CN221260959U - Water saving system - Google Patents

Abstract

The application discloses a water saving system, and relates to the technical field of reclaimed water. The water saving system comprises a water tank group, a recovery assembly and a detection assembly. The recovery component is connected with the water tank group; one end of the detection component is connected with an external water pipe, one end of the detection component, which is far away from the external water pipe, is connected with the recovery component, the detection component is used for detecting whether the water quality in the external water pipe is qualified or not, and the recovery component is used for recovering the water in the external water pipe and carrying out water supplementing treatment on the water tank group. The application saves water resources, reduces the production cost, and has convenient use and flexible operation.

Description

Water saving system

Technical Field

The application relates to the technical field of reclaimed water, in particular to a water saving system.

Background

The workshop site sterilization machine adopts a three-stage treatment form of circulating hot water sterilization, circulating warm water precooling and cooling by spraying cooling water. The treatment mode has the characteristics of automatic sterilization temperature control and the like. After the softened water injected into the water tank of each area reaches a set liquid level, the circulating pump is used for carrying out heat ventilation to inject the water into the spray pipe, and the water is sprayed to the surface of a product through the spray nozzle. The water is heated and cooled by the heat exchanger, and the pop cans sealed by the sealing cover are conveyed into the spraying area by the net chain plate.

When the water temperature of the product temperature zone reaching the cooling stage after the circulating hot water sterilization and spraying is far higher than the required cooling temperature, a large amount of cooling water is required to be supplemented for cooling so as to reach the set temperature. When the cooling water is replenished to a high position, the water automatically overflows out to be discharged, and a large amount of softened water is wasted in the whole water replenishing and cooling process.

In addition, the empty tank of raw materials is carried to the tank washing machine through the cableway, and the softened water of the tank washing machine washes the tank through the nozzle under the pressure of 0.2MPa, and after the flushing is finished, the compressed air is used for blowing the tank to enter into the tank for filling, and the water after flushing is directly discharged from the water outlet at the bottom of the tank, so that a large amount of softened water is wasted.

Disclosure of utility model

Accordingly, the present application is directed to a water saving system, which aims to solve the technical problems in the prior art.

In order to achieve the above purpose, the technical scheme adopted by the application is as follows:

The embodiment of the application provides a water saving system, which comprises:

a water tank group;

the recovery assembly is connected with the water tank group;

The water tank group is characterized by comprising a detection component, wherein one end of the detection component is connected with an external water pipe, one end of the detection component, which is far away from the external water pipe, is connected with a recovery component, the detection component is used for detecting whether the water quality in the external water pipe is qualified or not, and the recovery component is used for recovering the water in the external water pipe and carrying out water supplementing treatment on the water tank group.

In one embodiment of the application, the recovery assembly comprises:

A first water tank in communication with the detection assembly;

the second water tank is communicated with the first water tank and is used for storing water flowing into the second water tank from the first water tank.

In one embodiment of the application, the recovery assembly further comprises a second sensor arranged on one side of the first water tank, and the second sensor is used for detecting whether the first water tank is full of water.

In one embodiment of the application, the recycling assembly further comprises:

The first water pump is arranged between the first water tank and the detection assembly and is used for conveying water in the detection assembly into the first water tank;

The second water pump is arranged between the first water tank and the second water tank and is used for conveying water of the first water tank into the second water tank;

And the third water pump is arranged between the second water tank and the water tank group and is used for conveying water of the second water pump into the water tank group.

In one embodiment of the application, the recycling assembly further comprises:

The third sensor is arranged at one end, close to the third water pump, of the second water tank and is used for detecting whether water exists in the second water tank or not;

The fourth sensor is arranged at one end, far away from the third water pump, of the second water tank and is used for detecting whether the second water tank is full of water or not.

In one embodiment of the present application, the recovery assembly further includes a filtering portion disposed at an end of the third water pump near the water tank set, and the filtering portion is used for filtering water delivered into the water tank set by the recovery assembly.

In one embodiment of the application, the recovery assembly further comprises a first valve, the first valve is arranged at one end of the first water tank far away from the second water pump, and one end of the first valve far away from the first water tank is communicated with the second water tank, wherein the first water tank, the second water pump, the second water tank and the first valve form a loop.

In one embodiment of the present application, the recovery assembly further includes a first sensor disposed between the first water pump and the detection assembly, the first sensor being configured to detect whether water is present between the first water pump and the detection assembly.

In one embodiment of the application, the detection assembly comprises a turbidity meter, wherein the turbidity meter is arranged on one side of the first sensor, which is away from the first water pump, and is used for detecting whether the water quality of the water in the detection assembly is qualified.

In one embodiment of the application, the detection assembly further comprises a recovery tank for recovering water flowing into the detection assembly that is not acceptable for water quality detection.

Compared with the prior art, the application has the beneficial effects that: the application provides a water saving system which comprises a water tank group, a recovery assembly and a detection assembly. The recovery component is connected with the water tank group; one end of the detection component is connected with an external water pipe, one end of the detection component, which is far away from the external water pipe, is connected with the recovery component, the detection component is used for detecting whether the water quality in the external water pipe is qualified or not, and the recovery component is used for recovering the water in the external water pipe and carrying out water supplementing treatment on the water tank group. According to the application, overflow water and tank washing water of the sterilizing machine are recycled, and the overflow water and the tank washing water can be recycled for cooling and water supplementing of the sterilizing machine under the condition that the water quality of the overflow water and the tank washing water is qualified, so that water resources are saved, the production cost is reduced, the use is convenient, and the operation is flexible.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present application, the drawings that are needed in the embodiments will be briefly described below, it being understood that the following drawings only illustrate some embodiments of the present application and therefore should not be considered as limiting the scope, and other related drawings may be obtained according to these drawings without inventive effort for a person skilled in the art.

FIG. 1 is a schematic view of a water conservation system according to the present application;

Fig. 2 shows another view of the water saving system according to the present application.

Description of main reference numerals:

100-a water saving system; 110-a detection component; 111-a recovery tank; 112-a fifth pneumatic valve; 113-a third pneumatic valve; 114-turbidity meter; 115-fourth pneumatic valve; 116-a second one-way valve; 117-a second pneumatic valve; 120-a recovery assembly; 121-a first sensor; 122-a second valve; 123-a first water pump; 124-a first water tank; 125-a second sensor; 126-eleventh valve; 127-third valve; 128-a second water pump; 129-eighth valve; 121 a-a first one-way valve; 121 b-seventh valve; 121 c-a third water pump; 122 a-fourth valve; 122 b-twelfth valve; 122 c-a fifth valve; 123 a-sixth valve; 123 b-tenth valve; 123 c-a first valve; 124 a-ninth valve; 124 b-a third sensor; 124 c-a second water tank; 125 a-fourth sensor; 125 b-a first pneumatic valve; 130-a water tank set; 131-a third water tank; 132-sixth pneumatic valve; 133-an external water refill tube; 134-seventh pneumatic valve; 135-fourth tank; 136-eighth pneumatic valve; 137-a fifth water tank; 137 a-fifth sensor; 138-a sixth water tank; 139-a ninth pneumatic valve; 101-external water pipe.

Detailed Description

Embodiments of the present application are described in detail below, examples of which are illustrated in the accompanying drawings, wherein like or similar reference numerals refer to like or similar elements or elements having like or similar functions throughout. The embodiments described below by referring to the drawings are illustrative only and are not to be construed as limiting the application.

In the description of the present application, it should be understood that the terms "center", "longitudinal", "lateral", "length", "width", "thickness", "upper", "lower", "front", "rear", "left", "right", "vertical", "horizontal", "top", "bottom", "inner", "outer", "clockwise", "counterclockwise", "axial", "radial", "circumferential", etc. indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings are merely for convenience in describing the present application and simplifying the description, and do not indicate or imply that the device or element being referred to must have a specific orientation, be configured and operated in a specific orientation, and therefore should not be construed as limiting the present application.

Furthermore, the terms "first," "second," and the like, are used for descriptive purposes only and are not to be construed as indicating or implying a relative importance or implicitly indicating the number of technical features indicated. Thus, a feature defining "a first" or "a second" may explicitly or implicitly include one or more such feature. In the description of the present application, the meaning of "a plurality" is two or more, unless explicitly defined otherwise.

In the present application, unless explicitly specified and limited otherwise, the terms "mounted," "connected," "secured," and the like are to be construed broadly, and may be, for example, fixedly connected, detachably connected, or integrally formed; can be mechanically or electrically connected; can be directly connected or indirectly connected through an intermediate medium, and can be communicated with the inside of two elements or the interaction relationship of the two elements. The specific meaning of the above terms in the present application can be understood by those of ordinary skill in the art according to the specific circumstances.

In the present application, unless expressly stated or limited otherwise, a first feature "up" or "down" a second feature may be the first and second features in direct contact, or the first and second features in indirect contact via an intervening medium. Moreover, a first feature being "above," "over" and "on" a second feature may be a first feature being directly above or obliquely above the second feature, or simply indicating that the first feature is level higher than the second feature. The first feature being "under", "below" and "beneath" the second feature may be the first feature being directly under or obliquely below the second feature, or simply indicating that the first feature is less level than the second feature.

As shown in fig. 1 and 2, an embodiment of the present application provides a water conservation system 100. The water conservation system 100 includes a tank assembly 130, a recovery assembly 120, and a detection assembly 110.

Wherein the recovery assembly 120 is connected to the water tank set 130.

Specifically, one end of the detecting component 110 is connected to the external water pipe 101, for example, by a pipe connection.

The end of the detection assembly 110 remote from the external water pipe 101 is connected to the recovery assembly 120, optionally the detection assembly 110 is connected to the recovery assembly 120, for example by a pipe.

The detection assembly 110 is configured to detect whether the water in the external water pipe 101 is qualified, and the recovery assembly 120 is configured to recover the water in the external water pipe 101 and perform water replenishment treatment on the water tank set 130.

Alternatively, the water in the external water pipe 101 is, for example, tank washing water, that is, in this embodiment, the tank washing water with qualified water quality is recovered to the recovery assembly 120, and the tank washing water is conveyed to the water tank set 130 through the recovery assembly 120 for use, so that water resources are saved and production cost is reduced.

In this embodiment, the water conservation system 100 includes a water tank set 130, a recovery assembly 120, and a detection assembly 110. The embodiment recycles overflow water and tank washing water of the sterilizing machine, can be recycled for cooling and water supplementing of the sterilizing machine under the condition that the water quality of the overflow water and the tank washing water is qualified, saves water resources, reduces production cost, is convenient to use and flexible to operate.

Specifically, the recovery assembly 120 includes a first water tank 124 and a second water tank 124c.

Wherein the first water tank 124 is in communication with the detection assembly 110, optionally in a piping communication, for example, the water in the detection assembly 110 may flow into the first water tank 124.

The second water tank 124c communicates with the first water tank 124, and the second water tank 124c is used to store water flowing from the first water tank 124 to the second water tank 124 c. Optionally, the second water tank 124c is connected to the first water tank 124, for example, by a pipe.

Optionally, the recovery assembly 120 further includes a second sensor 125, where the second sensor 125 is disposed on one side of the first water tank 124, and the second sensor 125 is configured to detect whether the first water tank 124 is full of water.

Alternatively, the second sensor 125 is, for example, a liquid level sensor, and the second sensor 125 is located near the top of the first water tank 124, then the second sensor 125 may be used to detect whether the first water tank 124 is full of water.

Optionally, the recovery assembly 120 further includes a first water pump 123, a second water pump 128, and a third water pump 121c.

Wherein the first water pump 123 is disposed between the first water tank 124 and the detection assembly 110, and the first water pump 123 is used for delivering water in the detection assembly 110 into the first water tank 124.

Alternatively, the first water pump 123 is in communication with both the detection assembly 110 and the first water tank 124, such as pipes, and the first water pump 123 may provide power for the detection assembly 110 to transfer water into the first water tank 124.

In this embodiment, the recovery assembly 120 further includes a first sensor 121, where the first sensor 121 is disposed between the first water pump 123 and the detection assembly 110, and the first sensor 121 is configured to detect whether water exists between the first water pump 123 and the detection assembly 110.

Optionally, a second valve 122 is disposed between the first water pump 123 and the first sensor 121, and the second valve 122 is used to control whether the wash tank water flows into the first water pump 123. Wherein the second valve 122 is in communication with the first water pump 123 and the first sensor 121, respectively, for example, in a pipe communication manner.

Wherein the second water pump 128 is disposed between the first water tank 124 and the second water tank 124c, the second water pump 128 is used to deliver water of the first water tank 124 into the second water tank 124 c.

Optionally, the second water pump 128 is respectively connected to the first water tank 124 and the second water tank 124c, and the second water pump 128 is respectively connected to the first water tank 124 and the second water tank 124c by pipes, for example. The second water pump 128 may power the first water tank 124 to deliver water to the second water tank 124 c.

Optionally, a third valve 127 is disposed between the second water pump 128 and the first water tank 124, and the third valve 127 is used to control whether the wash tank water flows into the second water pump 128. Wherein the third valve 127 is in communication with the second water pump 128 and the first water tank 124, respectively, such as by a pipe.

A first check valve 121a is disposed between the second water pump 128 and the second water tank 124c, and the first check valve 121a is used to prevent water from flowing back from the second water pump 128 to the second water tank 124 c. The first check valve 121a is connected to the second water pump 128 and the second water tank 124c, respectively, and the communication manner is, for example, pipe connection.

Alternatively, the third water pump 121c is disposed between the second water tank 124c and the water tank set 130, and the third water pump 121c is configured to deliver water from the second water pump 128 to the water tank set 130.

Alternatively, the third water pump 121c is respectively connected to the second water tank 124c and the water tank set 130, and the third water pump 121c is respectively connected to the second water tank 124c and the water tank set 130 by pipes, for example. The third water pump 121c may power the second water tank 124c to deliver water to the water tank set 130.

A fourth valve 122a is disposed between the third water pump 121c and the second water tank 124c, and the fourth valve 122a is used for controlling whether the water in the second water tank 124c flows into the third water pump 121 c. The fourth valve 122a is connected to the third water pump 121c and the second water tank 124c, respectively, for example, by a pipe connection.

Optionally, the recycling assembly 120 further includes a third sensor 124b and a fourth sensor 125a.

Wherein the third sensor 124b is disposed at one end of the second water tank 124c near the third water pump 121c, and the third sensor 124b is configured to detect whether water is present in the second water tank 124 c.

Alternatively, the third sensor 124b is, for example, a liquid level sensor, that is, the third sensor 124b is disposed at the bottom of the second water tank 124c, so as to detect whether there is water in the second water tank 124 c.

The fourth sensor 125a is disposed at an end of the second water tank 124c away from the third water pump 121c, and the fourth sensor 125a is configured to detect whether the second water tank 124c is full of water.

Specifically, the fourth sensor 125a is, for example, a liquid level sensor, that is, the fourth sensor 125a is disposed on top of the second water tank 124c, so as to detect whether the second water tank 124c is full of water.

Optionally, the recovery assembly 120 further includes a filtering portion disposed at an end of the third water pump 121c near the water tank set 130, and the filtering portion is used for filtering water delivered into the water tank set 130 by the recovery assembly 120.

Specifically, the filtering portion includes a first filtering member and a second filtering member, where the first filtering member and the second filtering member are both connected to the third water pump 121c, and the connection manners thereof are all, for example, pipe connection.

The first filtering component includes a fifth valve 122c and a sixth valve 123a, the fifth valve 122c is disposed at one end of the third water pump 121c away from the fourth valve 122a, the sixth valve 123a is disposed at one side of the fifth valve 122c away from the third water pump 121c, the fifth valve 122c is connected with the sixth valve 123a and the third water pump 121c, and the fifth valve 122c is connected with the sixth valve 123a and the third water pump 121c through pipes, for example.

Specifically, the fifth valve 122c and the sixth valve 123a may filter the wash tank water passing through the fifth valve 122c and the sixth valve 123 a.

The second filtering element includes a seventh valve 121b and an eighth valve 129, the seventh valve 121b is disposed at one end of the third water pump 121c away from the fourth valve 122a, the eighth valve 129 is disposed at one side of the seventh valve 121b away from the third water pump 121c, the seventh valve 121b is connected with the eighth valve 129 and the third water pump 121c, and the seventh valve 121b is connected with the eighth valve 129 and the third water pump 121c through pipes, for example.

Specifically, the seventh valve 121b and the eighth valve 129 may filter the wash tank water passing through the seventh valve 121b and the eighth valve 129.

A ninth valve 124a is disposed on a side of the sixth valve 123a facing away from the fifth valve 122c, and a side of the ninth valve 124a near the sixth valve 123a is connected to the sixth valve 123a and the eighth valve 129, respectively. The ninth valve 124a is connected to both the sixth valve 123a and the eighth valve 129, for example, by pipes.

Optionally, a first pneumatic valve 125b is disposed on a side of the ninth valve 124a near the water tank set 130, and a side of the first pneumatic valve 125b facing away from the ninth valve 124a is connected to the water tank, where the first pneumatic valve 125b is used to control water in the third water pump 121c to flow into the water tank set 130. The ninth valve 124a is used for adjusting the water supplementing flow and pressure.

Wherein the first pneumatic valve 125b is connected to both the tank set 130 and the ninth valve 124a, for example, by a pipe.

Optionally, the recovery assembly 120 further includes a first valve 123c, the first valve 123c is disposed at an end of the first water tank 124 away from the second water pump 128, and an end of the first valve 123c away from the first water tank 124 is in communication with the second water tank 124c, wherein the first water tank 124, the second water pump 128, the second water tank 124c and the first valve 123c form a loop, and the first valve 123c is configured to form a loop of the cleaning recovery assembly 120.

The first valve 123c is connected to the first water tank 124 and the second water tank 124c, for example, through pipes, and the side of the first valve 123c near the first water tank 124 is also communicated with the first water pump 123, so that the first valve 123c is in a closed state during the production process, and the first valve 123c can be opened when cleaning is required.

Optionally, a tenth valve 123b is disposed between the first valve 123c and the second water tank 124c, and the tenth valve 123b is connected to the first valve 123c and the second water tank 124c, respectively, in a piping connection manner, for example. The tenth valve 123b is used for adjusting the water supplementing flow and pressure, and protecting the third water pump 121c.

In this embodiment, the recovery unit 120 further includes an eleventh valve 126, the eleventh valve 126 is disposed on one side of the first water tank 124, one side of the eleventh valve 126 close to the first water tank 124 is connected to the first water tank 124 and the third valve 127 through pipes, and one end of the eleventh valve 126 away from the first water tank 124 is in contact with the ground, and the eleventh valve 126 is used for draining water for cleaning the first water tank 124 on the ground.

In this embodiment, the recovery unit 120 further includes a twelfth valve 122b, the twelfth valve 122b is disposed at one side of the second water tank 124c, one side of the twelfth valve 122b close to the second water tank 124c is connected to the second water tank 124c and the fourth valve 122a through pipes, and one end of the twelfth valve 122b away from the second water tank 124c is in contact with the ground, and the twelfth valve 122b is used for draining the water for cleaning the second water tank 124c on the ground.

Optionally, the detecting assembly 110 includes a turbidity meter 114, the turbidity meter 114 is configured on a side of the first sensor 121 facing away from the first water pump 123, that is, on a side of the first sensor 121 facing away from the second valve 122, and the turbidity meter 114 is configured to detect whether the water quality of the water in the detecting assembly 110 is acceptable.

In this embodiment, a second pneumatic valve 117 is disposed between the first sensor 121 and the turbidity meter 114. The second pneumatic valve 117 is connected to the first sensor 121 and the turbidity meter 114, respectively, for example, by a pipe connection. The second pneumatic valve 117 is used to control whether water passing through the turbidity meter 114 reaches the first sensor 121.

Wherein, a third pneumatic valve 113 is arranged between the turbidity meter 114 and the external water pipe 101, and the third pneumatic valve 113 is used for controlling whether the wash tank water in the external water pipe 101 can enter the detection assembly 110.

The detection assembly 110 further includes a recovery tank 111, the recovery tank 111 being configured to recover water flowing into the detection assembly 110 that is not acceptable for water quality detection.

The recovery tank 111 is communicated with the turbidity meter 114 through a pipeline, a fourth pneumatic valve 115, a second one-way valve 116 and a fifth pneumatic valve 112 are sequentially arranged between the turbidity meter 114 and the recovery tank 111, and the turbidity meter 114, the fourth pneumatic valve 115, the second one-way valve 116, the fifth pneumatic valve 112 and the recovery tank 111 are all connected through pipelines.

Alternatively, the volume of the recovery tank 111 is 500T, for example.

In the present embodiment, the water tank set 130 includes a third water tank 131, a fourth water tank 135, a fifth water tank 137, and a sixth water tank 138.

One end of the third water tank 131 is provided with a sixth air-operated valve 132, and one side of the sixth air-operated valve 132 facing away from the third water tank 131 is respectively connected with the fourth water tank 135 and an external water supplementing pipe 133 in a pipeline connection manner, for example.

Specifically, a seventh air-operated valve 134 and an eighth air-operated valve 136 are sequentially disposed between the third water tank 131 and the fourth water tank 135, and the seventh air-operated valve 134 is configured to block water in the external water-supplementing pipe 133 from passing through the seventh air-operated valve 134 when water in the external water-supplementing pipe 133 is used to supplement water to the third water tank 131.

Wherein the seventh pneumatic valve 134 and the eighth pneumatic valve 136 are connected to the first pneumatic valve 125b, for example, by a pipe connection.

Optionally, a ninth air-operated valve 139 is disposed at an end of the sixth water tank 138 near the recovery assembly 120, and the ninth air-operated valve 139 is connected to the first air-operated valve 125b, that is, the water in the second water tank 124c may flow into the sixth water tank 138.

It should be noted that, the present embodiment is not limited to the number of the sixth water tanks 138, the specific number of the sixth water tanks 138 may be designed according to the actual production situation, and the present embodiment is not limited to the number of the ninth air-operated valves 139, and the specific number of the ninth air-operated valves 139 may be designed according to the actual production situation. Alternatively, the sixth water tank 138 in the present embodiment is, for example, four, and the number of the ninth air-operated valves 139 is, for example, two.

In addition, the fifth water tank 137 is connected to the connection pipe between the first sensor 121 and the second valve 122, that is, the wash tank water passing through the first sensor 121 may flow into the fifth water tank 137. Optionally, a fifth sensor 137a is provided in the fifth water tank 137, and the fifth sensor 137a is used to detect whether the water level in the fifth water tank 137 reaches the position of the fifth sensor 137 a.

In the production process, when water needs to be replenished to the third water tank 131, the fourth water tank 135 and the sixth water tank 138, and the third sensor 124b senses that the liquid level is enough, that is, when water exists in the second water tank 124c, the first pneumatic valve 125b is opened, the seventh pneumatic valve 134 is closed, and the water in the second water tank 124c directly supplements the water in the third water tank 131, the fourth water tank 135 and the sixth water tank 138, that is, supplements the water to the sterilizing machines in the third water tank 131, the fourth water tank 135 and the sixth water tank 138, and the water replenishing of the third water tank 131 is performed by communicating with the external water replenishing pipe 133.

When the second sensor 125 and the third sensor 124b detect that there is no water in the first water tank 124 and the second water tank 124c, respectively, or the turbidity meter 114 detects that the quality of the wash tank water entering the detection assembly 110 from the third air valve 113 is not acceptable, the second water pump 128 is not started, and the second air valve 117 is closed, and the fourth air valve 115 is opened, the wash tank water enters the detection assembly 110 from the third air valve 113, and sequentially passes through the fourth air valve 115, the second check valve 116, and the fifth air valve 112 to enter the recovery tank 111.

When the water levels in the sixth water tank 138 and the fourth water tank 135 are higher than 3% of the set level value, respectively, the third water pump 121c stops operating. When the water levels in the sixth water tank 138 and the fourth water tank 135 are respectively lower than 3% of the set level value, the third water pump 121c is kept on to ensure timely water replenishment to the sixth water tank 138 and the fourth water tank 135.

When the third sensor 124b senses that there is no water in the second water tank 124c, the third water pump 121c is stopped, the first air valve 125b is closed, the seventh air valve 134 is opened, water is replenished from the external water replenishing pipe 133 to the third water tank 131, the fourth water tank 135 and the sixth water tank 138, and the sterilizer cools down.

In this embodiment, the cleaning process of the recovery unit 120: the first pneumatic valve 125b, the seventh pneumatic valve 134, the eighth pneumatic valve 136, and the ninth pneumatic valve 139 are manually opened to inject the cleaning water into the first water tank 124 and the second water tank 124c, at least to ensure that the water in the second water tank 124c is circulated enough for the piping system, i.e., the water is added to the third sensor 124b of the second water tank 124 c.

Further, the third valve 127, the fourth valve 122a, the fifth valve 122c, the seventh valve 121b, the sixth valve 123a, the eighth valve 129, the first valve 123c and the tenth valve 123b are opened manually, the twelfth valve 122b, the ninth valve 124a, the eleventh valve 126 are closed manually, the second water and the third water pump 121c are opened manually, and at this time, the circulation of the pipeline is started.

When the cycle is completed, the second water pump 128 and the third water pump 121c are turned off, and then the twelfth, ninth and eleventh valves 122b, 124a and 126 are opened, and the water in the water tank is discharged. After the discharge is completed, the twelfth valve 122b, the first valve 123c, and the eleventh valve 126 are closed again.

In the description of the present specification, a description referring to terms "one embodiment," "some embodiments," "examples," "specific examples," or "some examples," etc., means 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 present application. In this specification, schematic representations of the above terms are not necessarily directed 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, the different embodiments or examples described in this specification and the features of the different embodiments or examples may be combined and combined by those skilled in the art without contradiction.

While embodiments of the present application have been shown and described above, it will be understood that the above embodiments are illustrative and not to be construed as limiting the application, and that variations, modifications, alternatives and variations may be made to the above embodiments by one of ordinary skill in the art within the scope of the application.

Claims (10)

1. A water conservation system, comprising:

a water tank group;

the recovery assembly is connected with the water tank group;

The water tank group is characterized by comprising a detection component, wherein one end of the detection component is connected with an external water pipe, one end of the detection component, which is far away from the external water pipe, is connected with a recovery component, the detection component is used for detecting whether the water quality in the external water pipe is qualified or not, and the recovery component is used for recovering the water in the external water pipe and carrying out water supplementing treatment on the water tank group.

2. The water conservation system of claim 1 wherein the recovery assembly comprises:

A first water tank in communication with the detection assembly;

the second water tank is communicated with the first water tank and is used for storing water flowing into the second water tank from the first water tank.

3. The water conservation system of claim 2 wherein the recovery assembly further comprises a second sensor disposed on a side of the first tank, the second sensor for detecting whether the first tank is full of water.

4. The water conservation system of claim 2 wherein the recovery assembly further comprises:

The first water pump is arranged between the first water tank and the detection assembly and is used for conveying water in the detection assembly into the first water tank;

The second water pump is arranged between the first water tank and the second water tank and is used for conveying water of the first water tank into the second water tank;

And the third water pump is arranged between the second water tank and the water tank group and is used for conveying water of the second water pump into the water tank group.

5. The water conservation system of claim 4 wherein the recovery assembly further comprises:

The third sensor is arranged at one end, close to the third water pump, of the second water tank and is used for detecting whether water exists in the second water tank or not;

The fourth sensor is arranged at one end, far away from the third water pump, of the second water tank and is used for detecting whether the second water tank is full of water or not.

6. The water conservation system of claim 4 wherein the recovery assembly further comprises a filter portion disposed at an end of the third water pump proximate the water tank set, the filter portion for filtering water delivered into the water tank set by the recovery assembly.

7. The water conservation system of claim 4 wherein the recovery assembly further comprises a first valve disposed at an end of the first tank remote from the second water pump, the end of the first valve remote from the first water tank in communication with the second water tank, wherein the first water tank, second water pump, second water tank and first valve form a circuit.

8. The water conservation system of claim 4 wherein the recovery assembly further comprises a first sensor disposed between the first water pump and the detection assembly, the first sensor for detecting whether water is present between the first water pump and the detection assembly.

9. The water conservation system of claim 8 wherein the detection assembly comprises a turbidity meter, the turbidity meter being positioned on a side of the first sensor facing away from the first water pump, the turbidity meter being configured to detect whether water quality in the detection assembly is acceptable.

10. The water conservation system of claim 1 wherein the detection assembly further comprises a recovery tank for recovering water that fails the water quality test flowing into the detection assembly.