CN219860581U

CN219860581U - Water-cooled ozone generator

Info

Publication number: CN219860581U
Application number: CN202321153471.7U
Authority: CN
Inventors: 陈龙龙
Original assignee: Shanghai Do & Got Ind Co ltd
Current assignee: Shanghai Do & Got Ind Co ltd
Priority date: 2023-05-15
Filing date: 2023-05-15
Publication date: 2023-10-20
Anticipated expiration: 2033-05-15

Abstract

The utility model discloses a water-cooled ozone generator, which comprises a box body, wherein a control module is fixedly arranged on the side surface of the box body, an ozone generator body is fixedly arranged in the box body, and a water cooling mechanism and a cooling water cooling mechanism are arranged on the box body; the water cooling mechanism comprises two water tanks, a water pump, a water inlet electromagnetic valve, a water inlet pipe, a main water pipe, a cooling pipe and a water return pipe, wherein the two water tanks are fixedly arranged on the side face of the box body.

Description

Water-cooled ozone generator

Technical Field

The utility model relates to the technical field of ozone generators, in particular to a water-cooled ozone generator.

Background

The ozone generator is a device for preparing ozone gas (O3). Ozone is easy to decompose and can not be stored, and the ozone is required to be prepared and stored in the field (can be stored for a short time under special conditions), so that an ozone generator is required in any place where ozone can be used. Ozone generator is widely used in the fields of drinking water, sewage, industrial oxidation, food processing and fresh keeping, medical synthesis, space sterilization and the like, and the water-cooled ozone generator is an ozone generator which cools a discharge tube in the ozone generator through circulating water, but when the conventional water-cooled ozone generator is used for a long time, a large amount of heat can be absorbed in cooling water of a water cooling system, the heat exchange efficiency of a heat exchanger in the water cooling system is limited, and when the water cooling system works for a long time, the heat of the cooling water in the water cooling system cannot be dissipated to the outside, so that the temperature of the cooling water is increased, the cooling effect of the ozone generator is reduced due to the increased cooling water, and the normal operation of the ozone generator is influenced.

Disclosure of Invention

In view of the problems existing in the prior art, the utility model discloses a water-cooled ozone generator, which adopts the technical scheme that the water-cooled ozone generator comprises a box body, wherein a control module is fixedly arranged on the side surface of the box body, an ozone generator body is fixedly arranged in the box body, and a water cooling mechanism and a cooling water cooling mechanism are arranged on the box body;

the water cooling mechanism comprises water tanks, a water pump, a water inlet electromagnetic valve, a water inlet pipe, a main water pipe, a cooling pipe and a water return pipe, wherein the two water tanks are arranged, the two water tanks are fixedly arranged on the side surfaces of the box body, water outlets of the side surfaces of the two water tanks are respectively connected with one ends of the two water inlet pipes, the other ends of the two water inlet pipes are connected with water inlets of the side surfaces of the main water pipe, the water pump and the water inlet electromagnetic valve are respectively arranged on the two water inlet pipes, the two water pumps are respectively fixedly arranged on the side surfaces of the two water tanks, the middle part of the cooling pipe is spiral, the side surface of the middle part of the cooling pipe is fixedly connected with the side surface of the ozone generator body, one end of the cooling pipe is connected with one end of the main water pipe, the other end of the cooling pipe is connected with one end of the lower side of the Y-shaped water return pipe, and the two ends of the upper side of the water return pipe are respectively connected with the water inlets of the side surfaces of the two water tanks;

the cooling water cooling mechanism comprises a cooling electromagnetic valve, a cooling water inlet pipe, heat exchangers and a cooling water outlet pipe, wherein the two heat exchangers are arranged and fixedly installed on the side surfaces of the two water tanks respectively, water inlets on the two heat exchangers are connected with one ends of the two cooling water inlet pipes respectively, the other ends of the cooling water inlet pipes are connected with water outlets on the side surfaces of the two water inlet pipes respectively, cooling water electromagnetic valves are installed on the cooling water inlet pipes respectively, water outlets on the two heat exchangers are connected with one ends of the two cooling water outlet pipes respectively, the other ends of the cooling water outlet pipes are connected with water inlets on the side surfaces of the two water tanks respectively, and the water pump, the water inlet electromagnetic valve and the cooling water electromagnetic valves are electrically connected with the control module.

As a preferable technical scheme of the utility model, the side surfaces of the two water tanks are fixedly provided with temperature sensors, one ends of the two temperature sensors penetrate through holes on the side surfaces of the two water tanks and extend into the two water tanks, and the temperature sensors are electrically connected with the control module.

As a preferable technical scheme of the utility model, the side surfaces of the two water tanks are fixedly provided with the supporting frames, the two supporting frames are respectively positioned on the upper sides of the two heat exchangers, the through grooves on the two supporting frames are fixedly provided with the radiating fans, and the radiating fans are electrically connected with the control module.

As a preferable technical scheme of the utility model, a baffle is fixedly arranged on the side surface of the box body, and the baffle is positioned between the two heat exchangers.

As a preferable technical scheme of the utility model, universal wheels are fixedly arranged at four corners of the bottom of the box body.

The utility model has the beneficial effects that: according to the utility model, the two water pumps can convey the cooling water in the two water tanks to the cooling pipe alternately along with the duration of the ozone generator body through the water inlet pipe and the main water pipe, so that the ozone generator body is cooled and radiated, the cooling water in the two water tanks can alternately cool and radiate the ozone generator, the cooling water in the water tanks for absorbing a large amount of heat can have enough time to radiate heat, the cooling water conveyed to the cooling pipe can always keep lower temperature, the temperature of the ozone generator can be effectively reduced when the ozone generator works for a long time, the phenomenon that the normal working of the ozone generator is influenced due to the fact that the cooling water temperature is too high is avoided, the cooling water with higher temperature can be conveyed to the heat exchanger through the cooling water inlet pipe, the heat in the cooling water is radiated through the heat exchanger, the temperature of the cooling water in the water tank is reduced, the temperature of the cooling water in the water tank can be monitored through the temperature sensor, the cooling water in the other water tank is automatically switched to cool the ozone generator when the temperature reaches a preset value, the air in the heat exchanger can be circulated through the heat radiating fan, the effect of the heat exchanger can be effectively improved, the heat exchanger can be prevented from being blown out of the heat exchanger through the baffle plate, the heat exchanger on the upper side can be prevented from being moved to the heat exchanger along with the heat radiating fan, and the heat can be conveniently transferred to the lower side of the heat exchanger through the heat exchanger.

Drawings

FIG. 1 is a schematic diagram of the front structure of the present utility model;

FIG. 2 is a schematic view of the back structure of the present utility model;

FIG. 3 is a schematic diagram of the internal structure of the present utility model.

In the figure: the device comprises a box body 1, an ozone generator body 2, a control module 3, a water cooling mechanism 4, a water tank 41, a water pump 42, a water inlet electromagnetic valve 43, a water inlet pipe 44, a main water pipe 45, a cooling pipe 46, a water return pipe 47, a cooling water cooling mechanism 5, a cooling electromagnetic valve 51, a cooling water inlet pipe 52, a heat exchanger 53, a cooling water outlet pipe 54, a temperature sensor 6, a supporting frame 7, a cooling fan 8, a baffle 9 and a universal wheel 10.

Detailed Description

Example 1

As shown in fig. 1 to 3, the utility model discloses a water-cooled ozone generator, which adopts the technical scheme that the water-cooled ozone generator comprises a box body 1, wherein a control module 3 is fixedly arranged on the side surface of the box body 1, an ozone generator body 2 is fixedly arranged in the box body 1, a water cooling mechanism 4 and a cooling water cooling mechanism 5 are arranged on the box body 1, universal wheels 10 are fixedly arranged at four corners of the bottom of the box body 1, and the box body 1 can be conveniently moved through the universal wheels 10, so that the flexibility of the ozone generator is improved;

the water cooling mechanism 4 comprises two water tanks 41, a water pump 42, a water inlet electromagnetic valve 43, a water inlet pipe 44, a main water pipe 45, a cooling pipe 46 and a water return pipe 47, wherein the two water tanks 41 are fixedly arranged on the side surface of the box body 1, water outlets on the side surfaces of the two water tanks 41 are respectively connected with one ends of the two water inlet pipes 44, the other ends of the two water inlet pipes 44 are connected with water inlets on the side surface of the main water pipe 45, the water pump 42 and the water inlet electromagnetic valve 43 are respectively arranged on the two water inlet pipes 44, the two water pumps 42 are respectively fixedly arranged on the side surfaces of the two water tanks 41, the middle part of the cooling pipe 46 is spiral, the side surface of the middle part of the cooling pipe 46 is fixedly connected with the side surface of the ozone generator body 2, one end of the cooling pipe 46 is connected with one end of the main water pipe 45, the other end of the cooling pipe 46 is connected with one end of the lower side of the Y-shaped water return pipe 47, two ends on the upper side of the water return pipe 47 are respectively connected with the water inlets on the side surfaces of the two water tanks 41, the side surfaces of the two water tanks 41 are fixedly provided with temperature sensors 6, one ends of the two temperature sensors 6 penetrate through holes on the side surfaces of the two water tanks 41 and extend into the two water tanks 41, the temperature sensors 6 are electrically connected with the control module 3, the temperature of cooling water in the water tanks 41 can be monitored through the temperature sensors 6, when the temperature reaches a preset value, the cooling water in the other water tank 41 is automatically switched to cool the ozone generator, the two water pumps 42 can alternately convey the cooling water in the two water tanks 41 into the cooling pipe 46 through the water inlet pipe 44 and the main water pipe 45 along with the duration of the ozone generator body 2, cool and dissipate heat of the ozone generator body 2, the cooling water in the two water tanks 41 can alternately cool and dissipate heat of the ozone generator, and the cooling water in the water tanks 41 absorbing a large amount of heat has enough time to dissipate heat, the cooling water conveyed into the cooling pipe 46 can be kept at a lower temperature all the time, so that the temperature of the ozone generator can be effectively reduced when the ozone generator works for a long time, and the influence of the excessive temperature of the cooling water on the normal work of the ozone generator is avoided;

the cooling water cooling mechanism 5 comprises a cooling electromagnetic valve 51, a cooling water inlet pipe 52, a heat exchanger 53 and a cooling water outlet pipe 54, wherein the two heat exchangers 53 are arranged, the two heat exchangers 53 are respectively and fixedly arranged on the side surfaces of the two water tanks 41, water inlets on the two heat exchangers 53 are respectively connected with one ends of the two cooling water inlet pipes 52, supporting frames 7 are respectively and fixedly arranged on the side surfaces of the two water tanks 41, the two supporting frames 7 are respectively positioned on the upper sides of the two heat exchangers 53, cooling fans 8 are respectively and fixedly arranged in through grooves on the two supporting frames 7, the cooling fans 8 are electrically connected with the control module 3, the air in the heat exchangers 53 can circulate through the cooling fans 8, the heat dissipation effect of the heat exchangers 53 can be effectively improved, the other ends of the two cooling water inlet pipes 52 are respectively connected with water outlets on the side surfaces of the two water inlet pipes 44, the two cooling water inlet pipes 52 are provided with cooling water electromagnetic valves 51, water outlets on the two heat exchangers 53 are respectively connected with one ends of two cooling water outlet pipes 54, a baffle plate 9 is fixedly arranged on the side face of the box body 1, the baffle plate 9 is positioned between the two heat exchangers 53, hot air blown out by the upper heat dissipation fan 8 can be blocked through the baffle plate 9, heat of the upper heat exchanger 53 is prevented from being transferred to the lower heat exchanger 53 along with the blowing of the heat dissipation fan 53, the other ends of the two cooling water outlet pipes 54 are respectively connected with water inlets on the side face of the two water tanks 41, the water pump 42, the water inlet electromagnetic valves 43 and the cooling water electromagnetic valves 51 are electrically connected with the control module 3, cooling water with higher temperature can be conveyed into the heat exchangers 53 through the cooling water inlet pipes 52, and the heat in the cooling water can be dissipated through the heat exchangers 53, so that the temperature of the cooling water is reduced.

The working principle of the utility model is as follows: when the ozone generator body 2 is in operation, the control module 3 can control the water pump 42 on one of the water tanks 41 to operate, so that the cooling water in the water tank 41 can be conveyed into the driving pipe 45 through the water inlet pipe 44, and the water is conveyed into the spiral cooling pipe 46 through the water pipe 45, so that the cooling water is fully contacted with the ozone generator body 2 in the cooling pipe 46, the cooling water absorbs heat generated when the ozone generator body 2 is in operation, the cooling water absorbing heat is conveyed back into the water tank 41 through the recovery pipe 47 along with the operation of the water pump 42, the temperature of the cooling water in the water tank 41 can be increased along with the continuous operation of the ozone generator body 2, the temperature sensor 6 can monitor the temperature of the cooling water in the water tank 41, and when the temperature of the cooling water in the water tank 41 is high and the set value, the control module 3 can automatically control the closing of the water inlet electromagnetic valve 43 on the water inlet pipe 44, meanwhile, the control module 3 can automatically control the other water pump 42 to work, so that the cooling water in the other water tank 41 is conveyed into the cooling pipe 46 through the water inlet pipe 44 and the main water pipe 45 to continuously cool the ozone generator body 2, when one water inlet electromagnetic valve 43 is closed, the control module 3 can simultaneously control the opening of the cooling electromagnetic valve 51 on the cooling water inlet pipe 52 connected with the water inlet pipe 44, under the working of the water inlet pipe 42, the cooling water with higher temperature in the water tank 41 is conveyed into the heat exchanger 53 through the water inlet pipe 44 and the cooling water inlet pipe 52, the heat in the cooling water is emitted into the air by the heat exchanger 53, thereby reducing the temperature of the cooling water, simultaneously, the cooling fan 8 is controlled to blow the heat exchanger 53 through the control module 3 to improve the circulation speed of the air in the heat exchanger 53, the heat exchange effect of the heat exchanger 53 is improved, so that the cooling water is rapidly cooled, the cooled cooling water flows back into the water tank 41 through the cooling water outlet pipe 54, and when the temperature of the cooling water in the other water tank 41 is higher, the control module 3 automatically operates the operation, so that the cooled cooling water in the water tank 41 is conveyed into the cooling pipe 46 to continuously cool the ozone generator body 2, and the cooled cooling water with higher temperature in the other water tank 41 is cooled.

The circuit connection related to the utility model is a conventional means adopted by the person skilled in the art, can obtain technical teaching through limited tests, and belongs to the widely used prior art.

The components not described in detail herein are prior art.

Although the specific embodiments of the present utility model have been described in detail, the present utility model is not limited to the above embodiments, and various changes and modifications without inventive labor may be made within the scope of the present utility model without departing from the spirit of the present utility model, which is within the scope of the present utility model.

Claims

1. The water-cooled ozone generator is characterized by comprising a box body (1), wherein a control module (3) is fixedly arranged on the side surface of the box body (1), an ozone generator body (2) is fixedly arranged in the box body (1), and a water cooling mechanism (4) and a cooling water cooling mechanism (5) are arranged on the box body (1);

the water cooling mechanism (4) comprises water tanks (41), water pumps (42), water inlet electromagnetic valves (43), water inlet pipes (44), main water pipes (45), cooling pipes (46) and water return pipes (47), wherein the two water tanks (41) are arranged, the two water tanks (41) are fixedly arranged on the side face of the box body (1), water outlets of the side faces of the two water tanks (41) are respectively connected with one ends of the two water inlet pipes (44), the other ends of the two water inlet pipes (44) are connected with water inlets of the side faces of the main water pipes (45), the water pumps (42) and the water inlet electromagnetic valves (43) are respectively arranged on the two water inlet pipes (44), the two water pumps (42) are respectively fixedly arranged on the side faces of the two water tanks (41), the middle part of the cooling pipe (46) is spiral, the side face of the middle part of the cooling pipe (46) is fixedly connected with one end of the main water pipe (45), the other end of the cooling pipe (46) is connected with one end of the Y-shaped water return pipe (47), and the two ends of the water return pipe (47) are respectively connected with the two water inlets of the side faces of the side of the Y-shaped water return pipe (47);

the cooling water cooling mechanism (5) comprises a cooling water electromagnetic valve (51), a cooling water inlet pipe (52), a heat exchanger (53) and a cooling water outlet pipe (54), wherein the two heat exchangers (53) are arranged, the two heat exchangers (53) are respectively and fixedly arranged on the side surfaces of the two water tanks (41), water inlets on the two heat exchangers (53) are respectively connected with one ends of the two cooling water inlet pipes (52), the other ends of the two cooling water inlet pipes (52) are respectively connected with water outlets on the side surfaces of the two water inlet pipes (44), the two cooling water electromagnetic valve (51) are respectively arranged on the two cooling water inlet pipes (52), water outlets on the two heat exchangers (53) are respectively connected with one ends of the two cooling water outlet pipes (54), the other ends of the two cooling water outlet pipes (54) are respectively connected with water inlets on the side surfaces of the two water tanks (41), and the water pump (42), the water inlet electromagnetic valve (43) and the cooling water electromagnetic valve (51) are electrically connected with the control module (3).

2. The water-cooled ozone generator of claim 1, wherein: the side faces of the two water tanks (41) are fixedly provided with temperature sensors (6), one ends of the two temperature sensors (6) penetrate through holes in the side faces of the two water tanks (41) and extend to the inside of the two water tanks (41), and the temperature sensors (6) are electrically connected with the control module (3).

3. The water-cooled ozone generator of claim 1, wherein: the side of two water tank (41) is all fixed mounting has braced frame (7), and two braced frame (7) are located the upside of two heat exchangers (53) respectively, and two equal fixed mounting has radiator fan (8) in the logical inslot on braced frame (7), radiator fan (8) and control module (3) electric connection.

4. The water-cooled ozone generator of claim 1, wherein: the side of the box body (1) is fixedly provided with a baffle plate (9), and the baffle plate (9) is positioned between the two heat exchangers (53).

5. The water-cooled ozone generator of claim 1, wherein: universal wheels (10) are fixedly arranged at four corners of the bottom of the box body (1).