CN220223751U - Water purification supply and storage system based on ozone sterilization - Google Patents

Abstract

The utility model relates to a water purification supply and storage system based on ozone sterilization, which belongs to the technical field of water treatment equipment and comprises a first water sump, a second water sump, a third water sump and an ozone quantitative supply device, wherein the first water sump, the second water sump and the third water sump are mutually independent, the ozone quantitative supply device is communicated with the first water sump through an ozone conveying pipeline, the first water sump is communicated with the second water sump and a water inlet pipeline, the third water sump is communicated with the second water sump and a water outlet pipeline, a high-level sensor and a low-level sensor are arranged in the first water sump, and a water suction pump I is arranged on a pipeline communicated between the second water sump and the first water sump and is in signal communication with the high-level sensor, the low-level sensor and the ozone quantitative supply device. Through many storehouse formula water tank structure, ozone ration injection mode, make sterilization process safe and abundant, thoroughly solved in the current sterilization technology ozone put in the precision low and probably brought the problem of health hidden danger for drinking water crowd.

Description

Water purification supply and storage system based on ozone sterilization

Technical Field

The utility model relates to the technical field of water treatment equipment, in particular to a water purification supply and storage system based on ozone sterilization.

Background

Ozone sterilization technology is one of the most thorough sterilization technologies currently acknowledged, and is widely applied to drinking water and food industries. However, in the application of water purification and sterilization, the precise control of the ozone amount has not been widely focused, because ozone is a strong oxidizing substance, and excessive administration causes direct or potential harm to human body, but too little administration causes incomplete sterilization. Accurate control of the amount of ozone is critical in the sterilization process. In the process of purifying drinking water, because the real-time water consumption of a user has uncertainty, serious unbalance exists between the ozone input amount and the water to be sterilized, and the problem that the ozone input amount is negligibly small inevitably exists.

Disclosure of Invention

In view of the above, the present utility model aims to provide a water purifying supply and storage system based on ozone sterilization, which adopts a multi-bin water tank structure and a quantitative ozone injection mode to solve the problem that the prior art cannot accurately control the ozone amount and has damage or insufficient sterilization.

The aim of the utility model is achieved by the following technical scheme:

the utility model provides a water purification supply and storage system based on ozone sterilization, includes first sump, second sump, third sump and ozone quantitative supply device, and first sump, second sump and third sump mutually independent set up, ozone quantitative supply device passes through ozone pipeline and first sump intercommunication, just first sump and second sump and water inlet line intercommunication, third sump and second sump and water outlet line intercommunication, be provided with high sensor and low sensor in the first sump, be provided with suction pump I on the pipeline of intercommunication between second sump and the first sump, suction pump I and high sensor, low sensor and ozone generating device signal communication.

Further, be provided with suction pump II on the pipeline of second sump and third sump intercommunication, also be provided with high sensor and low sensor in second sump and the third sump, high sensor and the suction pump I signal communication of second sump, also be provided with high sensor and low sensor in second sump's the low sensor and the third sump and all with suction pump II signal communication.

Further, the starting condition of the water pump I is that the liquid level of the first water bin is higher than the low-level sensor and 30 minutes after the ozone generating device is stopped, and the closing condition of the water pump I is that the liquid level of the first water bin is lower than the low-level sensor or the liquid level of the second water bin is higher than the high-level sensor.

Further, the starting condition of the water pump II is that the liquid level of the second water bin is higher than the low-level sensor and the liquid level of the third water bin is reduced to the low-level sensor, and the closing condition of the water pump II is that the liquid level of the second water bin is lower than the low-level sensor or the liquid level of the third water bin is higher than the high-level sensor.

Further, the first water sump, the second water sump and the third water sump are all provided with respirators.

Further, an electromagnetic control valve is arranged on the water inlet pipeline and is in signal communication with a high-level sensor and a low-level sensor in the first water bin.

Further, the electromagnetic valve is opened under the condition that the liquid level of the first water sump reaches the low level sensor, and is closed under the condition that the liquid level of the first water sump reaches the high level sensor.

The utility model has the beneficial effects that:

the quantitative ozone is supplied by the ozone quantitative supply device, and the volume of the liquid is ensured to be certain by controlling the high-low liquid level device, so that the quantitative ozone is added into the quantitative liquid, the ozone addition proportion is ensured, the accurate control of the ozone is realized, the sterilization and disinfection effects are realized, and the harm to the health of drinking water caused by excessive ozone input is effectively prevented; meanwhile, the utility model adopts a multi-bin structure of the first, the second and the third water bins, so that on one hand, the continuity of water supply is ensured, and on the other hand, the accuracy of ozone feeding amount and the effectiveness of sterilization time are further ensured.

Drawings

Fig. 1 is a schematic structural view of the present utility model.

Reference numerals illustrate:

1-a first water bin; 2-a second water bin; 3-a third water bin; 4-ozone quantitative supply device; 5-an ozone delivery conduit; 6-high level sensor; 7-a low level sensor; 8-a water suction pump I; 9-a water suction pump II; 10-a water inlet pipeline; 11-a water outlet pipeline; 12-an electromagnetic control valve; 13-respirator.

Detailed Description

For the purpose of making the objects, technical solutions and advantages of the embodiments of the present utility model more apparent, the technical solutions of the embodiments of the present utility model will be clearly and completely described below with reference to the accompanying drawings in the embodiments of the present utility model, and it is apparent that the described embodiments are some embodiments of the present utility model, but not all embodiments of the present utility model. The components of the embodiments of the present utility model generally described and illustrated in the figures herein may be arranged and designed in a wide variety of different configurations.

Thus, the following detailed description of the embodiments of the utility model, as presented in the figures, is not intended to limit the scope of the utility model, as claimed, but is merely representative of selected embodiments of the utility model. All other embodiments, which can be made by those skilled in the art based on the embodiments of the utility model without making any inventive effort, are intended to be within the scope of the utility model.

It should be noted that: like reference numerals and letters denote like items in the following figures, and thus once an item is defined in one figure, no further definition or explanation thereof is necessary in the following figures.

In the foregoing description of the utility model, it should be noted that the azimuth or positional relationship indicated by the terms "one side", "the other side", etc. are based on the azimuth or positional relationship shown in the drawings, or the azimuth or positional relationship in which the inventive product is conventionally put in use, are merely for convenience of describing the utility model and simplifying the description, and are not indicative or implying that the apparatus or element to be referred to must have a specific azimuth, be configured and operated in a specific azimuth, and therefore should not be construed as limiting the utility model. Furthermore, the terms "first," "second," and the like, are used merely to distinguish between descriptions and should not be construed as indicating or implying relative importance.

Furthermore, the terms "identical" and the like do not denote that the components are identical, but rather that there may be minor differences. The term "perpendicular" merely means that the positional relationship between the components is more perpendicular than "parallel" and does not mean that the structure must be perfectly perpendicular, but may be slightly tilted.

As shown in fig. 1, the ozone sterilization-based water purification supply and storage system in this embodiment includes a first water tank 1, a second water tank 2, a third water tank 3 and an ozone quantitative supply device 4, where the first water tank, the second water tank and the third water tank are set independently, the ozone quantitative supply device is communicated with the first water tank through an ozone conveying pipeline 5, the first water tank is communicated with the second water tank and a water inlet pipeline 10, the third water tank is communicated with the second water tank and a water outlet pipeline 11, a high-level sensor 6 and a low-level sensor 7 are disposed in the first water tank, a water pump I8 is disposed on a pipeline communicated between the second water tank and the first water tank, and the water pump I is communicated with the high-level sensor, the low-level sensor and the ozone generating device through signals, so that the water pump I obtains liquid level information of the high-level sensor and the low-level sensor or working time information of the ozone generating device, thereby performing start-stop operation.

In this embodiment, be provided with suction pump II 9 on the pipeline of second sump and third sump intercommunication, also be provided with high sensor and low sensor in second sump and the third sump, high sensor and the suction pump I signal intercommunication of second sump, also be provided with high sensor and low sensor in second sump and the third sump and all with suction pump II signal intercommunication. And in the same way, the water pump II obtains the liquid level information of the high-level sensor and the low-level sensor, so as to perform start-stop operation. The specific start-stop conditions are as follows:

the starting condition of the water pump I is that the liquid level of the first water bin reachesHigh-order sensorAnd the ozone generating device stops ozone feeding for 30 minutes. The water pump I is shut down if the liquid level in the first sump must be stopped when it is below the low level sensor and if the liquid level in the second sump is above the high level sensor.

The starting condition of the water pump II is that the liquid level of the second water bin is higher than the low-level sensor and the liquid level of the third water bin is reduced to the low-level sensor, and the closing condition of the water pump II is that the water pump II is stopped when the liquid level of the second water bin is lower than the low-level sensor and the water pump II is stopped when the liquid level of the third water bin is higher than the high-level sensor.

The operation flow of this embodiment is as follows:

when the liquid level of the first water bin reaches the high level sensor, the electromagnetic valve is closed, the ozone quantitative supply device is started and sends ozone into the first water bin according to the preset feeding amount, after the ozone quantitative supply device is stopped for 30 minutes, the sterilization process of the first water bin is completed, the water suction pump I is started, water in the first water bin is pumped into the second water bin, when the liquid level of the second water bin reaches the high level sensor, the water suction pump I is stopped, the electromagnetic valve is started at the moment, the first water bin starts to be injected with water again, and the previous process is circularly executed. At this time, the water pump II is started to pump water in the second water bin into the third water bin, when the liquid level of the third water bin reaches the high-level sensing, the water pump II is stopped, and after the sterilization process of the first water bin is finished, the water pump I is started again to pump water in the first water bin into the second water bin to be used for the third water bin.

When the water level of the water tank is lowered, external air needs to enter the water tank, and when the water level of the water tank is raised, air in the water tank needs to be discharged out of the water tank. In order to realize exchange and sanitation with the external air, in the embodiment, the respirators 13 are arranged in the first water sump, the second water sump and the third water sump, and the respirators also play a role in filtering air while keeping the connection with the external air.

In this embodiment, an electromagnetic control valve 12 is disposed on the water inlet pipe, and the electromagnetic control valve is in signal communication with the high-level sensor and the low-level sensor in the first water sump.

Further, the solenoid valve is opened in a condition that the liquid level of the first sump reaches the low level sensor, and is closed in a condition that the liquid level of the first sump reaches the high level sensor.

The embodiment ensures that the sterilization process is safe and full by adopting a multi-bin water tank structure and an ozone quantitative injection mode. Thoroughly solves the problems of low ozone delivery accuracy and potential hazards possibly brought to health of drinking water people in the past sterilization process.

The ozone dosing device and the respirator of this embodiment are mature devices and the structure or principle thereof is not further described. The embodiment is not limited to the specification and model, and the purchasing is carried out according to actual needs.

The signal communication in this embodiment mainly means that each component has signal transmission capability, so as to perform information transmission and identification, and the signal communication is usually a wireless communication or a wired communication.

Finally, it is noted that the above embodiments are only for illustrating the technical solution of the present utility model and not for limiting the same, and although the present utility model has been described in detail with reference to the preferred embodiments, it should be understood by those skilled in the art that modifications and equivalents may be made thereto without departing from the spirit and scope of the technical solution of the present utility model, which is intended to be covered by the scope of the claims of the present utility model.

Claims (7)

1. A clean water supply and storage system based on ozone sterilization, characterized in that: including first sump, second sump, third sump and ozone ration feeding mechanism, first sump, second sump and third sump mutually independent set up, ozone ration feeding mechanism passes through ozone pipeline and first sump intercommunication, just first sump and second sump and water inlet line intercommunication, third sump and second sump and outlet line intercommunication, be provided with high-order sensor and low-order sensor in the first sump, be provided with suction pump I on the pipeline of intercommunication between second sump and the first sump, suction pump I and high-order sensor, low-order sensor and ozone ration feeding mechanism signal communication.

2. An ozone sterilization-based clean water supply and storage system as set forth in claim 1, wherein: the water pump II is arranged on a pipeline for communicating the second water bin and the third water bin, a high-level sensor and a low-level sensor are also arranged in the second water bin and the third water bin, the high-level sensor of the second water bin is in signal communication with the water pump I, and the high-level sensor and the low-level sensor are also arranged in the low-level sensor of the second water bin and the third water bin and are in signal communication with the water pump II.

3. An ozone sterilization-based clean water supply and storage system as set forth in claim 2, wherein: the starting condition of the water pump I is that the liquid level of the first water bin is higher than the low-level sensor and 30 minutes after the ozone generating device is stopped, and the closing condition of the water pump I is that the liquid level of the first water bin is lower than the low-level sensor or the liquid level of the second water bin is higher than the high-level sensor.

4. An ozone sterilization-based clean water supply and storage system as set forth in claim 2, wherein: the starting condition of the water pump II is that the liquid level of the second water bin is higher than the low-level sensor and the liquid level of the third water bin is lower than the low-level sensor, and the closing condition of the water pump II is that the liquid level of the second water bin is lower than the low-level sensor or the liquid level of the third water bin is higher than the high-level sensor.

5. An ozone sterilization-based clean water supply and storage system according to any one of claims 1-4, wherein: the first water bin, the second water bin and the third water bin are all provided with respirators.

6. An ozone sterilization-based clean water supply and storage system according to any one of claims 1-4, wherein: the water inlet pipeline is provided with an electromagnetic control valve, and the electromagnetic control valve is in signal communication with a high-level sensor and a low-level sensor in the first water sump.

7. The ozone sterilization-based clean water supply and storage system of claim 6, wherein: the electromagnetic control valve is opened under the condition that the liquid level of the first water sump reaches the low-level sensor, and is closed under the condition that the liquid level of the first water sump reaches the high-level sensor.