CN214072813U - Ozone water cup - Google Patents

Abstract

The utility model provides an ozone water cup, which comprises a cup body, a cup seat and an ozone generating mechanism, wherein the ozone generating mechanism is provided with an air outlet channel, the cup seat comprises a bottom shell which is arranged at an interval with the cup body and is used for accommodating the ozone generating mechanism and a middle shell which is arranged between the cup body and the bottom shell, the middle shell comprises a fixed part which is connected with the cup body, a separation plate which extends inwards from the fixed part and forms a connection part which extends towards the bottom shell from the separation plate, a gas separating part which forms an air cavity with the separation plate is fixedly arranged at one side of the separation plate away from the connection part, the connection part forms a through hole which is communicated with the air cavity with the surrounding, the air outlet channel extends into the through hole from the bottom shell and is connected with the connection part in a sealing way, wherein, the bore of air cavity is greater than the air outlet channel bore, and gas partition spare includes ventilative barrier film and perforated plate, and ventilative barrier film presss from both sides and locates between perforated plate and the division board, and the perforated plate has the air flue of a plurality of intercommunication air cavities and cup body. The ozone water cup provided by the utility model can improve the efficiency of ozone dissolved in water.

Description

Ozone water cup

[ technical field ] A method for producing a semiconductor device

The utility model relates to an ozone water preparation field especially relates to an ozone drinking cup.

[ background of the invention ]

Ozone is a high-efficiency and quick bactericide, has strong universality in sterilization, can kill various bacteria, viruses and microorganisms causing diseases of people and animals, and destroys the structures of the bacteria, the viruses and other microorganisms in a short time to enable the bacteria, the viruses and the other microorganisms to lose viability. Ozone is dissolved in water, and the disinfection and sterilization effect is better and safer than that of ozone gas. However, the ozone water producing apparatus in the related art has not only problems of complicated structure, large volume, inconvenience in movement and portability, but also low efficiency in dissolving ozone in water.

Therefore, there is a real need for an improvement of the ozone production apparatus in the related art to avoid the above problems.

[ Utility model ] content

An object of the utility model is to provide an ozone drinking cup, this ozone drinking cup can improve the efficiency that ozone dissolved in water, and simple structure conveniently carries and uses.

The utility model provides an ozone water cup, which comprises a cup body, a cup seat and an ozone generating mechanism, wherein the ozone generating mechanism is provided with an air outlet channel, the cup seat comprises a bottom shell which is arranged at an interval with the cup body and is used for accommodating the ozone generating mechanism and a middle shell which is arranged between the cup body and the bottom shell, the middle shell comprises a fixed part which is connected with the cup body, a separation plate which is formed by extending inwards from the fixed part and a connecting part which is formed by extending inwards from the separation plate to the bottom shell, one side of the separation plate, which is far away from the connecting part, is fixedly provided with a gas separating part which forms an air cavity by surrounding the separation plate, the connecting part forms a through hole which is communicated with the air cavity by surrounding, the air outlet channel extends into the through hole from the bottom shell and is connected with the connecting part in a sealing way, wherein, the caliber of the air cavity is larger than that of the air outlet channel, the gas partition piece comprises a porous plate and a breathable isolating membrane clamped between the porous plate and the separating plate, and the porous plate is provided with a plurality of micron-sized gas passages communicated with a space surrounded by the gas cavity and the cup body.

Preferably, the pore diameter of the air channel is 5-20 microns.

Preferably, the partition plate is protruded in a direction away from the bottom case at a position between the fixing portion and the connecting portion to form a protruding portion, an accommodating cavity is formed by enclosing the protruding portion and the fixing portion, the cup body is inserted into the accommodating cavity, and the periphery of the gas dividing member is fixed to the protruding portion.

Preferably, a sealing groove is formed in one side, away from the bottom case, of the protrusion, and a sealing gasket clamped between the breathable isolation film and the protrusion is accommodated in the sealing groove.

Preferably, the gas separator and the protrusion are connected to each other by a fastener penetrating the gas separator, the gasket, and the protrusion.

Preferably, a sealing gasket clamped between the cup body and the partition plate is arranged in the accommodating cavity.

Preferably, ozone generation mechanism includes ozone generator, positive pole water tank and negative pole water tank, ozone generator includes positive pole inlet channel, positive pole gas outlet channel, negative pole inlet channel and negative pole gas outlet channel, the positive pole water tank includes gas outlet channel, with the positive pole water outlet channel of positive pole inlet channel intercommunication and with the positive pole intake duct of positive pole gas outlet channel intercommunication, the negative pole water tank include negative pole water supply channel, with the negative pole water outlet channel of negative pole inlet channel intercommunication and with the negative pole intake duct of negative pole gas outlet channel intercommunication, wherein, negative pole water supply channel stopper has the sealing plug.

Preferably, the middle shell further comprises an extending portion formed by extending from the fixing portion to the bottom shell, the extending portion, the bottom shell, the partition plate and the connecting portion are enclosed to form a containing cavity, the cathode water supply channel extends into the containing cavity, and the extending portion is provided with an air escape hole in a penetrating mode.

Preferably, the air outlet channel is detachably connected with the connecting part and the cup body is detachably connected with the fixing part.

Preferably, the air outlet channel is in threaded connection with the connecting portion and the cup body is in threaded connection with the fixing portion, and an axis of the air outlet channel is overlapped with an axis of the fixing portion.

Compared with the prior art, the utility model provides an ozone drinking cup through set the ozone that flows out the air outlet channel to in proper order through the air cavity with the piece gets into the cup body is cut apart to gas, wherein, the bore of air cavity is greater than the air outlet channel bore, the piece is cut apart to gas is including ventilative barrier film and perforated plate, ozone gas process ventilative barrier film with the bubbles of countless micron order are cut apart into to the perforated plate to the bubble of micron order is dissolved in aqueous, has increased the area of contact of ozone and water, has better dissolution efficiency, also is favorable to obtaining the ozone water of high concentration.

[ description of the drawings ]

FIG. 1 is an exploded view of an ozone cup provided by the present invention;

FIG. 2 is a schematic structural view of a middle shell in the ozone water cup shown in FIG. 1;

FIG. 3 is a schematic view showing the structure of a perforated plate in the ozone water cup shown in FIG. 1;

FIG. 4 is an assembled schematic view of the ozone cup of FIG. 1;

figure 5 is a cross-sectional view of the ozonated water cup of figure 4 taken along the direction a-a;

fig. 6 is an enlarged view of a portion a in the ozone water cup shown in fig. 5.

[ detailed description ] embodiments

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments. 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.

Referring to fig. 1 to 6, the ozone water cup includes a cup body 1, a cup holder 3 connected to the cup body 1, and an ozone generating mechanism 5 accommodated in the cup holder 3.

The cup holder 3 comprises a bottom shell 31 which is arranged at an interval with the cup body 1 and accommodates the ozone generating mechanism 5, and a middle shell 33 which is arranged between the cup body 1 and the bottom shell 31 and connected with the cup body 1.

The middle shell 33 comprises a fixing part 331 connected with the cup body 1, a partition plate 333 formed by extending inwards from the fixing part 331, and a connecting part 335 formed by extending from the partition plate 333 to the bottom shell 31, wherein an air dividing member 7 which forms an air cavity 3A by enclosing with the partition plate 333 is fixedly arranged on one side of the partition plate 333 away from the connecting part 335, and the connecting part 335 forms a through hole 33A communicated with the air cavity 3A by enclosing.

As shown in fig. 2 and 6, a protruding portion 337 is formed by protruding the partition plate 333 in a direction away from the bottom case 31 at a position between the fixing portion 331 and the connecting portion 335, an accommodating cavity 33B is formed by enclosing the protruding portion 337 and the fixing portion 331, the cup body 1 is inserted into the accommodating cavity 33B, and the periphery of the gas separator 7 is fixed to the protruding portion 337 so that the partition plate 333 and the gas separator 7 enclose the gas cavity 3A.

In order to improve the sealing and waterproof effects between the cup body 1 and the middle shell 33, in this embodiment, a sealing gasket 8 interposed between the cup body 1 and the partition plate 333 is provided in the accommodating chamber 33B.

In order to improve the sealing and waterproof effect between the gas separator 7 and the protrusion 337, in this embodiment, a sealing groove 339 is formed on a side of the protrusion 337 away from the bottom case 31, and a gasket 9 interposed between the gas separator 7 and the protrusion 337 is accommodated in the sealing groove 339.

In this embodiment, the gas separator 7 and the protrusion portion 337 are connected by a fastening member (not shown) penetrating the gas separator 7, the gasket 9 and the protrusion portion 337. Wherein, the fastener can be a combined structure of a bolt and a nut.

The gas separator 7 includes a gas-permeable barrier film 71 and a porous plate 73, the gas-permeable barrier film 71 is sandwiched between the porous plate 73 and the partition plate 333, and the porous plate 73 has a plurality of gas passages 731 communicating the gas chamber 3A and the cup body 1.

The air-permeable isolating membrane 71 can prevent water in the cup body 1 from flowing back to the anode water tank of the ozone generating mechanism 5, the porous plate 73 can support the air-permeable isolating membrane 71, and when ozone gas passes through the air-permeable isolating membrane 71 and the porous plate 73, the ozone gas is divided into countless micron-sized bubbles under the combined action of the air-permeable isolating membrane 71 and the porous plate 73, and the micron-sized bubbles are dissolved in the water in the cup body 1, so that the contact area between the ozone and the water is increased, the dissolving efficiency is better, and the obtaining of high-concentration ozone water is facilitated.

In the embodiment, the aperture of the air passage 731 is 5-20 μm. When the pore size of the gas passage 731 is less than 5 μm, there is a problem in that the ozone gas is discharged slowly, and when the pore size of the gas passage 731 is more than 20 μm, there is a problem in that the pore size of bubbles is too large, both of which affect the rate at which the ozone gas is dissolved in water.

As shown in fig. 6, the gas separator 7 has a flat plate structure, and it is understood that in other embodiments, the gas separator 7 may be provided in a curved shape, a truncated cone shape, a cone shape, or the like, which is advantageous for further increasing the contact area between the gas separator 7 and the ozone in the gas chamber 3A and the water in the cup body 1, so as to increase the speed of dissolving the ozone in the water.

The ozone generating mechanism 5 includes an ozone generator 51, and an anode water tank 53 and a cathode water tank 55 respectively communicated with the ozone generator 51.

The ozone generator 51 adopts a Polymer Electrolyte Membrane (PEM) electrolysis technology, and the ozone generator 51 performs electrolysis by using water as a raw material, generates oxygen and ozone at an anode thereof, and generates hydrogen at a cathode thereof. In this embodiment, the ozone generator 51 may use an electrolysis voltage of 3 to 6V.

The ozone generator 51 comprises an anode water inlet channel 511, an anode gas outlet channel 513, a cathode water inlet channel 515 and a cathode gas outlet channel 517.

The anode water tank 53 includes an air outlet channel 531 extending from the bottom shell 31 into the through hole 33A and connected to the connecting portion 335 in a sealing manner, an anode water outlet channel 533 connected to the anode water inlet channel 511, and an anode air inlet channel 535 connected to the anode water outlet channel 513. Ozone generated by the ozone generator 51 by electrolyzing water sequentially passes through the anode outlet channel 513, the anode inlet channel 535, the interior of the anode water tank 53, the air outlet channel 531, the air cavity 3A and the gas partitioning member 7 to enter the cup body 1 and be mixed with water to form ozone water.

In this embodiment, the aperture of the air cavity 3A is larger than the aperture of the air outlet channel 531.

It should be noted that, because ozone is corrosive, the anode water tank 55, the air-permeable isolating membrane 71, the porous plate 73, the cup body 1, the sealing gasket 8, the sealing gasket 9, etc. are all made of ozone-resistant materials. For example, the porous plate 73 may be made of titanium or stainless steel, and the gas-permeable separation film 71 may be EPTFE (EPTFE is a microporous film formed by expanding and stretching polytetrafluoroethylene).

The cathode water tank 55 comprises a cathode water replenishing channel 551, a cathode water outlet channel 553 communicated with the cathode water inlet channel 515, and a cathode air inlet channel 555 communicated with the cathode water outlet channel 517, wherein a sealing plug 557 is plugged in the cathode water replenishing channel 551. The hydrogen and the wastewater generated by the water electrolysis of the ozone generator 51 sequentially flow into the cathode water tank 55 through the cathode outlet channel 517 and the cathode inlet channel 555.

It is understood that a waste water discharge port may be further provided on the cathode water tank 55, so that waste water in the cathode water tank 55 may be discharged through the waste water discharge port.

In this embodiment, the anode inlet channel 511 and the anode outlet channel 533, the anode outlet channel 513 and the anode inlet channel 535, the cathode inlet channel 515 and the cathode outlet channel 553, and the cathode outlet channel 517 and the cathode inlet channel 555 are all connected by a pipeline (not shown).

In this embodiment, the air outlet channel 531 is detachably connected to the connecting portion 335 and the cup body 1 is detachably connected to the fixing portion 331. So that it is possible to facilitate the supply of water from the cathode water supply passage 551 and the air outlet passage 531 into the cathode water tank 55 and the anode water tank 55, respectively.

As shown in fig. 6, the air outlet channel 531 is connected to the connecting portion 335 and the cup body 1 is connected to the fixing portion 331 by screws, so that the assembly and disassembly are convenient. Wherein, the axis of the air outlet channel 531 and the axis of the fixing portion 331 overlap.

Furthermore, the middle housing 33 further includes an extension portion 336 formed by extending from the fixing portion 331 toward the bottom housing 31, the extension portion 336 forms a receiving cavity 33C by enclosing the bottom housing 31, the partition 333 and the connecting portion 335, the cathode water supply channel 551 extends into the receiving cavity 33C, and the extension portion 336 is provided with an air escape hole 33D. The provision of the air escape hole 33D prevents the ozone and the hydrogen gas from overflowing into the housing chamber 33C and exploding.

In this embodiment, the bottom case 31 is further fixedly provided with a heat dissipation fan 10. The cooling fan 10 may lower the temperature of the ozone generator 51 to increase the electrolysis rate of ozone.

A specific ozone cup was tested under the following conditions:

the working voltage of the ozone generator is 3-5V, and the working current is 12A;

the volume of water in the cup body is 300 ml.

Tests show that the ozone generator can generate high-concentration ozone water with the concentration of more than 10mg/L after working for 5 minutes, and can generate high-concentration ozone water with the concentration of 20mg/L after working for 10 minutes.

It should be noted that the ozone water prepared by the ozone water cup of the present invention can be used for drinking, disinfection, etc. according to the difference of the concentration.

The above embodiments of the present invention are only described, and it should be noted that, for those skilled in the art, modifications can be made without departing from the inventive concept, but these all fall into the protection scope of the present invention.

Claims (10)

1. The utility model provides an ozone drinking cup, its includes cup body, cup stand and ozone generation mechanism, ozone generation mechanism has air outlet channel, its characterized in that: the cup seat comprises a bottom shell which is arranged at an interval with the cup body and accommodates the ozone generating mechanism and a middle shell which is arranged between the cup body and the bottom shell, the middle shell comprises a fixed part connected with the cup body, a separation plate formed by extending inwards from the fixed part and a connecting part formed by extending from the separation plate to the bottom shell, one side of the partition board far away from the connecting part is fixedly provided with a gas partition piece which forms a gas cavity with the partition board, the connecting part is enclosed to form a through hole communicated with the air cavity, the air outlet channel extends into the through hole from the inside of the bottom shell and is hermetically connected with the connecting part, wherein the caliber of the air cavity is larger than that of the air outlet channel, the gas dividing piece comprises a porous plate and a breathable isolating membrane clamped between the porous plate and the partition plate, the porous plate is provided with a plurality of micron-sized air passages which are communicated with the space enclosed by the air cavity and the cup body.

2. The ozone water cup of claim 1, wherein: the aperture of the air passage is 5-20 microns.

3. The ozone water cup of claim 1, wherein: the separating plate is arranged between the fixing part and the connecting part and protrudes in the direction away from the bottom shell to form a protruding part, a containing cavity is formed by enclosing the protruding part and the fixing part, the cup body is inserted into the containing cavity, and the periphery of the gas dividing part is fixed to the protruding part.

4. The ozone water cup of claim 3, wherein: one side of the bulge part, which is far away from the bottom shell, is provided with a sealing groove, and a sealing gasket clamped between the breathable isolation film and the bulge part is accommodated in the sealing groove.

5. The ozone cup of claim 4, wherein: the gas dividing member and the boss are connected by a fastener penetrating through the gas dividing member, the gasket and the boss.

6. The ozone water cup of claim 3, wherein: the containing cavity is internally provided with a sealing gasket clamped between the cup body and the partition plate.

7. The ozone water cup of claim 1, wherein: ozone takes place the mechanism and includes ozone generator, positive pole water tank and negative pole water tank, ozone generator includes positive pole inlet channel, positive pole gas outlet channel, negative pole inlet channel and negative pole gas outlet channel, the positive pole water tank includes gas outlet channel, with the positive pole water outlet channel of positive pole inlet channel intercommunication and with the positive pole intake duct of positive pole gas outlet channel intercommunication, the negative pole water tank include negative pole water supply channel, with the negative pole water outlet channel of negative pole inlet channel intercommunication and with the negative pole intake duct of negative pole gas outlet channel intercommunication, wherein, negative pole water supply channel stopper has the sealing plug.

8. The ozone water cup of claim 7, wherein: the middle shell further comprises an extending part formed by extending from the fixing part to the bottom shell, the extending part, the bottom shell, the partition plate and the connecting part are enclosed to form a containing cavity, the cathode water replenishing channel extends into the containing cavity, and the extending part is provided with an air escape hole in a penetrating mode.

9. The ozone water cup of any one of claims 1-8, wherein: the air outlet channel is detachably connected with the connecting part and the cup body is detachably connected with the fixing part.

10. The ozone cup of claim 9, wherein: the air outlet channel is connected with the connecting part and the cup body is connected with the fixing part through threads, wherein the axis of the air outlet channel is overlapped with the axis of the fixing part.

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