CN213075403U - Ozone disinfection type drinking water equipment - Google Patents

Abstract

The utility model discloses an ozone disinfection type drinking water device, which comprises a machine body, a water purifying mechanism, a water storage tank, an ozone generating mechanism, a heating mechanism, a first water outlet assembly and a second water outlet assembly, wherein the output end of the water purifying mechanism is connected with the input end pipeline of the water storage tank; the output end of the water storage tank is connected with the input end pipeline of the heating mechanism, the first water outlet assembly is arranged on the machine body and connected with the output end pipeline of the heating mechanism, and the second water outlet assembly is arranged on the machine body and connected with the output end pipeline of the water storage tank. The drinking water equipment has a self-cleaning function and can carry out ozone sterilization on the wading part of the drinking water equipment; this equipment cools down the processing discharge with steam, and utilizes the heat of steam to heat up the water again at this in-process, reduces the required time of boiling of water, can reach the purpose of energy saving to heat recovery.

Description

Ozone disinfection type drinking water equipment

Technical Field

The utility model relates to a drinking water equipment field, in particular to ozone disinfection formula drinking water equipment.

Background

Along with the development of the times, because the problem of water quality is increasingly outstanding, drinking water dispensers capable of providing quality direct drinking water are arranged in most office buildings, the water supply pipeline of the drinking water dispensers is generally long, although the front-mounted filtering end of the direct drinking water is provided with a multi-layer filtering and disinfecting device, the sterilization and disinfection rate cannot reach 100%, and along with the prolonging of the service time, attachments such as algae and the like still appear in the water supply pipeline and are adsorbed on the pipe wall to influence the water quality of the direct drinking water. Therefore, it is necessary to periodically clean the water supply line, to kill the contaminants adhering to the pipe wall, and to remove them by an effective means.

SUMMERY OF THE UTILITY MODEL

According to one aspect of the utility model, an ozone disinfection type drinking water device is provided, which comprises a machine body, a water purifying mechanism, a water storage tank, an ozone generating mechanism, a heating mechanism, a first water outlet component and a second water outlet component, wherein the water purifying mechanism, the water storage tank and the heating mechanism are all arranged on the machine body, the output end of the water purifying mechanism is connected with the input end of the water storage tank through a pipeline, the ozone generating mechanism is arranged at the upper end of the water storage tank, and the action end of the ozone generating mechanism extends into the bottom of the water storage tank; the output end of the water storage tank is connected with the input end pipeline of the heating mechanism, the first water outlet assembly is arranged on the machine body and connected with the output end pipeline of the heating mechanism, and the second water outlet assembly is arranged on the machine body and connected with the output end pipeline of the water storage tank.

The utility model provides a drinking water equipment capable of self-cleaning and sterilizing. In the working process of the device, the water body is purified by the water purifying mechanism and then is input into the water storage tank, the water in the water storage tank enters the heating mechanism to be heated, and a user can take boiling water through the first water outlet assembly or take purified cold water through the second water outlet assembly. In the disinfection process of this equipment, ozone takes place the mechanism work, with ozone input water storage tank in, ozone and along with a pipeline gets into in the heating mechanism and export from first play water subassembly department, or along with another pipeline is direct to export from second play water subassembly department, because the bactericidal performance of ozone, disinfect to the water storage tank is inside to flow through the water that contains ozone in the water storage tank and disinfect each part that paddles of water dispenser. The utility model discloses a drinking water equipment possess self-purification function, can guarantee that user's drinking water is healthy.

In some embodiments, the ozone generating mechanism comprises an ozone generator and a bubbled stone, the ozone generator is fixed at the upper end of the water storage tank, the bubbled stone is positioned below the water storage tank, and the ozone generator is connected with the bubbled stone pipeline.

Therefore, the ozone generator is started and diffused into the water body of the water storage tank through the sepiolite.

In some embodiments, a water pump is arranged at the output end of the water storage tank, the water storage tank is connected with the heating mechanism through a pipeline, and the water tank is connected with the second water outlet assembly through a pipeline.

Therefore, the water pump provides water delivery power for the water storage tank.

In some embodiments, a water inlet pipe and a water outlet pipe are arranged in the water storage tank, the water inlet pipe is connected with a water purification mechanism pipeline, the water outlet pipe is connected with a water pump pipeline, and the water outlet pipe and the water inlet pipe are distributed in a height mode; a first high-low water level sensor is arranged in the water storage tank.

Thus, water supply can be ensured by the above structure.

In some embodiments, the heating mechanism includes a water tank, a heating tube, and a second high/low water level sensor, the heating tube is disposed in the water tank, the water tank is provided with a temperature detecting hole, and the second high/low water level sensor is disposed in the water tank.

Therefore, the water body enters the water liner and is heated by the heating pipe to rise the temperature.

In some embodiments, the heating mechanism further comprises a heat exchange assembly, the heat exchange assembly comprises an inner pipe and an outer pipe, the outer pipe is sleeved outside the inner pipe, and a sealing ring is arranged between the outer pipe and the inner pipe; the output end of the water storage tank is connected with the input end pipeline of the water container through the outer pipe, and the inner pipe is connected with the upper end of the water container.

Therefore, when the water body in the water liner is boiled, high-temperature steam is discharged from the upper end of the water liner and enters the inner pipe; the water body of the water storage tank enters the water container from the outer pipe, the cold water body is subjected to heat exchange with the high-temperature steam in the inner pipe through the inner pipe when passing through the outer pipe, the cold water is converted into warm water and enters the water container, and the high-temperature steam is condensed into warm water and is discharged out of the machine body. Through above structure, can prevent that steam from scalding the human body, and recycle steam, have energy-conserving effect.

In some embodiments, the water draining device further comprises a water draining groove and a water draining pipe, the water draining groove is arranged on the machine body and is located below the first water outlet assembly and the second water outlet assembly, and the water draining groove is communicated with the outside through the water draining pipe.

Thus, the drain tank is configured to receive the overflowing waste water and discharge the waste water to the outside of the machine body through the drain pipe.

In some embodiments, the lower end of the heating mechanism is provided with a third electromagnetic valve, and the heating mechanism is communicated with the drain pipe through the third electromagnetic valve.

Thereby, the third solenoid valve is configured to drain water in the heating mechanism.

In some embodiments, the first water outlet assembly includes a first electromagnetic valve, a first water outlet button, and a first water outlet, the first water outlet is connected to the output end of the heating mechanism through a pipeline, the first electromagnetic valve is disposed on the pipeline between the first water outlet and the heating mechanism, and the first water outlet button is in signal connection with the first electromagnetic valve.

Therefore, in the first water outlet assembly, the first electromagnetic valve can be opened through the first water outlet button, and the boiling water in the heating mechanism flows out from the first water outlet.

In some embodiments, the second water outlet assembly includes a second electromagnetic valve, a second water outlet button and a second water outlet, the second water outlet pipeline is connected to the output end pipeline of the water storage tank, the plurality of second electromagnetic valves are disposed on the pipeline between the second water outlet and the water storage tank, and the second water outlet button is in signal connection with the second electromagnetic valves.

Therefore, in the second water outlet assembly, the second electromagnetic valve can be opened through the second water outlet button, and the cold water in the water storage tank flows out from the second water outlet.

The utility model has the advantages that: the drinking water equipment has a self-cleaning function and can carry out ozone sterilization on the wading part of the drinking water equipment; moreover, the steam is cooled and discharged, the heat of the steam is reused to heat the water body in the process, the time required by boiling of the water body is shortened, the heat can be recycled, and the purpose of saving energy is achieved.

Drawings

Fig. 1 is a schematic front sectional view of an ozone disinfection drinking water device according to an embodiment of the present invention.

FIG. 2 is a schematic side sectional view of the ozone-sterilizing drinking water apparatus shown in FIG. 1.

FIG. 3 is a schematic cross-sectional view of the heat exchange module in the ozone-disinfecting drinking water apparatus shown in FIG. 1.

Fig. 4 is a partially enlarged schematic view of fig. 3.

Reference numbers in the figures: 0-machine body, 1-water purification mechanism, 11-filter, 12-water inlet, 2-water storage tank, 21-water pump, 22-water inlet pipe, 23-water outlet pipe, 24-first high and low water level, 3-ozone generation mechanism, 31-ozone generator, 32-air bubble stone, 4-heating mechanism, 41-water container, 42-heating pipe, 43-second high and low water level sensor, 44-temperature detecting hole, 45-heat exchange component, 451-inner pipe, 452-outer pipe, 453-sealing ring, 454-tee joint, 46-third electromagnetic valve, 5-first water outlet component, 51-first electromagnetic valve, 52-first water outlet button, 53-first water outlet, 6-second water outlet component, 61-second electromagnetic valve, 62-a second water outlet key, 63-a second water outlet, 71-a drainage groove and 72-a drainage pipe.

Detailed Description

The present invention will be described in further detail with reference to the accompanying drawings.

Fig. 1-2 schematically show an ozone disinfection type drinking water device according to an embodiment of the present invention, which includes a machine body 0, a water purifying mechanism 1, a water storage tank 2, an ozone generating mechanism 3, a heating mechanism 4, a first water outlet assembly 5 and a second water outlet assembly 6, wherein the water purifying mechanism 1, the water storage tank 2 and the heating mechanism 4 are all disposed on the machine body 0, an output end of the water purifying mechanism 1 is connected with an input end pipeline of the water storage tank 2, the ozone generating mechanism 3 is disposed at an upper end of the water storage tank 2, and an action end thereof extends into a bottom of the water storage tank 2; the output of storage water tank 2 and the input pipe connection of heating mechanism 4, first play water subassembly 5 locate on organism 0 and with the output pipe connection of heating mechanism 4, second play water subassembly 6 locate on organism 0 and with the output pipe connection of storage water tank 2. The water purification mechanism 1 comprises a filter 11 and a water inlet 12, the water inlet 12 is arranged on the outer wall of the machine body 0, the filter 11 is arranged in the machine body 0 and is positioned below the machine body, and the water inlet 12 is connected with an input end pipeline of the filter 11. The water storage tank 2 is arranged in the machine body 0 and is positioned at one side of the filter 11.

The utility model provides a drinking water equipment capable of self-cleaning and sterilizing. In the working process of the equipment, the water body is firstly purified by the water purifying mechanism 1 and then input into the water storage tank 2, the water in the water storage tank 2 enters the heating mechanism 4 to be heated, and the user can fetch boiling water through the first water outlet component 5 or fetch the purified cold water through the second water outlet component 6. In the disinfection process of this equipment, 3 work of mechanism are taken place to ozone, with ozone input storage water tank 2, ozone along with a pipeline get into in the heating mechanism 4 and export from first play water subassembly 5, or along with another pipeline is direct to export from second play water subassembly 6, because the bactericidal performance of ozone, disinfect 2 inside storage water tank to along with the flow of the water in the storage water tank 2 is disinfected to drinking water equipment each part of wading. The utility model discloses a drinking water equipment possess self-purification function, can guarantee that user's drinking water is healthy.

Referring to fig. 1, the ozone generating mechanism 3 comprises an ozone generator 31 and a sepiolite 32, the ozone generator 31 is fixed at the upper end of the water storage tank 2, a bubbled stone 32 is positioned below the water storage tank 2, and the ozone generator 31 is connected with the bubbled stone 32 through a pipeline. The ozone generator 31 is started and diffused into the water body of the water storage tank 2 through the sepiolite.

With reference to fig. 1-2, a water pump 21 is disposed at an output end of the water storage tank 2, the water storage tank 2 is connected to the heating mechanism 4 through the water pump 21, and the water tank is connected to the second water outlet assembly 6 through the water pump 21. The water pump 21 provides water delivery power for the water storage tank 2.

Referring to fig. 1-2, a water inlet pipe 22 and a water outlet pipe 23 are arranged in the water storage tank 2, the water inlet pipe 22 is connected with the water purification mechanism 1 through a pipeline, the water outlet pipe 23 is connected with the water pump 21 through a pipeline, and the water outlet pipe 23 and the water inlet pipe 22 are distributed in a high-low manner; a first high-low water level 24 sensor is arranged in the water storage tank 2. The water supply can be ensured by the above structure.

Referring to fig. 1-2, the heating mechanism 4 includes a water tank, a heating tube 42, and a second high/low water level sensor 43, the heating tube 42 is disposed in the water tank, the water tank is provided with a temperature detecting hole 44, and the second high/low water level sensor 43 is disposed in the water tank. The water body enters the water container and is heated by the heating tube 42.

With reference to fig. 1-4, the heating mechanism 4 further includes a heat exchange assembly 45, the heat exchange assembly 45 includes an inner tube 451 and an outer tube 452, and both the inner tube 451 and the outer tube 452 are corrugated tubes. The outer tube 452 is sleeved outside the inner tube 451, and a sealing ring 453 is arranged between the outer tube 452 and the inner tube 451; the output end of the water storage tank 2 is connected with the input end of the water container through an outer pipe 452, two ends of the outer pipe 452 are provided with a tee 454 for connecting the pipes, and the inlet end of the inner pipe 451 is connected with the upper end of the water container.

When the water in the water container is boiling, high-temperature steam is discharged from the upper end of the water container and enters the inner pipe 451; the water in the water storage tank 2 enters the water container from the outer pipe 452, the cold water passes through the outer pipe 452 and is subjected to heat exchange with the high-temperature steam in the inner pipe 451 through the inner pipe 451, the cold water is converted into warm water and enters the water container, and the high-temperature steam is condensed into warm water and is discharged out of the machine body 0. Through above structure, can prevent that steam from scalding the human body, and recycle steam, have energy-conserving effect.

With reference to fig. 1-2, the water dispenser further includes a water drainage groove 71 and a water drainage pipe 72, the water drainage groove 71 is disposed on the machine body 0 and located below the first water outlet assembly 5 and the second water outlet assembly 6, and the water drainage groove 71 is communicated with the outside through the water drainage pipe 72. The drain tank 71 is configured to receive the overflowing waste water and discharge the waste water to the outside of the machine body 0 through a drain pipe 72. The outlet end of the inner pipe 451 communicates with the drain pipe 72.

Referring to fig. 1-2, the lower end of the water bladder of the heating mechanism 4 is provided with a third electromagnetic valve 46, and the heating mechanism 4 is communicated with a drain pipe 72 through the third electromagnetic valve 46. The third solenoid valve 46 is configured to purge the water in the heating mechanism 4.

Referring to fig. 1-2, the first water outlet assembly 5 includes a first solenoid valve 51, a first water outlet button 52 and a first water outlet 53, the first water outlet 53 is connected to an output end of the heating mechanism 4, the first solenoid valve 51 is disposed on a pipe between the first water outlet 53 and the heating mechanism 4, and the first water outlet button 52 is in signal connection with the first solenoid valve 51. In the first water outlet assembly 5, the first solenoid valve 51 can be opened through the first water outlet button 52, so that the boiling water in the heating mechanism 4 flows out from the first water outlet 53.

Referring to fig. 1-2, the second water outlet assembly 6 includes a second solenoid valve 61, a second water outlet button 62 and a second water outlet 63, the second water outlet 63 is connected to the output end of the water storage tank 2, the second solenoid valves 61 are disposed on the pipeline between the second water outlet 63 and the water storage tank 2, and the second water outlet button 62 is in signal connection with the second solenoid valves 61. In the second water outlet assembly 6, the second electromagnetic valve 61 can be opened through the second water outlet button 62, so that the cold water in the water storage tank 2 flows out from the second water outlet 63.

Referring to fig. 1-2, the energy-saving drinking water apparatus further includes an electrical assembly and a control device. The electric component is electrically connected with the control device, and the electric component is electrically connected with electric elements such as the ozone generating mechanism 3, the water purifying mechanism 1, the first water outlet component 5, the second water outlet component 6, the heating mechanism 4, the water pump 21, the third electromagnetic valve 46 and the like. The electric assembly and the control device are an electric control system of the equipment.

In this embodiment, the disinfection function is automatically turned on, the disinfection time is set when leaving the factory, and the disinfection interval time can be adjusted by the user at the later stage as required.

1. And (3) normal state:

the water is input from the water inlet 12, filtered by the filter 11 and then input into the water storage tank 2. One end of the cold water in the water storage tank 2 is input into the water container to be heated into boiling water; before entering the water tank, the cold water is subjected to heat exchange by the heat exchange mechanism; high-temperature steam is discharged from the upper end of the water container and enters the inner pipe 451; the water in the water storage tank 2 enters the water container from the outer pipe 452, the cold water passes through the outer pipe 452 and is subjected to heat exchange with the high-temperature steam in the inner pipe 451 through the inner pipe 451, the cold water is converted into warm water and enters the water container, and the high-temperature steam is condensed into warm water and is discharged out of the machine body 0. The first solenoid valve 51 can be opened by the first water outlet button 52, so that the boiling water in the heating mechanism 4 flows out from the first water outlet 53.

The water is input from the water inlet 12, filtered by the filter 11 and then input into the water storage tank 2. The other end of the water body is directly output from the second water outlet assembly 6. The second solenoid valve 61 can be opened by the second water outlet button 62, and the purified water in the water storage tank 2 directly flows out from the second water outlet 63.

2. And (3) disinfection state:

the ozone generating mechanism 3 works, the ozone generator 31 is started, and the ozone is diffused into the water body of the water storage tank 2 through the sepiolite. Ozone enters a water container of the heating mechanism 4 along with a pipeline and is output from the first water outlet assembly 5; or directly output from the second water outlet assembly 6 along with another pipeline, and disinfect and sterilize the inside of the water storage tank 2 due to the sterilization performance of ozone, and disinfect and sterilize each wading part of the water dispenser through the flow of water containing ozone in the water storage tank 2.

The drinking water equipment has a self-cleaning function and can carry out ozone sterilization on the wading part of the drinking water equipment; moreover, the steam is cooled and discharged, the heat of the steam is reused to heat the water body in the process, the time required by boiling of the water body is shortened, the heat can be recycled, and the purpose of saving energy is achieved.

What has been described above are only some embodiments of the invention. For those skilled in the art, without departing from the inventive concept, several modifications and improvements can be made, which are within the scope of the invention.

Claims (10)

1. The ozone disinfection type drinking water equipment is characterized by comprising a machine body (0), a water purifying mechanism (1), a water storage tank (2), an ozone generating mechanism (3), a heating mechanism (4), a first water outlet assembly (5) and a second water outlet assembly (6), wherein the water purifying mechanism (1), the water storage tank (2) and the heating mechanism (4) are all arranged on the machine body (0), the output end of the water purifying mechanism (1) is connected with the input end of the water storage tank (2) through a pipeline, the ozone generating mechanism (3) is arranged at the upper end of the water storage tank (2), and the action end of the ozone generating mechanism extends into the bottom of the water storage tank (2); the output of storage water tank (2) and the input pipe connection of heating mechanism (4), first play water subassembly (5) are located on organism (0) and are connected with the output pipe connection of heating mechanism (4), second play water subassembly (6) are located on organism (0) and are connected with the output pipe connection of storage water tank (2).

2. The ozone disinfection type drinking water equipment as claimed in claim 1, wherein the ozone generating mechanism (3) comprises an ozone generator (31) and a sepiolite (32), the ozone generator (31) is fixed at the upper end of the water storage tank (2), the bubbled stone (32) is positioned below the inside of the water storage tank (2), and the ozone generator (31) is connected with the bubbled stone (32) through a pipeline.

3. The ozone disinfection drinking water device as claimed in claim 1, wherein a water pump (21) is provided at the output end of the water storage tank (2), the water storage tank (2) is in pipe connection with the heating mechanism (4) through the water pump (21), and the water tank is in pipe connection with the second water outlet assembly (6) through the water pump (21).

4. The ozone disinfection type drinking water equipment as claimed in claim 3, wherein a water inlet pipe (22) and a water outlet pipe (23) are arranged in the water storage tank (2), the water inlet pipe (22) is connected with the water purification mechanism (1) through a pipeline, the water outlet pipe (23) is connected with the water pump (21) through a pipeline, and the water outlet pipe (23) and the water inlet pipe (22) are distributed in a height way; a first high-low water level (24) sensor is arranged in the water storage tank (2).

5. The ozone disinfection type drinking water device as claimed in claim 1, wherein the heating mechanism (4) comprises a water tank (41), a heating tube (42) and a second high and low water level sensor (43), the heating tube (42) is arranged in the water tank (41), a temperature detecting hole (44) is arranged on the water tank (41), and the second high and low water level sensor (43) is arranged in the water tank (41).

6. The ozone disinfection type drinking water device as claimed in claim 5, wherein the heating mechanism (4) further comprises a heat exchange assembly (45), the heat exchange assembly (45) comprises an inner tube (451) and an outer tube (452), the outer tube (452) is sleeved outside the inner tube (451), and a sealing ring (453) is arranged between the outer tube (452) and the inner tube (451); the output end of the water storage tank (2) is connected with the input end pipeline of the water container (41) through an outer pipe (452), and the inner pipe (451) is connected with the upper end of the water container (41).

7. The ozone disinfection type drinking water device as claimed in any one of claims 1-6, further comprising a drainage groove (71) and a drainage pipe (72), wherein the drainage groove (71) is arranged on the machine body (0) and is positioned below the first water outlet assembly (5) and the second water outlet assembly (6), and the drainage groove (71) is communicated with the outside through the drainage pipe (72).

8. The ozone disinfection drinking water device as claimed in claim 7, wherein a third solenoid valve (46) is provided at the lower end of the heating means (4), and the heating means (4) is communicated with the drain pipe (72) through the third solenoid valve (46).

9. The ozone disinfection type drinking equipment as claimed in claim 7, wherein the first water outlet assembly (5) comprises a first solenoid valve (51), a first water outlet button (52) and a first water outlet (53), the first water outlet (53) is connected with an output end pipeline of the heating mechanism (4), the first solenoid valve (51) is arranged on a pipeline between the first water outlet (53) and the heating mechanism (4), and the first water outlet button (52) is in signal connection with the first solenoid valve (51).

10. The ozone disinfection type water drinking device as claimed in claim 7, wherein the second water outlet assembly (6) comprises a second electromagnetic valve (61), a second water outlet button (62) and a second water outlet (63), the second water outlet (63) is connected with the output end of the water storage tank (2) through a pipeline, the second electromagnetic valves (61) are arranged on the pipeline between the second water outlet (63) and the water storage tank (2), and the second water outlet button (62) is in signal connection with the second electromagnetic valves (61).

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