CN219538047U - Ozone disinfection drinking machine - Google Patents

Abstract

The utility model discloses an ozone disinfection drinking machine, comprising: the warm boiled water waterway is provided with a main waterway and a plurality of branch waterways, and the end parts of the branch waterways are provided with warm boiled water mouths; an ozone generator; the ozone distributor is provided with an input end and a plurality of output ends, wherein the input end is connected with the ozone generator, and the output ends are respectively connected with the warm boiled water waterways. The design has the following characteristics: (1) The sterilization is rapid and thorough, ozone can permeate into each corner of water, and bacteria and microorganisms growing in the water are rapidly killed; (2) Ozone can be quickly volatilized and reduced into oxygen molecules, and no residue exists in water, so that the water quality sanitation is not affected; (3) relatively low cost; (4) damage is easily found and replaced.

Description

Ozone disinfection drinking machine

Technical Field

The utility model relates to the technical field of water dispensers, in particular to an ozone disinfection water dispenser.

Background

For the energy-saving water dispenser provided with the warm boiled water storage tank, how to ensure the sterility of the warm boiled water storage tank and the warm boiled water outlet pipeline and ensure the cleanness, sterility, sanitation and health of the drinking water, a method for sterilizing bacteria by installing an overcurrent type ultraviolet sterilizer on the warm boiled water pipeline is generally adopted in the industry, and the method has two disadvantages for the water dispenser with a plurality of warm boiled water outlets: (1) Because the overcurrent ultraviolet sterilizer is required to be arranged in front of the water outlet nozzle of each water outlet pipeline, the installation is troublesome; (2) The sterilization effect is gradually deteriorated or even not affected by the attenuation of ultraviolet rays and the service life, but the attenuation or damage of the ultraviolet sterilizer is difficult to be found by observing the appearance of the ultraviolet sterilizer.

Disclosure of Invention

The utility model aims to solve the technical problems that: an ozone disinfection drinking machine is provided to solve one or more technical problems existing in the prior art, and at least provides a beneficial choice or creation condition.

The utility model solves the technical problems as follows:

an ozone disinfection water dispenser comprising:

the warm boiled water waterway is provided with a main waterway and a plurality of branch waterways, and the end parts of the branch waterways are provided with warm boiled water mouths;

an ozone generator;

the ozone distributor is provided with an input end and a plurality of output ends, wherein the input end is connected with the ozone generator, and the output ends are respectively connected with the warm boiled water waterways.

Through the technical scheme, the novel water dispenser is provided with the ozone generator, the ozone generator is opened at regular time to generate ozone by program setting, the ozone is uniformly conveyed to each branch waterway through the ozone distributor, the plurality of branch waterways are disinfected and sterilized, then the water flows back to the warm water tank through each branch pipeline, and the ozone can destroy the structure of a microbial film, so that the effect of rapid sterilization can be achieved; meanwhile, the ozone has the characteristic of quickly volatilizing and reducing into oxygen molecules after being dissolved in water, and no harmful substances remain after disinfection.

The design has the following characteristics: (1) The sterilization is rapid and thorough, ozone can permeate into each corner of water, and bacteria and microorganisms growing in the water are rapidly killed; (2) Ozone can be quickly volatilized and reduced into oxygen molecules, and no residue exists in water, so that the water quality sanitation is not affected; (3) relatively low cost; (4) damage is easily found and replaced.

As a further improvement of the technical scheme, the main waterway is provided with a warm water tank.

Through the technical scheme, the warm water tank can be used for storing warm boiled water, and the flow rate of warm boiled water is larger when warm boiled water is stored in the warm water tank and taken.

As a further improvement of the technical scheme, the warm water tank is provided with a heat preservation device.

Through the technical scheme, the heat preservation device can preserve the temperature of the warm boiled water stored in the warm water tank, so that the warm boiled water in the warm water tank is kept within a certain temperature range.

As a further improvement of the technical scheme, the branch waterway is provided with a warm water electromagnetic valve.

By the technical scheme, the warm water solenoid valve is used for controlling whether the warm water nozzle discharges water or not.

As a further improvement of the technical scheme, the water dispenser further comprises a boiled water tank, the boiled water tank is connected with the warm water tank, and a water pump is arranged between the boiled water tank and the warm water tank.

Through the technical scheme, the water pump pumps boiled water in the boiled water tank to the warm water tank.

As a further improvement of the technical scheme, the boiled water tank is provided with a second water level detection device, and the second water level detection device is arranged at the upper end of the boiled water tank.

As a further improvement of the technical scheme, the water boiling tank is provided with a third water level detection device, and the third water level detection device is arranged at the lower end of the water boiling tank.

As a further improvement of the above technical scheme, the water dispenser further comprises a cold water channel, and the cold water channel is connected with the water boiling tank; the cold water waterway is provided with a one-way valve and a water inlet electromagnetic valve.

As a further improvement of the technical scheme, the cold water channel is also provided with a water purifying filter.

Through above-mentioned technical scheme, water purification filter is used for filtering external inflow's water to guarantee quality of water.

As a further improvement of the technical scheme, the water dispenser is further provided with a heat exchanger, the heat exchanger is provided with a cold water pipeline and a hot water pipeline, two ends of the cold water pipeline are respectively connected with the cold water waterway and the boiled water tank, and two ends of the hot water pipeline are respectively connected with the water pump and the boiled water tank.

Through the technical scheme, the heat exchanger can enable cold water flowing through to be heated and hot water to be cooled.

The beneficial effects of the utility model are as follows: (1) The sterilization is rapid and thorough, ozone can permeate into each corner of water, and bacteria and microorganisms growing in the water are rapidly killed; (2) Ozone can be quickly volatilized and reduced into oxygen molecules, and no residue exists in water, so that the water quality sanitation is not affected; (3) relatively low cost; (4) damage is easily found and replaced.

The utility model is used in the technical field of water dispensers.

Drawings

In order to more clearly illustrate the technical solutions in the embodiments of the present utility model, the drawings that are required to be used in the description of the embodiments will be briefly described below. It is evident that the drawings described are only some embodiments of the utility model, but not all embodiments, and that other designs and drawings can be obtained from these drawings by a person skilled in the art without inventive effort.

Fig. 1 is a schematic overall structure of an embodiment of the present utility model.

100, a boiled water tank; 110. a boiled water heating device; 120. a second water level detecting means; 130. a third water level detecting means; 200. a heat exchanger; 300. a warm boiled water waterway; 301. a main waterway; 302. a branch waterway; 310. a water pump; 320. a warm water tank; 340. a warm water tap; 350. a first water level detecting means; 360. an overflow port; 370. a thermal insulation structure; 380. a warm water solenoid valve; 400. a cold water path; 410. a water source; 420. a water purifying filter; 430. a water inlet electromagnetic valve; 440. a one-way valve; 510. an ozone generator; 520. an ozone dispenser.

Detailed Description

The conception, specific structure, and technical effects produced by the present utility model will be clearly and completely described below with reference to the embodiments and the drawings to fully understand the objects, features, and effects of the present utility model. It is apparent that the described embodiments are only some embodiments of the present utility model, but not all embodiments, and that other embodiments obtained by those skilled in the art without inventive effort are within the scope of the present utility model based on the embodiments of the present utility model. In addition, all coupling/connection relationships mentioned herein do not refer to direct connection of the components, but rather, refer to the fact that a more optimal coupling structure may be formed by adding or subtracting coupling aids depending on the particular implementation. The technical features in the utility model can be interactively combined on the premise of no contradiction and conflict.

Referring to fig. 1, an ozone sterilizing water dispenser includes a cold water path 400, a boiled water tank 100, a warm water tank 320, a heat exchanger 200, an ozone generator 510, and an ozone dispenser 520.

The cold water path 400 is provided with a water purification filter 420, a water inlet solenoid valve 430, and a check valve 440. The water purification filter 420, the water inlet solenoid valve 430 and the check valve 440 are sequentially arranged in the water inlet direction, and the water purification filter 420, the water inlet solenoid valve 430 and the check valve 440 are connected through water pipes. One end of the cold water waterway 400 is connected to a water source 410, and the water source 410 is municipal tap water. The water purification filter 420 serves to filter municipal tap water to achieve purification of water. The water inlet solenoid valve 430 is used to control whether municipal tap water flows into the water dispenser.

The flow direction of the check valve 440 is from the water source 410 toward the heat exchanger 200. The check valve 440 serves to prevent water from flowing back from the heat exchanger 200 into the cold water waterway 400.

The heat exchanger 200 is provided with a hot water pipe and a cold water pipe. The hot water and the cold water flow in the hot water pipe and the cold water pipe, respectively, and the flow directions of the hot water and the cold water are opposite.

The cold water pipe is provided with a cold water inlet end and a cold water outlet end, the cold water inlet end is connected with one end of the check valve 440, which is far away from the water inlet electromagnetic valve 430, through a water pipe, and the cold water outlet end is connected with the boiled water tank 100 through a water pipe.

The hot water pipe is provided with a hot water inlet end and a hot water outlet end, the hot water inlet end is connected with the boiled water tank 100 through a water pipe, and the hot water outlet end is in butt joint with the warm boiled water waterway 300.

When cold water and hot water flow in the heat exchanger 200, the heat of the hot water can be transferred to the cold water, and the heat transfer of the liquid can be realized, so that the cold water in the cold water pipeline is preheated, and the hot water in the hot water pipeline is cooled.

The boiled water tank 100 is internally provided with a boiled water heating device 110, the boiled water heating device 110 is provided as a heating pipe, and the boiled water heating device 110 is used for heating boiled water in the boiled water tank 100 to boiling. The boiled water tank 100 is installed therein with a second water level detecting device 120 and a third water level detecting device 130, the second water level detecting device 120 and the third water level detecting device 130 are installed at the upper and lower ends of the boiled water tank 100, and the second water level detecting device 120 is disposed above the third water level detecting device 130.

The second water level detecting device 120 and the third water level detecting device 130 are respectively used for detecting the water level in the boiled water tank 100, when the water level of the boiled water tank 100 reaches the second water level detecting device 120, water inflow is stopped, so that the water level in the boiled water tank 100 is near the water level with a specific height before heating, a sufficient amount of air is left in the boiled water tank 100, and the excessive pressure in the boiled water tank 100 caused by the expansion of the water volume in the boiled water tank 100 during boiling is avoided; the water level of the boiled water tank 100 is lower than the third water level detecting means 130 to start water inflow so as to prevent the water level of the boiled water tank 100 from being excessively low.

The warm boiled water waterway 300 comprises a main waterway 301 and a plurality of branch waterways 302, wherein the plurality of branch waterways 302 are communicated with the main waterway 301, and the warm boiled water waterway 300 is provided with a water pump 310, a warm water tank 320, a warm boiled water electromagnetic valve 380 and a warm boiled water nozzle 340; the water pump 310 and the warm water tank 320 are all arranged on the main waterway 301, the number of the warm water solenoid valves 380 and the warm water mouths 340 is equal to that of the branch waterways 302, and the warm water solenoid valves 380 and the warm water mouths 340 are all arranged on the branch waterways 302. The water pump 310, the warm water tank 320, the warm water solenoid valve 380 and the warm water nozzle 340 are sequentially arranged along the direction from one end close to the boiled water tank 100 to one end far away from the boiled water tank 100, and the water pump 310, the warm water tank 320, the warm water solenoid valve 380 and the warm water nozzle 340 are connected through water pipes.

The water pump 310 is used to pump the boiled water heated to boiling in the boiled water tank 100 out to the warm water tank 320.

The thermal insulation structure 370 is installed in the warm water tank 320, the thermal insulation structure 370 is a heating pipe, the thermal insulation structure 370 is used for carrying out thermal insulation heating on warm boiled water stored in the warm water tank 320, so that the temperature of the warm water in the warm water tank 320 is kept within a certain range, and a drinker can obtain warm boiled water in a proper temperature range.

The warm water tank 320 is provided with a first water level detection device 350, and the first water level detection device 350 is used for detecting the water level of the warm water tank 320, so as to avoid the water level in the warm water tank 320 from being too high.

The ozone distributor 520 is provided with a plurality of output terminals and an input terminal, which is connected to the ozone generator 510. The number of the output ends is matched with that of the branch waterways 302, the output ends are arranged in one-to-one correspondence with the branch waterways 302, and the output ends are connected with the corresponding branch waterways 302.

The water source 410 (municipal tap water) of the water dispenser is purified by the water purifying filter 420, the water inlet valve 430 controls the water inlet pipeline entering the heat exchanger 200 to enter the water boiling tank 100 for heating, the water in the water boiling tank 100 is heated and boiled, then rapidly cooled by the heat exchanger 200 to warm boiled water, and then pumped by the water pump 310 to the warm water tank 320 for storage and heat preservation.

The warm boiled water is taken out through the warm boiled water waterway 300, the warm boiled water solenoid valve 380 and the warm boiled water nozzle 340.

Since the environments of the warm water tank 320 and the warm water waterway 300 are suitable for the breeding of microorganisms and bacteria, it is necessary to sterilize them at regular time. According to the scheme, the ozone generator 510 and the ozone distributor 520 are arranged in the water dispenser, the water dispenser can be set by a program to turn on the ozone generator 510 at regular time to generate ozone, the ozone is uniformly conveyed to each branch waterway 302 of the warm boiled water waterway 300 through the ozone distributor 520, the plurality of branch waterways 302 of the warm boiled water are sterilized, then the warm water is returned to the warm water tank 320 through each branch pipeline, and the ozone damages the microbial membrane structure through oxidation-reduction reaction, so that the effect of rapid sterilization can be achieved. Ozone gradually reduces and volatilizes in the disinfection and sterilization process, and returns to the air through the overflow port 360 of the warm water tank 320. Ozone is dissolved in water and then quickly reduced into oxygen molecules, so that ozone residue is avoided after disinfection by ozone is finished, and the health of drinkers is facilitated.

The design utilizes the function of rapid sterilization of ozone and the function of automatic volatilization and reduction, and the built-in program of the water dispenser uniformly fills ozone into the warm boiled water waterway 300 and the warm water tank 320 of the water dispenser at midnight idle time of the water dispenser for sterilization so as to provide clean, sterile, healthy and sanitary drinking water.

The program in the ozone generator 510 is set with different working time periods according to the different water supply time periods of each water dispenser, so that the sterility and microorganisms of drinking warm boiled water can be ensured, and meanwhile, no ozone residue can be ensured during drinking, and clean, sanitary and delicious warm boiled water can be drunk.

The design has the following characteristics: (1) The sterilization is rapid and thorough, ozone can permeate into each corner of water, and bacteria and microorganisms growing in the water are rapidly killed; (2) Ozone can be quickly volatilized and reduced into oxygen molecules, and no residue exists in water, so that the water quality sanitation is not affected; (3) relatively low cost; (4) damage is easily found and replaced.

While the preferred embodiment of the present utility model has been described in detail, the utility model is not limited to the embodiments, and various equivalent modifications and substitutions can be made by those skilled in the art without departing from the spirit of the utility model, and these modifications and substitutions are intended to be included in the scope of the present utility model as defined in the appended claims.

Claims (10)

1. An ozone disinfection drinking machine, which is characterized in that: comprising the following steps:

the warm water waterway comprises a main waterway and a plurality of branch waterways, and warm water mouths are arranged at the end parts of the branch waterways;

an ozone generator;

the ozone distributor is provided with an input end and a plurality of output ends, wherein the input end is connected with the ozone generator, and the output ends are respectively connected with the warm boiled water waterways.

2. An ozone disinfection drinking machine as set forth in claim 1, wherein: the main waterway is provided with a warm water tank.

3. An ozone disinfection drinking machine as set forth in claim 2, wherein: the warm water tank is provided with a heat preservation device.

4. An ozone disinfection drinking machine as set forth in claim 2, wherein: the branch waterway is provided with a warm boiled water electromagnetic valve.

5. An ozone disinfection drinking machine as set forth in claim 2, wherein: the water dispenser also comprises a boiled water tank, wherein the boiled water tank is connected with the warm water tank, and a water pump is arranged between the boiled water tank and the warm water tank.

6. An ozone disinfecting drinking machine as defined in claim 5, wherein: the boiled water tank is provided with a second water level detection device, and the second water level detection device is arranged at the upper end of the boiled water tank.

7. An ozone disinfecting drinking machine as defined in claim 5, wherein: the water boiling tank is provided with a third water level detection device, and the third water level detection device is arranged at the lower end of the water boiling tank.

8. An ozone disinfecting drinking machine as defined in claim 5, wherein: the water dispenser further comprises a cold water channel, and the cold water channel is connected with the boiled water tank; the cold water waterway is provided with a one-way valve and a water inlet electromagnetic valve.

9. The ozone disinfection drinking machine of claim 8, wherein: the cold water channel is also provided with a water purifying filter.

10. The ozone disinfection drinking machine of claim 8, wherein: the water dispenser is also provided with a heat exchanger, the heat exchanger is provided with a cold water pipeline and a hot water pipeline, two ends of the cold water pipeline are respectively connected with the cold water pipeline and the boiled water tank, and two ends of the hot water pipeline are respectively connected with the water pump and the boiled water tank.