduces life quality, for example: the tap water is directly guided to a tap or a water heater to clean the skin of the human body, so that the skin is not smooth and fine any more, and is yellow and withered; tap water is directly guided to a dish washer to wash bowls and chopsticks or is guided to a washing machine to wash clothes, and stains and oil stains are difficult to remove.

However, acid-base water can have many applications in domestic water, such as: the acidic water has a plurality of benefits to human skin, and the alkaline water can effectively clean oil stains. The acidic water is applied to the faucet or the water heater, so that the skin of a human body can be effectively protected, and certain benefits are provided for hair; the acidic water is used for the final flushing of the washing machine, so that the skin of a human body can be prevented from being damaged by alkaline substances remained on clothes; the use of alkaline water in the washing process of a dishwasher or washing machine can improve the removal of oil stains, and thus there are many benefits in applying acid-alkaline water to whole house water.

A whole house water supply system according to the present invention will be described with reference to the accompanying drawings.

Fig. 1 is a schematic view illustrating a control principle of a whole-house water supply system according to an embodiment of the present invention. Fig. 2 is a schematic structural view of a whole-house water supply system according to an embodiment of the present invention. As shown in fig. 1 and 2, in an embodiment of the present invention, there is provided a whole-house water supply system including:

the water supply device 1 is positioned at the front end of the water supply of the whole house water supply system and is used for supplying water to the whole house;

the electrolysis device 2 is connected with the water supply device 1 and electrolyzes to obtain acidic water and alkaline water;

the water utilization device 4 is positioned at the water supply tail end of the whole-house water supply system and is connected with the electrolysis device 2 through a pipeline; and

and the control device 3 is used for controlling the acidic water or the alkaline water generated by the electrolysis device 2 to be selectively guided to the corresponding water using device 4.

The water supply device 2 and the control device 3 are arranged in the whole house water supply system, so that the water supply of the water supply device 1 is electrolyzed by the electrolysis device 2 to obtain acidic water and alkaline water, and the acidic water or the alkaline water generated by the electrolysis device 2 is selectively guided to the corresponding water using device 4 by the control device 3 according to the water using requirement, namely the water using device 4 positioned at the water supply tail end of the whole house water supply system can guide the acidic water or the alkaline water as domestic water, when the acidic water is applied to a water tap 44 or a water heater 43, the skin and hair of a human body can be effectively protected, and when the alkaline water is applied to a dishwasher 42 or a washing machine 41, the removing capability of stains and oil stains can be obviously improved, so that the purpose of improving the life quality of a user can be achieved.

In particular, the PH values of the acidic water and the alkaline water obtained by the electrolyzing apparatus 2 in the present invention are set within appropriate ranges.

Fig. 2 is a schematic structural view of a whole-house water supply system according to an embodiment of the present invention. As shown in fig. 2, in the embodiment of the present invention, the water using device 4 includes at least one of a washing machine 41, a dishwasher 42, a water heater 43, and a water tap 44. The water supply device 4 for supplying water by using acidic water or alkaline water is not limited to the combination of the dishwasher 42, the washing machine 41, the faucet 44 and the water heater 43, and may be one of them or a combination of several of them, and the user may select them according to the actual situation.

In the embodiment of the present invention, the dishwasher 42, the washing machine 41, the faucet 44, and the water heater 43 are respectively connected to the electrolyzer 2 by pipes to be able to apply acidic water or alkaline water as domestic water to the whole house water supply.

Meanwhile, fig. 7 is another structural schematic diagram of the whole house water supply system according to an embodiment of the present invention. As shown in fig. 7, the pipes leading to the dishwasher 42, the washing machine 41, the water tap 44 and the water heater 43 may be provided with second valves 82, so that the opening and closing of each second valve 82 may be controlled to implement the acidic water or the alkaline water into the corresponding water using device 4. That is, when the electrolysis device 2 is used to guide the electrolyzed acidic water or alkaline water to the washing machine 41, the second valves 82 on the branch pipes leading to the washing machine 41 may be controlled to be opened, and the second valves 82 on the remaining three branch pipes may be controlled to be closed, so as to guide the electrolyzed acidic water or alkaline water obtained by the electrolysis device 2 to the washing machine 41; when the electrolysis device 2 is used to guide the electrolyzed acidic water or alkaline water to the dishwasher 42, the second valves 82 on the branch pipes leading to the dishwasher 42 may be controlled to be opened, and the second valves 82 on the remaining three branch pipes may be controlled to be closed, so as to guide the electrolyzed acidic water or alkaline water obtained by the electrolysis device 2 to the dishwasher 42; when the electrolysis device 2 is used to guide the electrolyzed acidic water or alkaline water to the water heater 43, the second valve 82 on the branch pipeline leading to the water heater 43 can be controlled to be opened, and the second valves 82 on the other three branch pipelines are controlled to be closed, so as to guide the electrolyzed acidic water or alkaline water obtained by the electrolysis device 2 to the water heater 43; when the electrolysis device 2 is used to guide the electrolyzed acidic water or alkaline water to the faucet 44, the second valve 82 on the branch line leading to the faucet 44 may be controlled to be opened, and the second valves 82 on the remaining three branch lines may be controlled to be closed, so as to guide the electrolyzed acidic water or alkaline water obtained by the electrolysis device 2 to the faucet 44.

Specifically, fig. 3 is a schematic structural diagram of a washing machine as a water utilization device in a whole-house water supply system according to an embodiment of the present invention. As shown in fig. 3, when the water using device 4 is the washing machine 41, after the washing machine 41 starts to work, a control instruction for selecting alkaline water to perform the first washing may be sent to the control device 3, and then the control device 3 controls the alkaline water generated by the electrolysis device 2 to be directed to the washing machine 41, so that the alkaline water may be used to wash the clothes in the washing machine 41, thereby improving the capability of removing dirt and oil stain on the clothes; when the washing machine 41 is operated to the last washing, a control command for selecting the acidic water may be issued to the control device 3, and then the control device 3 controls the acidic water generated from the electrolysis device 2 to be directed to the washing machine 41, so as to prevent the user from damaging the skin by the alkaline water remaining on the laundry when the user takes the laundry.

Specifically, fig. 4 is a schematic structural diagram of a water consumption device in a whole-house water supply system according to an embodiment of the present invention, when the water consumption device 4 is a dishwasher 42, after the dishwasher 42 starts to work, a control instruction for selecting alkaline water to perform first cleaning can be sent to the control device 3, and then the control device 3 controls the alkaline water generated by the electrolysis device 2 to be directed to the dishwasher 42, so that the alkaline water can be used to clean the bowls and chopsticks in the dishwasher 42, thereby improving the capability of removing oil stains on the bowls and chopsticks; in addition, when the dishwasher 42 is operated to the last washing, a control instruction for selecting the acidic water may be issued to the control device 3, and then the control device 3 controls the acidic water generated by the electrolysis device 2 to be directed to the dishwasher 42, so as to prevent the skin of the user from being damaged by the alkaline water remaining on the clothes when the user takes the bowls and chopsticks.

Specifically, fig. 5 is a schematic structural diagram of a water-using device in a whole-house water supply system according to an embodiment of the present invention. As shown in fig. 5, when the water consumption device 4 is a water heater 43, after the water heater 43 starts to operate, a control instruction for selecting the acidic water may be sent to the control device 3, and then the control device 3 controls the acidic water generated by the electrolysis device 2 to be directed to the water heater 43, so that the user can use the acidic water to wash the skin and hair, thereby effectively protecting the skin and hair of the human body.

Specifically, fig. 6 is a schematic structural diagram of a water faucet as a water using device in a whole-house water supply system according to an embodiment of the present invention. As shown in fig. 6, when the water using device 4 is a water tap 44, if the user is to wash the skin, a control command for selecting the acidic water can be sent to the control device 3, and then the control device 3 controls the acidic water generated by the electrolysis device 2 to be guided to the water tap 44, so that the skin of the human body can be effectively protected while the skin is washed; in addition, if the user is to wash the oil stains on the bowls, chopsticks or clothes, a control instruction for selecting the alkaline water may be issued to the control device 3, and then the control device 3 controls the alkaline water generated by the electrolysis device 2 to be directed to the faucet 44, so as to improve the oil stain removing capability.

In the embodiment of the present invention, fig. 7 is another schematic structural diagram of a whole-house water supply system according to an embodiment of the present invention. As shown in fig. 7, the control device 3 includes a control main board 31 and an electromagnetic valve 32 electrically connected to the control main board 31, the electromagnetic valve 32 has a first outlet end, a second outlet end and two inlet ends, the two inlet ends are respectively connected to the acidic water outlet end and the alkaline water outlet end of the electrolysis device 2 in a one-to-one correspondence manner, the water using device 4 is connected to the first outlet end, the control main board 31 is used for controlling and selecting one of the acidic water and the alkaline water to be guided to the water using device 4 from the first outlet end, and the other of the acidic water and the alkaline water is discharged from the second outlet end. Namely, the electromagnetic valve 32 can be controlled by the control main board 31 to operate, so that when the water consumption device 4 needs acidic water, the acidic water outlet end of the electrolysis device 2 is communicated with the water consumption device 4, and when the water consumption device 4 needs alkaline water, the alkaline water outlet end of the electrolysis device 2 is communicated with the water consumption device 4, so that the automatic switching of the supply of the acidic water or the alkaline water to the water consumption device 4 can be realized.

Specifically, the solenoid valve 32 of the present invention includes, but is not limited to, a two-position four-way valve, and may be a multi-way valve having more than two inlet ports and more than two outlet ports. The control device 3 in the present invention is not limited to the electromagnetic valve 32 controlled by the control main board 31, and may be a multi-way valve switched by manual control or a reversing conduction device with other suitable structure.

Further, the control main board 31 can be electrically connected to the second valves 82 on the pipes leading to the dishwasher 42, the washing machine 41, the water faucet 44 and the water heater 43, respectively, so that the second valves 82 can be automatically opened and closed through the control main board 31.

Further, if the third valve 83 is provided on a pipe leading to a common connection end of the first outlet end of the solenoid valve 32 and the dishwasher 42, the washing machine 41, the water tap 44, and the water heater 43, the fourth valve 84 is provided on a pipe leading to an external connection end of the second outlet end of the solenoid valve 32, and the control main board 31 is electrically connected to the third valve 83 and the fourth valve 84, respectively, the opening and closing of the third valve 83 and the fourth valve 84 can be controlled by the control main board 31, respectively. When the water consuming device 4 of the dishwasher 42, the washing machine 41, the faucet 44 and the water heater 43 needs to use acidic water or alkaline water, the main board 31 may be controlled to open the third valve 83 to guide the electrolyzed water or alkaline water obtained by the electrolysis device 2 to one of the dishwasher 42, the washing machine 41, the faucet 44 and the water heater 43, and the main board 31 may be controlled to open the fourth valve 84 to guide the other of the acidic water or alkaline water not guided to the water consuming device 4 to the outside.

In the embodiment of the present invention, fig. 7 is another schematic structural diagram of a whole-house water supply system according to an embodiment of the present invention. As shown in fig. 7, the water supply device 1 includes a tap water pipe 11 for introducing tap water, and a water purifier 12 connected to the tap water pipe 11, and a wastewater outlet end of the water purifier 12 may be connected to the electrolysis device 2 to guide the wastewater filtered by the water purifier 12 to the electrolysis device 2. Specifically, the water purifier 12 has a pure water outlet end and a waste water outlet end, the pure water outlet end can discharge pure water for drinking, and the waste water outlet end can discharge waste water containing impurities, i.e., in the present embodiment, the water purifier 12 can be introduced into a whole-house water supply system on the one hand, so as to provide filtered pure water for a user for drinking, and on the other hand, the waste water obtained after the water purifier 12 is filtered can be guided to the electrolysis device 2, so as to be reused after the waste water is electrolyzed by the electrolysis device 2 to obtain acidic water and alkaline water, so that reuse of the waste water discharged from the water purifier 12 can be completed, and water saving is facilitated.

Specifically, a tap water pipe 11 into which tap water is introduced and the water purifier 12 may be connected by a pipe, and a fifth valve 85 may be provided on the pipe between the tap water pipe 11 and the water purifier 12, and the fifth valve 85 may be electrically connected to the control main board 31, so that opening and closing of the fifth valve 85 may be controlled by the control main board 31. When the tap water stored in the water purifier 12 is lower than the minimum threshold, the water purifier 12 may issue a control instruction for opening the fifth valve 85 to the control main board, so that the tap water pipe 11 guides the tap water into the water purifier 12; when the tap water stored in the water purifier 12 reaches the maximum threshold value, the water purifier 12 may issue a control command for closing the fifth valve 85 to the control main board, so that the tap water pipe 11 stops supplying water to the water purifier 12.

Meanwhile, the waste water outlet end of the water purifier 12 may be connected to the electrolysis device 2 through a pipeline, a sixth valve 86 may be further disposed between the waste water outlet end and the electrolysis device 2, and the sixth valve 86 may be electrically connected to the control main board 31, so as to control the opening and closing of the sixth valve 86 through the control main board 31. When the water using device 4 needs to use acidic water or alkaline water, the control main board 31 may control the sixth valve 86 to open, so that the wastewater generated by the water purifier 12 may be guided to the electrolysis device 2 from the wastewater outlet end; when the water consuming device 4 does not need to use acidic water or alkaline water, the control board may control the sixth valve 86 to maintain the closed state.

Further, the tap water pipe 11 through which tap water is introduced is a water supply front end of the whole house water supply system, and the tap water pipe 11 may introduce tap water to a user through connection with a municipal tap water main.

Further, the water purifier 12 may be a pure water machine, and the core component of the pure water machine is a reverse osmosis membrane (RO membrane), which works as a process of concentrating a liquid, and the salt content of the water is continuously increased as the water passes through the surface of the RO membrane, and the osmotic pressure of the water is continuously increased, and when the osmotic pressure is increased to the pressure of the booster pump, the water cannot flow into the purified water end through the RO membrane. In addition, due to the increasing concentration of mineral substances in water, some mineral substances can be deposited on the surface of the reverse osmosis membrane and block the pores of the reverse osmosis membrane, so that the water yield of the reverse osmosis membrane is reduced and the salt rejection rate of the reverse osmosis membrane is reduced. Therefore, in order to avoid the above phenomena during the operation of the water purifier, the residues are discharged from the waste water outlet end of the water purifier along with the water. If the water is not discharged in time and needs to be purified, the waste water will have many effects, which directly affect the water yield and the water quality, and this is the reason why the water purifier 12 produces waste water. The waste water from the purifier 12 is also called concentrated water, i.e. the concentrated water formed by the tap water during the filtration process, and the total soluble solids (concentration) of the concentrated water is higher than that of the pure water obtained by the purifier 12 at the pure water outlet end.

In the embodiment of the present invention, fig. 7 is another schematic structural diagram of a whole-house water supply system according to an embodiment of the present invention. As shown in fig. 7, the tap water pipe 11 may be directly connected to a water inlet of the electrolysis device 2, and the electrolysis device 2 is configured to mix the waste water discharged from the water purifier 12 with tap water to obtain mixed water and electrolyze the mixed water to obtain acidic water and alkaline water. That is, the electrolysis device 2 may be connected to the tap water pipe 11 and the waste water outlet end of the water purifier 12 by pipes, respectively, so as to obtain a mixed water of the waste water discharged from the water purifier 12 and the tap water and electrolyze the mixed water. Since the amount of wastewater obtained by the water purifier 12 is limited, it is impossible to satisfy the water demand of the water using device 4 for a long time, and in this embodiment, tap water is introduced to be mixed with wastewater to be electrolyzed to obtain acidic water or alkaline water required by the user device, thereby facilitating the long-term satisfaction of the water demand of the water using device 4.

Further, a seventh valve 87 is disposed on the pipeline between the tap water pipe 11 and the water inlet end of the electrolysis device 2, and the seventh valve 87 can be electrically connected with the control main board 31, so that the opening and closing of the seventh valve 87 can be controlled by the control main board 31. When the water using device 4 needs to use acidic water or alkaline water, the control main board 31 may simultaneously control the sixth valve 86 and the seventh valve 87 to be opened, so that the wastewater generated by the water purifier 12 and the tap water introduced from the tap water pipe 11 are guided to the electrolysis device 2 to be mixed; when the water consuming device 4 does not need to use acidic water or alkaline water, the control main board 31 may control the sixth valve 86 and the seventh valve 87 to maintain the closed state.

In the embodiment of the present invention, fig. 7 is another schematic structural diagram of a whole-house water supply system according to an embodiment of the present invention. As shown in fig. 7, the whole-house water supply system further includes a toilet tank 5, and a first valve 81 disposed between the waste water outlet end and the toilet tank 5, the first valve 81 being used to guide waste water to the toilet tank 5. That is, the toilet tank 5 may be continuously introduced into the whole house water supply system so that when the water using device 4 has no demand for water and the waste water stored in the water purifier 12 has exceeded the capacity of the space available for storage, the first valve 81 may be opened to guide the waste water to the toilet tank 5, so that the waste water discharged from the water purifier 12 may be used for toilet flushing.

Specifically, the toilet tank 5 is the core part of the toilet, referred to in the industry as the "toilet heart", and is mainly composed of a water inlet valve, a water outlet valve and a button. The water inlet valve is a device for automatically controlling the water inlet of the toilet water tank 5, when the water level in the toilet water tank 5 is lowered to the working water level, the water inlet is automatically started, when the water level reaches the working water level, the toilet water tank 5 automatically stops water inlet, and the water outlet valve is a drainage device for controlling the toilet water tank 5, and can discharge the preset water amount and automatically close after being opened. Namely, the waste water outlet end can be connected with the water inlet valve of the toilet water tank 5 through a pipeline.

In addition, the first valve 81 may be electrically connected to the control main board 31, so that the opening and closing of the first valve 81 can be controlled by the control main board 31. Of course, the control main board 31 may also be in signal connection with the water purifier 12, the water purifier 12 may send the waste water storage amount of the water purifier 12 to the control main board 31 in real time, when the waste water storage amount reaches the maximum threshold value, the control main board 31 may control the first valve 81 to open, and when the waste water storage amount reaches the minimum threshold value, the control main board 31 may control the first valve 81 to close.

In the embodiment of the present invention, fig. 7 is another schematic structural diagram of a whole-house water supply system according to an embodiment of the present invention. As shown in fig. 7, the toilet tank 5 is further connected to the control device 3, and the control device 3 is used for controlling one of the acidic water and the alkaline water which is not guided to the water using device 4 to be guided to the toilet tank 5. The control device 3 comprises a control mainboard 31 and an electromagnetic valve 32 electrically connected with the control mainboard 31, wherein a second outlet end of the electromagnetic valve 32 can be in pipeline connection with the toilet water tank 5, namely when the water using device 4 in pipeline connection with the first outlet end needs to use acid water, the second outlet end of the electromagnetic valve 32 can simultaneously discharge the generated alkaline water to the toilet water tank 5; when the water using device 4 connected with the first outlet end pipe needs to use alkaline water, the second outlet end of the electromagnetic valve 32 can simultaneously discharge the generated acidic water to the toilet tank 5, so that water resources can be further saved.

Specifically, a fourth valve 84 electrically connected to the control main board 31 is disposed on a pipe connecting the second outlet end of the solenoid valve 32 with the outside, and an outlet end of the fourth valve 84 may be connected to the toilet tank 5 through a pipe to guide one of the non-guided water consumption devices 4 in the acidic water and the alkaline water to the toilet tank 5, or may be connected to an indoor sewer through a pipe branch to directly discharge one of the non-guided water consumption devices 4 in the acidic water and the alkaline water as waste water. In addition, an eighth valve 88 can be arranged on a pipeline leading to an indoor sewer, the eighth valve 88 can be electrically connected with the control main board 31, when the storage amount of the waste water in the toilet water tank 5 reaches a maximum threshold value, the control main board 31 can control the eighth valve 88 to be opened so as to directly discharge one of the acidic water and the alkaline water which is not guided to the water using device 4 to the sewer as the waste water; when the storage amount of the waste water in the toilet tank 5 does not reach the maximum threshold value, the control main board 31 may control the eighth valve 88 to close, so that one of the acidic water and the alkaline water which is not directed to the water using device 4 may be directed to the toilet tank 5.

In the embodiment of the present invention, fig. 7 is another schematic structural diagram of a whole-house water supply system according to an embodiment of the present invention. As shown in fig. 7, the tap water pipe 11 is also connected to the water using device 4 and the toilet tank 5, respectively. The water pipe 11 that introduces the running water promptly can also branch and carry out the pipe connection with the public end of intaking of water consuming device 4 and toilet tank 5 to direct running water respectively to water consuming device 4 and toilet tank 5, thereby can further perfect whole room water supply system, with the alternative that increases domestic water, improve user's experience and feel.

Specifically, the pipelines of the branch of the tap water pipe 11, which are connected to the public water inlet end of the water using device 4 and the toilet tank 5, may further be respectively provided with a ninth valve 89, and the ninth valve 89 may be electrically connected to the control main board 31 to control the ninth valve 89 to open or close through the control main board 31.

More specifically, when the user selects the acidic water or the alkaline water electrolyzed by the electrolysis device 2 to be used as the domestic water of the water using device 4, the control main board 31 controls the ninth valve 89 on the pipe between the tap water pipe 11 and the common water inlet end of the water using device 4 to be kept closed; when the user selects the tap water introduced from the tap water pipe 11 as the domestic water of the water using device 4, the control main board 31 may control the ninth valve 89 on the pipe between the tap water pipe 11 and the public water inlet end of the water using device 4 to be opened, so that the tap water pipe 11 directly supplies water to the public water inlet end of the water using device 4. When the amount of wastewater passed to the toilet tank 5 by the water purifier 12 and the electrolysis device 2 has not reached the maximum threshold value, the control main board 31 may control the ninth valve 89 on the pipe between the tap water pipe 11 and the toilet tank 5 to open to guide the tap water introduced from the tap water pipe 11 to the toilet tank 5; when the water consumption in the toilet tank 5 reaches the maximum threshold value, the control main board 31 may control the ninth valve 89 on the pipe between the water pipe 11 and the toilet tank 5 to close, so that the water pipe 11 stops supplying water to the toilet tank 5.

In an embodiment of the present invention, fig. 2 is a schematic structural diagram of a whole-house water supply system according to an embodiment of the present invention, as shown in fig. 2, the whole-house water supply system further includes a TDS detection device 6, the TDS detection device 6 is disposed between the water supply device 1 and the electrolysis device 2, the TDS detection device 6 is electrically connected to the control motherboard 31, the TDS detection device 6 is configured to perform TDS detection on the water supply entering the electrolysis device 2 and feed back a TDS detection result to the control motherboard 31, and the control motherboard 31 is configured to perform voltage control on the electrolysis device 2 according to the TDS detection result. That is, the control main board 31 may be electrically connected to the electrolyzer 2, so that the voltage of the electrolyzer 2 can be controlled by the control main board 31. In this embodiment, the TDS detection device 6 can detect the quality of the supplied water entering the electrolysis device 2, so as to feed back the detection result to the control main board 31, and the voltage for electrolysis of the electrolysis device 2 is adjusted by the control main board 31, so as to control the PH value of the acidic water or the alkaline water electrolyzed by the electrolysis device 2.

Specifically, TDS is an acronym of total soluble solids (totaldisolved solids) and refers to the concentration of total soluble solids in water in milligrams per liter (MG/L), which mainly reflects the concentration of Ca2+, MG2+, Na +, K + and other ions in water, and has a good correspondence with the hardness and conductivity of water, and the lower the TDS value, the lower the concentration of Ca2+, MG2+, Na +, K + and the like in water, the lower the conductivity. In the present invention, the TDS detection device 6 may be a TDS tester, which is a special tester for measuring the total dissolved solids content of water. Purified water contains very little dissolved total solids, ranging from zero to tens of milligrams per liter. If the water becomes contaminated or has dissolved into many other electrolytic species, its total solids content increases. TDS tester can come out this index direct measurement, thereby can insert the test end of TDS tester in the pipeline between water supply installation 1 and the electrolytic device 2, TDS tester and control mainboard 31 signal connection, thereby just can feed back the foreign matter content that dissolves in getting into electrolytic device 2's the water supply to control mainboard 31, so that control mainboard 31 carries out the voltage of electrolysis to electrolytic device 2 according to the foreign matter content that dissolves in the water supply and adjusts, the pH value of the acid water or the alkaline water that final control electrolysis obtained.

In an embodiment of the present invention, fig. 2 is a schematic structural diagram of a whole-house water supply system according to an embodiment of the present invention, as shown in fig. 2, the whole-house water supply system further includes a PH detection device 7, the PH detection device 7 is disposed between the electrolysis device 2 and the water using device 4, the PH detection device 7 is electrically connected to the control main board 31, the PH detection device 7 is configured to perform PH detection on acidic water or alkaline water led to the water using device 4 and feed back a PH detection result to the control main board 31, and the control main board 31 is configured to perform voltage control on the electrolysis device 2 according to the PH detection result. Can carry out the PH value to the sour water or the alkaline water of guiding water installation 4 through PH detection device 7 promptly and detect, and PH detection device 7 is connected with control mainboard 31 electricity to can feed back PH value testing result to control mainboard 31, so that control mainboard 31 carries out the voltage of electrolysis to electrolytic device 2 according to PH value testing result and adjusts, with the PH value of the sour water or the alkaline water that finally can adjust guiding water installation 4, make it keep in a suitable within range.

Specifically, the PH detection device 7 is disposed on a pipeline between a first outlet end of the solenoid valve 32 and a common water inlet end of the water using device 4, so as to detect the PH of the acidic water or the alkaline water entering the water using device 4.

More specifically, when the first outlet end guides the acidic water to the water consumption device 4, the PH detection device 7 disposed on the pipeline between the first outlet end and the public water intake end of the water consumption device 4 can detect the PH value of the acidic water, and feed the PH value detection result back to the control main board 31, the control main board 31 compares the PH value detection result with the preset PH value range, if the PH value detection result of the acidic water is within the preset PH value range, the electrolysis of the electrolytic device 2 is continuously controlled according to the existing voltage, if the PH value detection result of the acidic water is not within the preset PH value range, the control main board 31 can adjust the voltage of the electrolysis of the electrolytic device 2 according to the PH value detection result until the PH value detection result obtained by the PH detection device 7 is within the preset PH value range. When the first outlet end leads alkaline water to the water consumption device 4, the PH detection device 7 arranged on the pipeline between the first outlet end and the public water inlet end of the water consumption device 4 can detect the PH value of the alkaline water, and feeds the PH value detection result back to the control mainboard 31, the control mainboard 31 compares the PH value detection result with the preset PH value range, if the PH value detection result of the alkaline water is in the preset PH value range, the electrolysis of the electrolytic device 2 is continuously controlled according to the existing voltage, if the PH value detection result of the alkaline water is not in the preset PH value range, the control mainboard 31 can adjust the voltage of the electrolysis of the electrolytic device 2 according to the PH value detection result, until the PH value detection result obtained by the detection of the PH detection device 7 is in the preset PH value range.

In the description of the present invention, it is to be understood that the terms "first", "second" and the like are used for descriptive purposes only and are not to be construed as indicating or implying relative importance or implying any number of technical features indicated. Thus, a feature defined as "first" or "second" may explicitly or implicitly include at least one such feature. In the description of the present invention, "a plurality" means at least two, e.g., two, three, etc., unless specifically limited otherwise.

In the present invention, unless otherwise expressly stated or limited, the terms "mounted," "connected," "secured," and the like are to be construed broadly and can, for example, be fixedly connected, detachably connected, or integrally formed; may be mechanically coupled, may be electrically coupled or may be in communication with each other; they may be directly connected or indirectly connected through intervening media, or they may be connected internally or in any other suitable relationship, unless expressly stated otherwise. The specific meanings of the above terms in the present invention can be understood by those skilled in the art according to specific situations.

In the description herein, references to the description of the term "one embodiment," "some embodiments," "an example," "a specific example," or "some examples," etc., mean that a particular feature, structure, material, or characteristic described in connection with the embodiment or example is included in at least one embodiment or example of the utility model. In this specification, the schematic representations of the terms used above are not necessarily intended to refer to the same embodiment or example. Furthermore, the particular features, structures, materials, or characteristics described may be combined in any suitable manner in any one or more embodiments or examples. Furthermore, various embodiments or examples and features of different embodiments or examples described in this specification can be combined and combined by one skilled in the art without contradiction.

Although embodiments of the present invention have been shown and described above, it is understood that the above embodiments are exemplary and should not be construed as limiting the present invention, and that variations, modifications, substitutions and alterations can be made to the above embodiments by those of ordinary skill in the art within the scope of the present invention.

Claims (10)

1. A whole house water supply system, characterized in that it comprises:

the water supply device (1) is positioned at the water supply front end of the whole house water supply system and is used for supplying water to the whole house;

the electrolysis device (2) is connected with the water supply device (1) and electrolyzes to obtain acidic water and alkaline water;

the water utilization device (4) is positioned at the water supply tail end of the whole house water supply system and is in pipeline connection with the electrolysis device (2); and

a control device (3), said control device (3) being adapted to control said acidic water or said alkaline water produced by said electrolysis device (2) to be selectively directed to a respective said water consuming device (4).

2. The whole house water supply system according to claim 1, wherein the water usage device (4) comprises at least one of a washing machine (41), a dishwasher (42), a water heater (43) and a water tap (44).

3. The whole house water supply system according to claim 1, wherein the control device (3) comprises a control main board (31) and a solenoid valve (32) electrically connected to the control main board (31), the solenoid valve (32) has a first outlet end, a second outlet end and two inlet ends, the two inlet ends are respectively connected to the acidic water outlet end and the alkaline water outlet end of the electrolysis device (2) in a one-to-one correspondence, the water consumption device (4) is connected to the first outlet end, and the control main board (31) is used for controlling and selecting one of the acidic water and the alkaline water to be guided to the water consumption device (4) from the first outlet end and the other one to be discharged from the second outlet end.

4. The whole house water supply system according to claim 1, wherein the water supply device (1) comprises a tap water pipe (11) for introducing tap water, and a water purifier (12) connected to the tap water pipe (11), and a wastewater outlet end of the water purifier (12) is connected to the electrolysis device (2) to guide the wastewater filtered by the water purifier (12) to the electrolysis device (2).

5. The whole house water supply system according to claim 4, wherein the tap water pipe (11) is further connected to the electrolysis device (2), and the electrolysis device (2) is configured to mix the waste water and the tap water to obtain mixed water, and electrolyze the mixed water to obtain the acidic water and the alkaline water.

6. The whole house water supply system according to claim 4, further comprising a toilet tank (5) and a first valve (81) arranged between the waste water outlet and the toilet tank (5), the first valve (81) being adapted to direct the waste water to the toilet tank (5).

7. The whole house water supply system according to claim 6, wherein the toilet tank (5) is further connected to the control device (3), the control device (3) being adapted to control the one of the acidic water and the alkaline water not directed to the water use device (4) to be directed to the toilet tank (5).

8. The whole house water supply system according to claim 6, wherein the water supply pipe (11) is further connected to the water using device (4) and the toilet tank (5), respectively.

9. The whole house water supply system according to claim 3, further comprising a TDS detection device (6), wherein the TDS detection device (6) is arranged between the water supply device (1) and the electrolysis device (2), and the TDS detection device (6) is electrically connected with the control main board (31), the TDS detection device (6) is used for performing TDS detection on the water supply entering the electrolysis device (2) and feeding back a TDS detection result to the control main board (31), and the control main board (31) is used for performing voltage control on the electrolysis device (2) according to the TDS detection result.

10. The whole house water supply system according to claim 3, further comprising a pH detection device (7), wherein the pH detection device (7) is disposed between the electrolysis device (2) and the water consumption device (4), the pH detection device (7) is electrically connected with the control mainboard (31), the pH detection device (7) is used for detecting the pH value of the acidic water or the alkaline water guided to the water consumption device (4) and feeding the detected pH value back to the control mainboard (31), and the control mainboard (31) is used for controlling the voltage of the electrolysis device (2) according to the detected pH value.

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