CN214360769U - Water body purifying equipment - Google Patents

Abstract

The utility model provides a pair of water clarification plant relates to water treatment technical field, include: the equipment comprises an equipment main body, a plurality of supporting rods and a plurality of supporting rods, wherein at least three mounting grooves are formed in the equipment main body, and the mounting grooves are sequentially communicated; the ozone generating box, the gas-liquid mixing box and the reaction box are sequentially communicated and installed in a plurality of continuous installation grooves in a head-tail sequence, and are sequentially communicated and assembled through the plurality of installation grooves which are sequentially communicated; wherein, a UV photocatalysis device is detachably assembled in the reaction box; the flow regulating mechanism is at least arranged between two mounting grooves; the inlet pipe is arranged on the equipment main body and is communicated with the gas-liquid mixing box; and the discharge pipe is arranged on the equipment main body and is communicated with the reaction box.

Description

Water body purifying equipment

Technical Field

The utility model belongs to the technical field of the water treatment technique and specifically relates to a water clarification plant is related to.

Background

With the economic development, the problem of water pollution is more and more serious. The polluted water contains more and more trace harmful chemical substances such as toxic and harmful to human bodies and environmental hormones. At present, the treatment of sewage is often carried out by adopting water purification treatment equipment to realize the purification of the sewage. The existing water body purification equipment is communicated with all relevant treatment equipment in the treatment process through a plurality of pipelines or pipelines before being used, so that sewage can be sequentially treated correspondingly through the treatment equipment, and finally, the sewage is purified.

However, the water body purification equipment not only needs to consume a lot of time for communication operation before use, but also occupies a lot of field areas in a communication-finished state to be used, and because the connected pipelines or pipelines are all of a fixed flow size, once the use environment changes, when sewage flow in a corresponding stage needs to be adjusted, the sewage flow needs to be realized through a corresponding valve body or by replacing pipelines with different sizes, so that the operation is complex and the cost is high.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide a water clarification plant to it is loaded down with trivial details to solve among the prior art water clarification plant assembly, leads to the relatively poor technical problem of environment suitability in the use.

The utility model provides a pair of water clarification plant, include:

the device comprises a device main body, a plurality of supporting rods and a plurality of connecting rods, wherein at least three mounting grooves are formed in the device main body, and the mounting grooves are communicated in sequence;

the ozone generating box, the gas-liquid mixing box and the reaction box are sequentially communicated and installed in a plurality of continuous installation grooves in an end-to-end sequence, and are sequentially communicated and assembled through the installation grooves; wherein, a UV photocatalysis device is detachably assembled in the reaction box;

at least one flow regulating mechanism, wherein the flow regulating mechanism is at least arranged between two mounting grooves;

the inlet pipe is arranged on the equipment main body and is communicated with the gas-liquid mixing box;

a discharge pipe installed on the apparatus main body, and the discharge pipe communicates with the reaction tank.

Further, the method also comprises the following steps:

the booster box is internally provided with an additional pump;

the number of the mounting grooves is four, and the four mounting grooves are sequentially communicated;

the ozone generation box, the gas-liquid mixing box, the reaction box and the pressurization box are sequentially communicated and installed in four continuous installation grooves in an end-to-end sequence, and the ozone generation box, the gas-liquid mixing box, the reaction box and the pressurization box are sequentially communicated and assembled through the four installation grooves which are sequentially communicated;

the discharge pipe is communicated with the reaction box through the pressurization box.

Further, the method also comprises the following steps:

and the sewage tank is communicated with the inlet pipe.

Further, the method also comprises the following steps:

and the water pump is arranged between the sewage pool and the inlet pipe.

Furthermore, a flow regulating cavity is arranged between the adjacent mounting grooves, and water passing holes which are communicated with the adjacent mounting grooves and are symmetrically arranged with each other are respectively arranged on the cavity walls at the two sides of the flow regulating cavity; the flow regulating cavity is internally provided with a regulating partition plate in a linear sliding manner, and the regulating partition plate regulates the area for shielding the water through hole by linearly sliding in the flow regulating cavity;

the flow regulating cavity and the regulating partition plate form the flow regulating mechanism.

Furthermore, the quantity of the water holes on the two side cavity walls of the flow adjusting cavity is multiple, the water holes are linearly arranged along the linear sliding direction of the adjusting partition plate, and the adjusting partition plate is linearly slid in the flow adjusting cavity to adjust the area and the quantity of the water holes.

Furthermore, the opening areas of the water through holes are sequentially increased along the linear direction of the flow adjusting cavity in which the adjusting partition plate linearly slides out.

Furthermore, the number of the flow regulating mechanisms is one, and the flow regulating mechanisms are assembled between two adjacent mounting grooves for mounting the gas-liquid mixing box and the reaction box so as to control the flow between the gas-liquid mixing box and the reaction box.

Furthermore, the number of the flow regulating mechanisms is two, and the two flow regulating mechanisms are assembled between adjacent mounting grooves of the gas-liquid mixing box, the reaction box and the pressurizing box so as to control the flow between the gas-liquid mixing box and the reaction box and control the flow between the reaction box and the pressurizing box.

Further, the mounting groove is a square groove, and the ozone generating box, the gas-liquid mixing box, the reaction box and the pressurizing box are square boxes matched with the square groove in shape; wherein the ozone generating box, the gas-liquid mixing box, the reaction box and the pressurizing box are also provided with lifting handles.

In the above technical solution, the main body of the equipment is a main structure having a plurality of mounting grooves, wherein the mounting grooves are sequentially communicated with each other, and a certain mounting groove at the head end is communicated with the inlet pipe, and a certain mounting groove at the tail end is communicated with the outlet pipe, thereby forming a channel communicated from the inlet pipe to the outlet pipe. Sewage can flow through this passageway and carry out corresponding purification operation, and each relevant equipment that carries out sewage treatment can carry out corresponding purification operation to sewage in the mounting groove that corresponds the order through the form grafting assembly of assembling, carries out corresponding purification operation to sewage in different stages, and the mode of assembling makes the operation simpler and more convenient, and need not occupy a large amount of area. Meanwhile, the flow between the adjacent mounting grooves is adjusted through a flow adjusting mechanism, and the flow is controlled in different purification treatment stages.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings used in the embodiments or the technical solutions in the prior art will be briefly described below, and it is obvious that the drawings in the following description are some embodiments of the present invention, and for those skilled in the art, other drawings can be obtained according to these drawings without creative efforts.

Fig. 1 is a perspective view of a water body purification apparatus provided by an embodiment of the present invention;

FIG. 2 is a plan view of the water purification apparatus shown in FIG. 1;

FIG. 3 is a perspective view of the water purification apparatus shown in FIG. 1;

FIG. 4 is a plan exploded view of the water purification apparatus shown in FIG. 1;

fig. 5 is a schematic plan view of a flow rate adjustment mechanism according to an embodiment of the present invention, illustrating a schematic plan view of the flow rate adjustment mechanism 1;

fig. 6 is a schematic plan view of a flow rate adjustment mechanism according to an embodiment of the present invention, which is shown in fig. 2;

fig. 7 is a schematic plan view of a flow rate adjustment mechanism according to an embodiment of the present invention, shown in fig. 3;

fig. 8 is a schematic plan view of a flow rate adjustment mechanism according to an embodiment of the present invention, illustrating a schematic plan view of the flow rate adjustment mechanism shown in fig. 4;

fig. 9 is a schematic structural view of a water outlet hole provided in the present invention.

Reference numerals:

1. an apparatus main body; 2. an ozone generating box; 3. a gas-liquid mixing tank; 4. a reaction box; 5. a pressurizing box;

11. mounting grooves; 12. a flow rate adjusting mechanism; 13. an inlet pipe; 14. a discharge pipe;

121. a flow regulating cavity; 122. water passing holes; 123. adjusting the partition plate; 124. and (7) water outlet holes.

Detailed Description

The technical solution of the present invention will be described clearly and completely with reference to the accompanying drawings, and obviously, the described embodiments are some, but not all embodiments of the present invention. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative work belong to the protection scope of the present invention.

In the description of the present invention, it should be noted that the terms "center", "upper", "lower", "left", "right", "vertical", "horizontal", "inner", "outer", and the like indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, and are only for convenience of description and simplification of description, but do not indicate or imply that the device or element referred to must have a specific orientation, be constructed and operated in a specific orientation, and thus, should not be construed as limiting the present invention. Furthermore, the terms "first," "second," and "third" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance.

In the description of the present invention, it is to be noted that, unless otherwise explicitly specified or limited, the terms "mounted," "connected," and "connected" are to be construed broadly, and may be, for example, fixedly connected, detachably connected, or integrally connected; can be mechanically or electrically connected; they may be connected directly or indirectly through intervening media, or they may be interconnected between two elements. The specific meaning of the above terms in the present invention can be understood in specific cases to those skilled in the art.

As shown in fig. 1 to 9, the water purifying apparatus provided in this embodiment includes:

the device comprises a device main body 1, wherein at least three mounting grooves 11 are formed in the device main body 1, and the mounting grooves 11 are sequentially communicated;

the device comprises an ozone generation box 2, a gas-liquid mixing box 3 and a reaction box 4, wherein the ozone generation box 2, the gas-liquid mixing box 3 and the reaction box 4 are sequentially communicated and installed in a plurality of continuous installation grooves 11 in a head-tail sequence, and the ozone generation box 2, the gas-liquid mixing box 3 and the reaction box 4 are sequentially communicated and assembled through the plurality of installation grooves 11 which are sequentially communicated; wherein, a UV photocatalysis device is detachably assembled in the reaction box 4;

at least one flow regulating mechanism 12, wherein the flow regulating mechanism 12 is at least arranged between two installation grooves 11;

and the inlet pipe 13 is arranged on the equipment main body 1, and the inlet pipe 13 is communicated with the gas-liquid mixing box 3.

It should be noted that, prior water body purification equipment needs to communicate each relevant treatment equipment in the treatment process through a plurality of pipelines or pipelines before use, so that sewage can be correspondingly treated by each treatment equipment in sequence, and finally, the purification treatment of sewage is realized. However, the existing water body purification equipment not only needs to consume a lot of time for communication operation before use, but also occupies a lot of field areas when the communication is finished and the use state is to be used, and because the connected pipelines or pipelines are all of the size of constant flow, once the use environment is changed, when the sewage flow in the corresponding stage needs to be adjusted, the sewage flow needs to be realized through the corresponding valve body or the pipelines with different sizes, and the operation is complex and the cost is high.

In order to solve the technical problem, the water purifying equipment of the present application provides an equipment structure of a split mounting type concept, the equipment structure provides an equipment main body 1, the equipment main body 1 is a main structure provided with a plurality of installation grooves 11, wherein the installation grooves 11 are sequentially communicated, a certain installation groove 11 at the head end is communicated with an inlet pipe 13, a certain installation groove 11 at the tail end is communicated with a discharge pipe 14, and a channel communicated from the inlet pipe 13 to the discharge pipe 14 is further formed. Sewage can flow through this passageway and carry out corresponding purification operation, and each relevant equipment that carries out sewage treatment can carry out corresponding purification operation to sewage in different stages through the form grafting assembly of assembling in the mounting groove 11 that corresponds the order, and the mode of assembling makes the operation simpler and more convenient, and need not occupy a large amount of area. Meanwhile, the flow between the adjacent mounting grooves 11 is adjusted through a flow adjusting mechanism 12, and the flow is controlled according to different purification treatment stages.

As for the communication structure between the mounting grooves 11 and the specific adjustment manner of the flow adjusting mechanism 12, in one embodiment, a flow adjusting cavity 121 is disposed between adjacent mounting grooves 11, and water through holes 122, which are symmetrically disposed and communicated with the adjacent mounting grooves 11, are respectively disposed on the cavity walls on both sides of the flow adjusting cavity 121; an adjusting partition plate 123 is linearly and slidably assembled in the flow adjusting cavity 121, and the adjusting partition plate 123 adjusts the area for shielding the water through hole 122 by linearly sliding in the flow adjusting cavity 121; the flow rate adjustment chamber 121 and the adjustment diaphragm 123 constitute the flow rate adjustment mechanism 12.

Therefore, a flow regulating cavity 121 is formed between the adjacent mounting grooves 11, water holes 122 are formed in the cavity walls on the two sides of the flow regulating cavity 121 respectively, the water holes 122 are communicated with the adjacent mounting grooves 11, and therefore the adjacent mounting grooves 11 can be communicated through the water holes 122. At this time, the adjusting partition plate 123 is linearly slidably assembled in the flow adjusting cavity 121, when the adjusting partition plate 123 slides along the flow adjusting cavity 121, the adjusting partition plate 123 adjusts the area shielding the water passing hole 122 through the linear sliding motion, when the area shielding the water passing hole 122 is larger, the area of the exposed water passing hole 122 is smaller, and at this time, the flow rate of the liquid passing through between the adjacent mounting grooves 11 is smaller, and conversely, when the area shielding the water passing hole 122 is smaller, the area of the exposed water passing hole 122 is larger, and at this time, the flow rate of the liquid passing through between the adjacent mounting grooves 11 is larger. Thus, the flow control between the adjacent mounting grooves 11 can be realized by adjusting the shielding of the partition 123 to the area of the water through hole 122.

The regulating partition 123 may be provided with a sealing layer, for example, the sealing layer may be made of a material having a sealing function, such as a rubber layer, so that even if the regulating partition 123 slides in the flow rate regulating cavity 121, the water passing hole 122 can be effectively shielded to prevent the liquid from leaking. In this process, the material standard of the sealing layer can be adjusted and selected, as long as the adjusting partition 123 can smoothly slide and form a good sealing effect, which is not described herein again.

Furthermore, the flow rate adjusting cavity 121 has a plurality of water holes 122 on the two side walls, the water holes 122 are linearly arranged along the direction in which the adjusting partition 123 slides linearly, and the adjusting partition 123 slides linearly in the flow rate adjusting cavity 121 to adjust the area of the water holes 122 and the number of the water holes 122.

Therefore, when the number of the water holes 122 is set to be plural, the adjusting partition plate 123 is in the linear sliding process in the flow adjusting cavity 121, not only the area of the single water hole 122 that is shielded can be adjusted, but also the number of the plural water holes 122 that are shielded can be adjusted, thus, not only the flow in a small range can be adjusted by shielding the area of the water hole 122, but also the flow can be adjusted in a large range by adjusting the number of the water holes 122 that are shielded, and this way can make the flow adjustment more flexible.

Wherein, along the linear direction that the adjusting partition 123 slides out of the flow rate adjusting cavity 121 linearly, the opening areas of the plurality of water passing holes 122 increase in sequence. Therefore, when the adjusting partition 123 slides out linearly, the total flow rate can be increased in an accelerated manner, and the total flow rate can be adjusted rapidly.

In one embodiment, the apparatus main body 1 is further provided with an ozone generating box 2, a gas-liquid mixing box 3 and a reaction box 4 in a matching way, the ozone generating box 2, the gas-liquid mixing box 3 and the reaction box 4 can be respectively inserted and assembled in different mounting grooves 11, and the inlet pipe 13 is communicated with the gas-liquid mixing box 3. It should be noted that, ozone generation box 2, the quantity of the water holes 122 of crossing that set up in the mounting groove 11 of rather than grafting assembly is all seted up to the both sides of gas-liquid mixing box 3 and reaction box 4, apopore 124 that size and size are unanimous, so that ozone generation box 2, after gas-liquid mixing box 3 and reaction box 4 installed in the corresponding mounting groove 11, can make water holes 122 and apopore 124 form the intercommunication, make ozone generation box 2, gas-liquid mixing box 3 and reaction box 4 assembly back that finishes, if sewage gets into the back from admission pipe 13, gas-liquid mixing box 3 and reaction box 4 can flow through in proper order, ozone generation box 2 also communicates with gas-liquid mixing box 3 simultaneously.

Wherein, when sewage flows to gas-liquid mixing case 3 through admission pipe 13, because ozone takes place case 2 and also communicates with gas-liquid mixing case 3, so ozone takes place case 2 and also can be with leading-in this gas-liquid mixing case 3 of ozone, at this moment, in gas-liquid mixing case 3, sewage can form the intensive mixing with ozone, can enter reaction box 4 after mixing, because install UV photocatalysis apparatus in the reaction box 4, so can implement the processing of eliminating bacterium and virus microorganism through this UV photocatalysis apparatus's ultraviolet irradiation, reintroduction to the contaminated water after the processing, realize the purification of water through above circulation.

Further, the device also comprises a pressurizing box 5, wherein an additional pump is arranged in the pressurizing box 5; the number of the mounting grooves 11 is four, and the four mounting grooves 11 are sequentially communicated; the ozone generation box 2, the gas-liquid mixing box 3, the reaction box 4 and the pressurization box 5 are sequentially communicated and installed in four continuous mounting grooves 11 in an end-to-end sequence, and the ozone generation box 2, the gas-liquid mixing box 3, the reaction box 4 and the pressurization box 5 are sequentially communicated and assembled through the four sequentially communicated mounting grooves 11.

In this embodiment, when sewage flows to the gas-liquid mixing tank 3 through the inlet pipe 13, the ozone generating tank 2 is also communicated with the gas-liquid mixing tank 3, so the ozone generating tank 2 also guides ozone into the gas-liquid mixing tank 3, at this time, in the gas-liquid mixing tank 3, sewage can be sufficiently mixed with ozone, and can enter the reaction tank 4 after being mixed, because the UV photocatalysis device is installed in the reaction tank 4, treatment for killing bacteria and virus microorganisms can be implemented through ultraviolet irradiation of the UV photocatalysis device, purified sewage can be pressurized and guided into a polluted water body through the pressurization tank 5 after treatment, and purification of the water body is realized through the above circulation.

The mode combines the photocatalysis technology, the ozone advanced oxidation technology and the gas-liquid mixing technology, can effectively oxidize and decompose organic matters, microorganisms, germs, viruses and the like in the water body, does not add any chemical preparation, and does not generate any harmful by-product. The organic matters which are difficult to degrade in the sewage are subjected to reduction reaction, and the high molecular and the macromolecular organic matters are reacted to form small molecular compounds until carbon dioxide is generated, so that pollutants such as COD (chemical oxygen demand), BOD (biochemical oxygen demand) 5 and the like in the sewage can be reduced, and the biochemical degradability of the sewage is improved.

Further, the sewage treatment device also comprises a sewage pool which is communicated with the inlet pipe 13, so that sewage can be firstly introduced into the sewage pool and then introduced into the gas-liquid mixing box 3 through the communication between the sewage pool and the inlet pipe 13. And, in this process, a water pump is also included, which is installed between the wastewater tank and the inlet pipe 13, and at this time, the water pump can assist the wastewater to be guided from the wastewater tank to the gas-liquid mixing tank 3 through the inlet pipe 13.

Further, the number of the flow rate adjusting mechanism 12 is one, and the flow rate adjusting mechanism 12 is assembled between two adjacent mounting grooves 11 in which the gas-liquid mixing tank 3 and the reaction tank 4 are mounted, so as to control the flow rate between the gas-liquid mixing tank 3 and the reaction tank 4. Therefore, the flow rate between the gas-liquid mixing tank 3 and the reaction tank 4 can be adjusted by the flow rate adjusting mechanism 12, and the flow rate between the gas-liquid mixing tank 3 and the reaction tank 4 can be adjusted according to the reaction degree between the sewage and the ozone in the process of sewage purification treatment so as to be adapted to the actual sewage treatment, so that the sewage and the ozone are fully mixed and then led into the reaction tank 4.

Further, the number of the flow rate adjusting mechanisms 12 is two, and two of the flow rate adjusting mechanisms 12 are assembled between the adjacent mounting grooves 11 in which the gas-liquid mixing tank 3, the reaction tank 4 and the pressurizing tank 5 are mounted, so as to control the flow rate between the gas-liquid mixing tank 3 and the reaction tank 4, and control the flow rate between the reaction tank 4 and the pressurizing tank 5. Therefore, the flow rate between the gas-liquid mixing tank 3 and the reaction tank 4 can be adjusted by the flow rate adjusting mechanism 12, and the flow rate between the gas-liquid mixing tank 3 and the reaction tank 4 can be adjusted according to the reaction degree between the sewage and the ozone in the process of sewage purification treatment so as to be adapted to the actual sewage treatment, so that the sewage and the ozone are fully mixed and then led into the reaction tank 4. And the flow between the reaction box 4 and the pressurizing box 5 can be adjusted through the flow adjusting mechanism 12, and the reaction box 4 is fully reacted and then is guided into the polluted water body through the pressurizing box 5, so that the water body is circularly purified.

Preferably, the mounting groove 11 is a square groove, and the ozone generating box 2, the gas-liquid mixing box 3, the reaction box 4 and the pressurizing box 5 are square boxes matched with the square groove in shape; wherein, the ozone generating box 2, the gas-liquid mixing box 3, the reaction box 4 and the pressurizing box 5 are also provided with lifting handles. At this time, the ozone generation tank 2, the gas-liquid mixing tank 3, the reaction tank 4, the pressurizing tank 5 and the mounting groove 11 can be conveniently assembled by plugging with a handle.

Finally, it should be noted that: the above embodiments are only used to illustrate the technical solution of the present invention, and not to limit the same; although the present invention has been described in detail with reference to the foregoing embodiments, it should be understood by those skilled in the art that: the technical solutions described in the foregoing embodiments may still be modified, or some or all of the technical features may be equivalently replaced; such modifications and substitutions do not depart from the spirit and scope of the present invention.

Claims (10)

1. A water purification apparatus, comprising:

the device comprises a device main body, a plurality of supporting rods and a plurality of connecting rods, wherein at least three mounting grooves are formed in the device main body, and the mounting grooves are communicated in sequence;

the ozone generating box, the gas-liquid mixing box and the reaction box are sequentially communicated and installed in a plurality of continuous installation grooves in an end-to-end sequence, and are sequentially communicated and assembled through the installation grooves; wherein, a UV photocatalysis device is detachably assembled in the reaction box;

at least one flow regulating mechanism, wherein the flow regulating mechanism is at least arranged between two mounting grooves;

the inlet pipe is arranged on the equipment main body and is communicated with the gas-liquid mixing box;

a discharge pipe installed on the apparatus main body, and the discharge pipe communicates with the reaction tank.

2. The water purifying apparatus of claim 1, further comprising:

the booster box is internally provided with an additional pump;

the number of the mounting grooves is four, and the four mounting grooves are sequentially communicated;

the ozone generation box, the gas-liquid mixing box, the reaction box and the pressurization box are sequentially communicated and installed in four continuous installation grooves in an end-to-end sequence, and the ozone generation box, the gas-liquid mixing box, the reaction box and the pressurization box are sequentially communicated and assembled through the four installation grooves which are sequentially communicated;

the discharge pipe is communicated with the reaction box through the pressurization box.

3. The water purifying apparatus of claim 1, further comprising:

and the sewage tank is communicated with the inlet pipe.

4. The water purifying apparatus of claim 3, further comprising:

and the water pump is arranged between the sewage pool and the inlet pipe.

5. The water purifying equipment according to any one of claims 1 to 4, wherein a flow regulating cavity is formed between adjacent mounting grooves, and water passing holes which are communicated with the adjacent mounting grooves and are symmetrically arranged with each other are respectively formed on the cavity walls at two sides of the flow regulating cavity; the flow regulating cavity is internally provided with a regulating partition plate in a linear sliding manner, and the regulating partition plate regulates the area for shielding the water through hole by linearly sliding in the flow regulating cavity;

the flow regulating cavity and the regulating partition plate form the flow regulating mechanism.

6. The water purifying device of claim 5, wherein the flow regulating cavity has a plurality of water holes on two side walls, the water holes are linearly arranged along the direction of linear sliding of the regulating partition plate, and the regulating partition plate is capable of regulating the area for shielding different water holes and the number of the water holes by linearly sliding in the flow regulating cavity.

7. The water purifying apparatus of claim 6, wherein the opening areas of the water through holes are sequentially increased along the linear direction in which the adjusting partition plate slides out of the flow adjusting chamber linearly.

8. The water purifying apparatus of claim 5, wherein the flow rate adjusting mechanism is one in number, and is fitted between two adjacent mounting grooves in which the gas-liquid mixing tank and the reaction tank are mounted to control the flow rate between the gas-liquid mixing tank and the reaction tank.

9. The water purifying apparatus of claim 2, wherein the number of the flow regulating mechanisms is two, and two of the flow regulating mechanisms are fitted between adjacent mounting grooves in which the gas-liquid mixing tank, the reaction tank and the pressurizing tank are mounted to control the flow rate between the gas-liquid mixing tank and the reaction tank and to control the flow rate between the reaction tank and the pressurizing tank.

10. The water purifying apparatus according to claim 2, wherein the installation groove is a square groove, and the ozone generating tank, the gas-liquid mixing tank, the reaction tank and the pressurizing tank are square tanks having shapes matched with the square groove; wherein the ozone generating box, the gas-liquid mixing box, the reaction box and the pressurizing box are also provided with lifting handles.

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