CN220361170U - Water oxygen sol generating device - Google Patents

Abstract

The application discloses a water oxygen aerosol generating device includes: the water tank is suitable for containing water and forming an air chamber above the water surface, the wall of the water tank is provided with an air inlet and an air outlet, and the air inlet and the air outlet are both communicated with the air chamber; the discharging device is arranged on the wall of the water tank and comprises a discharging needle and a needle sleeve sleeved outside the discharging needle, the position of the needle sleeve sleeved on the discharging needle is adjustable, the discharging end of the discharging needle is exposed in the air chamber, and the discharging needle is suitable for discharging in the air chamber to generate ozone and negative oxygen ions; the atomizer is suitable for being immersed in water in the water tank, the atomizer atomizes the water in the water tank to form water mist so as to be mixed with air containing ozone and negative oxygen ions to form water oxygen sol, and the water oxygen sol is suitable for being released from the open air outlet to the outside of the water tank. The water-oxygen sol generating device can generate ozone and negative oxygen ions simultaneously, so that the structure is simplified, the proportion of the ozone to the negative oxygen ions is adjustable, the water-oxygen sol generating device is suitable for different requirements, and the effective acting time of the ozone and the negative oxygen ions can be prolonged.

Description

Water oxygen sol generating device

Technical Field

The application relates to the technical field of water-oxygen sol generating devices, in particular to a water-oxygen sol generating device.

Background

The negative oxygen ions can promote the synthesis and storage of vitamins, strengthen and activate the physiological activities of human bodies, and effectively activate oxygen molecules in the air, so that the negative oxygen ions are more active and are easier to be absorbed by the human bodies, and the air conditioning disease can be effectively prevented. The ozone has a plurality of beneficial functions, such as food purification, drinking water purification, disinfection and sterilization, air purification, fresh-keeping and mildew-proof of fruits and vegetables, and the like, and can also be used for deodorization.

In view of the beneficial effects of negative oxygen ions and ozone, a purifying device is designed, in the purifying device, the negative oxygen ions generating structure and the ozone generating structure are independently arranged, the structure is complex, and the generating proportion of the ozone and the negative oxygen ions is not adjustable, so that the purifying device cannot adapt to different requirements, in addition, the ozone and the negative oxygen ions are directly discharged to the air, and the effective acting time of the ozone and the negative oxygen ions in the air is short.

Disclosure of Invention

Therefore, the technical problem to be solved by the application is to overcome the defects that the negative oxygen ion generating structure and the ozone generating structure in the prior art are independently arranged, the structure is complex, the proportion of the negative oxygen ion to the ozone is not adjustable, and the negative oxygen ion and the ozone are directly discharged in the air to cause the effective action time to be shorter, so that the water-oxygen sol generating device is provided.

In order to solve the technical problems, the technical scheme of the application is as follows:

a water-oxygen sol generating device comprising:

the water tank is suitable for containing water and forming an air chamber above the water surface, the wall of the water tank is provided with an air inlet and an air outlet, and the air inlet and the air outlet are both communicated with the air chamber;

the discharging device is arranged on the wall of the water tank and comprises a discharging needle and a water absorbing needle sleeve sleeved outside the discharging needle, the position of the water absorbing needle sleeve sleeved outside the discharging needle is adjustable, the discharging end of the discharging needle is exposed in the air chamber, and the discharging needle is suitable for discharging in the air chamber to generate ozone and negative oxygen ions;

the atomizer is suitable for being immersed in water in the water tank, the atomizer atomizes the water in the water tank to form water mist so as to be mixed with air containing ozone and negative oxygen ions to form water oxygen sol, and the water oxygen sol is suitable for being released to the outside of the water tank from the open air outlet.

Further, the discharge needle is a capillary and the surface of the discharge needle is hollow.

Further, the included angle between the discharge needle and the horizontal direction is not smaller than 45 degrees.

Further, the root of the discharge needle is provided with an air-filling hole.

Further, the water absorbing needle sleeve is made of porous materials and is suitable for absorbing moisture in the air.

Further, the fog outlet of the atomizer is positioned 2-3cm below the water surface.

Further, the atomizer is an ultrasonic atomizer.

Further, the water tank is further provided with an air pump, the air pump is positioned in the water tank, an air inlet of the air pump is positioned in the air chamber, an air outlet of the air pump is immersed in water in the water tank, and the air pump is suitable for pumping the air pump containing ozone and negative oxygen ions in the air chamber into the water.

Further, an air outlet of the air pump is connected with fine bubble stones with single-side air outlet.

Further, the fine bubble stone is arranged at the bottom of the water tank, an included angle between the bottom non-air outlet surface of the fine bubble stone and the bottom of the water tank is 5-75 degrees, and an included angle between the bottom non-air outlet surface of the fine bubble stone and the side wall of the water tank is 5-75 degrees.

The technical scheme of the application has the following advantages:

1. the utility model provides a water oxygen sol generating device, the needle cover that absorbs water cup joints outside the needle that absorbs water in the air chamber, and store in the needle cover that absorbs water, discharge needle switch on behind the high voltage power supply in the air chamber, discharge to the air and produce ozone, produce negative oxygen ion to the water discharge that comes from in the needle cover that absorbs water, in this way, a discharging device can produce the active particle including ozone and negative oxygen ion simultaneously, compare ozone generating structure and negative oxygen ion generating structure in the prior art and set up alone, ozone and negative oxygen ion generating structure has been simplified, moreover, because the needle cover that absorbs water cup joints the position adjustable outside the needle that absorbs water for the ratio of ozone and negative oxygen ion that produces is adjustable, adaptable different demands, in addition, the atomizer can form water smoke with the air mixing that contains ozone and negative oxygen ion with the water oxygen ion in the water tank, in this way, can prolong ozone and negative oxygen ion at the effective action time of target area.

2. The utility model provides a water oxygen aerosol's generating device, discharging device's discharge needle is capillary and surface is the fretwork form for discharging needle's setting angle is not limited to discharging end vertical downwards, and then can improve discharging needle setting angle's adaptability, in addition, the needle cover that absorbs water is made for porous material, can uninterruptedly adsorb the moisture in the air and store in the needle cover, guarantees discharging device's required water source's stability, improves the convenience of acquireing the water source.

3. The utility model provides a generating device of water oxygen aerosol, fine bubble stone is connected to the air pump gas outlet, and fine bubble stone arranges the bottom of water tank in, and the contained angle between the bottom of fine bubble stone and the bottom of water tank is 5 degrees to 75 degrees, and the contained angle between the side wall of fine bubble stone bottom and the water tank is 5 degrees to 75 degrees, so, the bubble will form helical motion in water after coming out from fine bubble stone, the motion track in water is longer, ozone and negative oxygen ion are longer with water contact time, the dissolution effect is better.

Drawings

In order to more clearly illustrate the embodiments of the present application or the technical solutions in the prior art, the drawings that are needed in the description of the embodiments or the prior art will be briefly described below, and it is obvious that the drawings in the following description are some embodiments of the present application, and other drawings may be obtained according to these drawings without inventive effort for a person skilled in the art.

FIG. 1 is a schematic perspective view of a water-oxygen sol generating device of the present embodiment;

fig. 2 is a perspective schematic view of a water tank upper cover in which a discharge device is installed in the present embodiment;

FIG. 3 is a schematic perspective view of the outlet cover in this embodiment;

FIG. 4 is a schematic perspective view of the air inlet in the present embodiment;

FIG. 5 is a schematic perspective view of the discharging device in the present embodiment;

FIG. 6 is a schematic perspective view of the needle hub of the present embodiment;

FIG. 7 is a schematic perspective view of the discharge needle in this embodiment;

fig. 8 is a perspective schematic view of the air pump in the present embodiment.

Reference numerals illustrate:

A. a water tank; B. a discharge device; C. an atomizer; D. an air pump; E. fine bubble stones; 1. a metal sheet; 2. a discharge needle; 21. a through hole; 22. an air supplementing hole; 23. root part; 24. a discharge end; 3. a water-absorbing needle sleeve; 4. an upper cover; 41. an air inlet; 43. a cover; 44. an air chamber.

Detailed Description

The following description of the embodiments of the present application will be made apparent and fully in view of the accompanying drawings, in which some, but not all embodiments of the utility model are shown. All other embodiments, which can be made by one of ordinary skill in the art without undue burden from the present disclosure, are within the scope of the present disclosure.

In the description of the present application, it should be noted that the directions or positional relationships indicated by the terms "center", "upper", "lower", "left", "right", "vertical", "horizontal", "inner", "outer", etc. are based on the directions or positional relationships shown in the drawings, are merely for convenience of description of the present application and to simplify the description, and do not indicate or imply that the devices or elements referred to must have a specific orientation, be configured and operated in a specific orientation, and thus should not be construed as limiting the present application. Furthermore, the terms "first," "second," and "third" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance.

In the description of the present application, it should be noted that, unless explicitly specified and limited otherwise, the terms "mounted," "connected," and "connected" are to be construed broadly, and may be either fixedly connected, detachably connected, or integrally connected, for example; can be mechanically or electrically connected; can be directly connected or indirectly connected through an intermediate medium, and can be communication between two elements. The specific meaning of the terms in this application will be understood by those of ordinary skill in the art in a specific context.

In addition, the technical features described below in the different embodiments of the present application may be combined with each other as long as they do not collide with each other.

Examples

As shown in fig. 1 to 8, the present embodiment provides a water-oxygen sol generating device including a water tank a, a discharge device B, an atomizer C, and an air pump D.

The tank a is adapted to hold water and form a plenum 44 above the water surface. The wall of the water tank A is provided with an air inlet 41 and an air outlet (not marked), the air inlet 41 and the air outlet are both communicated with an air chamber 44, and the total sectional area of the air outlet is larger than that of the air inlet 41. The air inlet 41 provides a passage for external air to enter the air chamber 44, and the air outlet provides a passage for water-oxygen sol in the air chamber 44 to be released to the outside of the water tank A. In this embodiment, the water tank a is provided with an upper cover 4, the air inlet 41 and the air outlet are both opened on the upper cover 4, the air outlet upper cover is provided with a cover 43, and the cover 43 is in a normally closed state, however, the water tank a can also be set in a normally open state, and the air outlet is closed by covering the cover 43 when preparing the water-oxygen sol. The air inlet 41 is an air inlet 41 of a venturi structure, and is in a normally open state, and an air supplementing device (not shown) supplements air into the air chamber 44 along the air inlet duct via the air inlet 41. When the cover 43 on the air outlet is in a closed state, the air chamber 44 can only communicate with the outside through the air inlet 41, and air can only enter the air chamber 44 from the air inlet 41 and cannot flow outwards from the air chamber 44 through the air inlet 41, so that leakage of water and oxygen sol is avoided.

The discharge device B is arranged on the wall of the water tank A. The discharging device B comprises a discharging needle 2 and a water absorbing needle sleeve 3 sleeved outside the discharging needle 2, the position of the water absorbing needle sleeve 3 sleeved outside the discharging needle 2 is adjustable (for example, the position is adjusted by a moving mechanism or an elastic mechanism and a control switch), and the discharging end of the discharging needle 2 is exposed in the air chamber 44. After the discharge needle 2 is connected with high-voltage electricity, ozone is generated by discharging air, and negative oxygen ions are generated by discharging water from the water-absorbing needle sleeve 3. The discharge needle 2 can protrude out of the water-absorbing needle sleeve 3 or can be hidden into the water-absorbing needle sleeve 3, but in any case, the discharge end of the discharge needle 2 is exposed to the air. Because the position of the water absorbing needle sleeve 3 sleeved outside the discharge needle 2 is adjustable, the adjustment of ozone output is realized without periodical on-off control or periodical high-low voltage output change on the high-voltage package, so that the design difficulty of the high-voltage package in transformation is reduced, and the risk of the high-voltage package caused by overcurrent impact caused by output voltage change in operation is also reduced. In addition, the position of the water absorbing needle sleeve 3 sleeved outside the discharge needle 2 is adjustable, after the distance that the discharge end of the discharge needle 2 extends out of the water absorbing needle sleeve 3 or the distance that the discharge end is hidden into the water absorbing needle sleeve 3 is changed, the generation proportion of ozone and negative oxygen ions can be adjusted to meet different requirements, but no matter how the ozone is adjusted, ozone can be generated.

Of course, the discharging device B may be provided with a plurality of discharging needles 2, in which case, the plurality of discharging needles 2 need to be connected together by means of the strip-shaped metal sheet 1, and the high voltage electricity is directly applied to the metal sheet 1.

The discharge needle 2 is made of an electrically conductive material, but may be made of a non-conductive material, and is coated with an electrically conductive coating on the outer surface or the inner and outer surfaces. In this embodiment, the discharge needle 2 is hollow and is a capillary, and the surface of the discharge needle 2 has a plurality of through holes 21 to form a hollow shape. One end of the discharge needle 2 is connected to the metal sheet 1, and the end far away from the metal sheet 1 is a discharge end 24. The portion of the discharge needle 2 adjacent to the metal sheet 1 and exposed to the water absorbing needle cover 3 is referred to as a root 23 of the discharge needle 2, and the root 23 of the discharge needle 2 is provided with an air supply hole 22 adapted to supply air into the discharge needle 2 through the air supply hole 22, thereby forming an air circulation in the hollow discharge needle 2. The form of the air supply hole 22 may be different from that of the through hole 21, or may be the same as that of the through hole 21.

The water absorbing needle sheath 3 is made of a porous material, and the moisture in the air chamber 44 is absorbed without interruption by utilizing the porous property, and the moisture is stored in the water absorbing needle sheath 3. Hydrophilic materials can be added into the porous material of the water-absorbing needle sleeve 3 to increase the hydrophilic performance of the water-absorbing needle sleeve 3 and improve the capability of the water-absorbing needle sleeve 3 for absorbing moisture in air. Of course, the hydrophilic coating may be directly applied to the surface of the water-absorbing needle sheath 3. The water absorbing needle sleeve 3 is sleeved outside the discharge needle 2, and the inner wall of the water absorbing needle sleeve 3 is contacted with the outer wall of the discharge needle 2. The water absorbed by the water absorbing needle cover 3 enters the inner wall of the discharge needle 2 through the through hole 21 and flows towards the discharge end 24 under the siphon action of the capillary tube.

In this embodiment, the operation of the discharging device B is as follows:

the water absorbing needle sleeve 3 continuously absorbs the water in the air chamber 44 and stores the water in the water absorbing needle sleeve 3;

the water in the water absorbing needle sleeve 3 enters the inner wall of the discharge needle 2 from the through hole 21 on the discharge needle 2 to form a water film, and flows towards the discharge end 24 under the siphon action of the capillary tube;

the high-voltage electricity is loaded on the discharge needle 2 through the metal sheet 1, the discharge end 24 of the discharge needle 2 discharges air to generate ozone, and negative oxygen ions are generated by discharging water from the water-absorbing needle sleeve 3; of course, in this process, air needs to be supplemented into the discharge needle 2 through the air supplementing holes 22 on the capillary outside the water absorbing needle cover 3, so that air circulation is formed to continuously supplement air.

In the discharging device B in the embodiment, the water in the air is absorbed by the water absorbing needle sleeve 3 made of the porous material, the water is stored in the water absorbing needle sleeve 3, the water source required by high-pressure ionized water is ensured, the convenience of water source acquisition is improved, the yield of negative oxygen ions is further ensured, and the generated negative oxygen ions are more than the negative oxygen ions generated by coating the porous water absorbing material outside the solid discharging needle 2. This is because, compared with the solid needle, a layer of water film is added in the capillary tube, and the amount of negative oxygen ions generated by the water film cannot be provided by the solid needle. In addition, since the discharge needle 2 is a capillary, water flows in the capillary by means of siphoning, so that the placement position of the discharge needle 2 in the capillary form is not limited to the vertical downward placement of the discharge end, and further, the placement angle adaptation performance of the discharge needle 2 in the capillary form can be improved, and the included angle of the discharge needle 2 in the capillary form relative to the horizontal direction is not less than 45 degrees.

The air pump D is positioned in the water tank A, the air inlet 41 of the air pump D is positioned in the air chamber 44, the air outlet is immersed in the water tank A, and the air outlet of the air pump D is connected with the fine bubble stone E with single-sided air outlet. The bottom of water tank A is arranged in to fine bubble stone E, and the bottom of fine bubble stone E does not go out the contained angle between face and the bottom of water tank A and is 5 degrees to 75 degrees, and the bottom of fine bubble stone E does not go out the contained angle between face and the lateral wall of water tank A and is 5 degrees to 75 degrees, so, the bubble will form helical motion in water after coming out from fine bubble stone E, and the motion track in water is longer, and ozone and negative oxygen ion are longer with water contact time, and the dissolution effect is better. The air pump D pumps the air containing ozone and negative oxygen ions into the water, so that the decomposition speed of the ozone and the negative oxygen ions can be reduced and the service lives of the ozone and the negative oxygen ions can be prolonged as compared with the case that the ozone and the negative oxygen ions are directly released into the air when the air pump D pumps the air containing the ozone and the negative oxygen ions into the water. The air pump D may be selectively turned off according to the actual situation, and at this time, ozone and negative oxygen ions in the air chamber 44 will not be pumped into the water.

The atomizer C is immersed in water in the water tank A, the atomizer C is suitable for atomizing water containing ozone and negative oxygen ions in the water tank A into water mist containing the ozone and the negative oxygen ions to be mixed with air in the air chamber to form water oxygen sol, and the water oxygen sol is suitable for being released to the outside of the water tank A along the air outlet channel from the open air outlet. Under the condition that the air pump D is not started, the atomizer C atomizes water in the water tank A into water mist, the water mist enters the air chamber 44 and is mixed with air containing ozone and negative oxygen ions in the air chamber 44 to form water-oxygen sol. In the embodiment, the atomizer C is an ultrasonic atomizer, and the mist outlet of the atomizer C is positioned 2-3cm below the water surface so as to achieve a better atomization effect. Preferably, a buoy is added at the other end of the air inlet 41 of the atomizer C, so that on one hand, the atomizer C can be controlled to be always at the liquid level depth with the best atomization effect, and on the other hand, the atomizer C can be used as a buoy to mark the upper water level and the lower water level, so that the working water level interval of the atomizer C is limited, and the safety is ensured.

By way of supplementary explanation, in this embodiment, the air supplementing device supplements air into the air chamber 44 along the air inlet channel via the air inlet 41, forces the water-oxygen sol in the air chamber 44 to release outwards along the air outlet channel via the open air outlet, so that no aerodynamic device is provided in the water tank a.

Of course, in the actual use process, the water-absorbing needle sleeve 3 can be removed from the discharge needle 2, the discharge needle 2 is a bare needle, and after the discharge device B is connected with high-voltage electricity, the discharge needle 2 ionizes air to generate ozone.

In this embodiment, the water absorbing needle sleeve 3 is sleeved outside the discharging needle 2, the water absorbing needle sleeve 3 can absorb the water in the air chamber 44 above the water surface in the water tank a and store the water in the water absorbing needle sleeve 3, the discharging needle 2 is connected with high voltage and then discharges in the air chamber 44, ozone is generated by discharging air, negative oxygen ions are generated by discharging water from the water absorbing needle sleeve 3, so that one discharging device can simultaneously generate active particles comprising ozone and the negative oxygen ions.

It is apparent that the above examples are given by way of illustration only and are not limiting of the embodiments. Other variations or modifications of the above teachings will be apparent to those of ordinary skill in the art. It is not necessary here nor is it exhaustive of all embodiments. While nevertheless, obvious variations or modifications may be made to the embodiments described herein without departing from the scope of the utility model.

Claims (10)

1. A water-oxygen sol generating device, comprising:

the water tank (A) is suitable for containing water and forming an air chamber (44) above the water surface, an air inlet (41) and an air outlet are formed in the wall of the water tank (A), and the air inlet (41) and the air outlet are both communicated with the air chamber (44);

the discharging device (B) is arranged on the wall of the water tank (A) and comprises a discharging needle (2) and a water absorbing needle sleeve (3) sleeved outside the discharging needle (2), the position of the water absorbing needle sleeve (3) sleeved outside the discharging needle (2) is adjustable, the discharging end (24) of the discharging needle (2) is exposed in the air chamber (44), and the discharging needle (2) is suitable for discharging in the air chamber (44) to generate ozone and negative oxygen ions;

the atomizer (C) is suitable for being immersed in water in the water tank (A), the atomizer (C) atomizes the water in the water tank (A) to form water mist so as to be mixed with air containing ozone and negative oxygen ions to form water oxygen sol, and the water oxygen sol is suitable for being released from the open air outlet to the outside of the water tank (A).

2. The water-oxygen sol generating device according to claim 1, wherein the discharge needle (2) is a capillary tube and has a hollowed-out surface.

3. The water-oxygen sol generating device according to claim 1, wherein the angle between the discharge needle (2) and the horizontal direction is not less than 45 degrees.

4. The water-oxygen sol generating device according to claim 1, characterized in that the root (23) of the discharge needle (2) is provided with an air-filling hole (22).

5. The water-oxygen sol generating device according to claim 1, characterized in that the water-absorbing needle sheath (3) is made of a porous material, adapted to absorb moisture in the air.

6. The water-oxygen sol generating device according to claim 1, wherein the mist outlet of the atomizer (C) is located 2-3cm below the water surface.

7. The water-oxygen-sol generating device according to claim 1, characterized in that the atomizer (C) is an ultrasonic atomizer.

8. The water-oxygen-sol generating device according to any one of claims 1-7, further comprising an air pump (D), said air pump (D) being located in said water tank (a), an air inlet (41) of said air pump (D) being located in said air chamber (44), an air outlet being submerged in the water in said water tank (a), said air pump (D) being adapted to pump the air pump containing ozone and negative oxygen ions in said air chamber (44) into the water.

9. The water-oxygen sol generating device according to claim 8, wherein the air outlet of the air pump (D) is connected with a fine bubble stone (E) with single-sided air outlet.

10. The water aerosol generating device according to claim 9, wherein the fine bubble stone (E) is disposed at the bottom of the water tank (a), an angle between a bottom non-air outlet surface of the fine bubble stone (E) and the bottom of the water tank (a) is 5 degrees to 75 degrees, and an angle between a bottom non-air outlet surface of the fine bubble stone (E) and a side wall of the water tank (a) is 5 degrees to 75 degrees.