CN213243114U - Hydrated negative oxygen ion generating device - Google Patents

Abstract

The utility model relates to a hydrated negative oxygen ion produces device, including base, anion needle and can produce the water smoke of water smoke and take place the subassembly, the inside cavity of base forms the ion take place the chamber, the anion needle is located during the ion takes place the chamber, the output port that the subassembly was taken place to the water smoke takes place the chamber with the ion and is linked together, the at least part of base lateral wall leans out gradually from bottom to top, it has the air feed to get into the input port in the ion takes place the chamber to open on the lateral wall of base slope, it has the opening that supplies water smoke input ion to take place in the chamber to open on the base diapire, open at the base top has the delivery outlet that supplies the output of water to close. Set up the input port that the slope was arranged, when the air flowed from bottom to top, the entering ion that can be easier, rapid took place the chamber to improve the oxygen concentration in the ion emergence chamber, simultaneously, the water smoke upwards diffuses from the base bottom under the air current drives, thereby is favorable to the water smoke to produce the hydrated negative oxygen ion of high concentration with negative oxygen ion parcel fast, thereby improves air purification effect.

Description

Hydrated negative oxygen ion generating device

Technical Field

The utility model relates to an air purification technical field specifically indicates a hydrated negative oxygen ion produces device.

Background

As society develops and environments become polluted, air cleaners are becoming more familiar, and in general, air cleaners absorb polluted ambient air, purify the absorbed air, and discharge clean air to the outside, thereby purifying air in the area around the air cleaners. The negative ions (negative oxygen ions) are gas ions with negative charges in the air, and according to the regulations of the world health organization, when the concentration of the negative oxygen ions in the air is not less than 1000-1500 per cubic centimeter, the air is regarded as fresh air. Therefore, the module capable of generating negative oxygen ions is arranged in the air purifier, so that the air purification effect is improved.

The Chinese patent application with the application publication number of CN105526640A, namely 'a double-power-supply driven anion air purifier' (application number of CN201610023392.2) and the Chinese patent application with the application number of CN105650752A, namely 'a purifying device with an integrated ion air purifying system' (application number of CN201610001146.7) are both provided with anion generating modules, wherein the anion generating modules mainly adopt a sharp corona discharge mode to generate anions, and then directly blow out the anions through a fan. Chinese patent No. CN101214390B entitled "negative ion generating device" (application number: cn200810010137.x) discloses a more specific structure similar to negative ion generation, which includes a base, a casing assembled on the base, needle strips of homopolar discharge needles fixed between a partition and a window grid and arranged at equal intervals vertically, and a control loop, wherein the casing is composed of a rear shell and a front shell, the window grid is movably connected with the rear shell, the homopolar tungsten alloy discharge needles arranged at equal intervals vertically are fixed between the needle strips and a pressing plate by a one-time packaging process, carbon fibers fixed on the needle strips are communicated with the small high-pressure blocks, a closed carbon fiber ring is arranged in an annular groove at the periphery of the needle strips, the high-pressure block components fixed in the casing are packaged in a shielding case, and the base and the casing are hinged together by a rotary positioning device.

The above-mentioned anion produces principle and structure and is more mature, but, the anion life-span that produces with the corona discharge mode is very short, will disappear very soon, can't carry out long-distance propagation, hardly builds the anion environment of high concentration in big space. In life, people feel fresh air after thunderstorm and beside waterfall, because a large amount of 'hydrated negative oxygen ions' exist in the air, and the negative ions are O₂ ^-(H₂O)_nThe form has a half-life period of 60s, the hydrated negative oxygen ions have longer life, and the rapid propagation is expected to improve the indoor environment. Therefore, it is necessary to provide an air purification device capable of generating hydrated negative oxygen ions. Meanwhile, in order to improve the air purification effect, it is also necessary to increase the concentration of the hydrated negative oxygen ions.

SUMMERY OF THE UTILITY MODEL

The utility model aims to solve the technical problem that the current situation of the prior art is aimed at, and a hydrated negative oxygen ion generating device capable of generating high-concentration hydrated negative oxygen ions is provided.

The utility model provides a technical scheme that above-mentioned technical problem adopted does: the utility model provides a hydrated negative oxygen ion generating device, includes that base, anion needle and can produce the water smoke of water smoke and take place the subassembly, the inside cavity of base forms the ion generation chamber, the anion needle is located in the ion generation chamber, the output port and the ion generation chamber of subassembly are linked together, its characterized in that take place for the water smoke: at least part of base lateral wall leans out gradually from bottom to top, it has the input port that supplies the air to get into in the ion generation chamber to open on the lateral wall of base slope, it has the opening that supplies water smoke input ion generation chamber to open on the base diapire, open at the base top has the delivery outlet that supplies to close negative oxygen ion output.

Preferably, the upper part of the water mist generating assembly is arranged corresponding to the opening, and the bottom wall of the base is gradually inclined downwards from the outer edge to the opening to form a flow guide surface capable of guiding the condensed water downwards so as to flow back to the water mist generating assembly. The structure is convenient for the backflow reuse of condensed water generated by water mist in the anion cavity, and the problem of short circuit caused by excessive condensed water is avoided.

Preferably, the bottom wall of the base extends downwards from the edge of the opening to form an assembly sleeve, the assembly sleeve is connected with the flow guide surface through a flow guide arc surface in smooth transition, and the upper part of the water mist generation assembly extends into the assembly sleeve from bottom to top. The structure is favorable for further improving the backflow effect of the condensed water.

In each of the above schemes, the top of the water mist generating assembly is provided with a water mist output port, the output port is arranged corresponding to the opening, and the side wall of the upper part of the water mist generating assembly is provided with a backflow structure for backflow of condensed water in the assembly set to the water mist generating assembly. Above-mentioned structure is convenient for carry the water smoke, and the reflux structure is favorable to improving the comdenstion water backward flow effect.

The water mist generation assembly comprises a water tank, an ultrasonic atomization piece and a water absorption piece, the water tank is detachably arranged below the base, the ultrasonic atomization piece is located at the top of the assembly sleeve and is connected with the water tank through the water absorption piece, the water absorption piece is restrained at the lower port of the assembly sleeve through the assembly seat and covers the lower port, and the backflow structure is a backflow port arranged on the side wall of the assembly seat.

Preferably, a circuit board is arranged below the base, the lower end of the negative ion needle is connected to the circuit board, and the upper end of the negative ion needle extends to the input port. As a setting scheme of the negative ion needle, the upper part of the negative ion needle passes through the bottom wall of the base and is vertically arranged in the negative ion generating cavity and close to the input port; as another arrangement scheme of the negative ion needle, the upper part of the negative ion needle is bent upwards in an inclined way, and the upper end of the negative ion needle is arranged close to the lower edge of the input port. The structure enables the negative ions excited by the negative ion needle to rapidly enter a high-humidity and high-oxygen environment, so that high-concentration hydrated negative oxygen ions are generated.

Preferably, the top of the base is provided with a top cover detachably connected with the base, the output port is arranged on the top cover, the lower wall surface of the top cover is provided with a flow guide rib gradually extending downwards from the edge to the middle, and the lower end of the flow guide rib is arranged corresponding to the inner edge of the opening. This structure is favorable to further improving the backward flow effect of comdenstion water, avoids the condensation water droplet that the wall formed under the top cap to drop on ultrasonic atomization piece and influence the water smoke and produce the effect.

Further preferably, the lower wall surface of the top cover is provided with a baffle corresponding to the opening, the edge of the baffle is provided with an arc-shaped flow guide strip which gradually arches upwards from the edge to the middle, and the lower end of the flow guide strip is connected with the lower end of the flow guide rib. The baffle is arranged right opposite to the ultrasonic atomization sheet, so that water mist is uniformly dispersed in the ion generation cavity, the water drops condensed by the water mist can be guided to the opening edge to flow back by the guide strips, and the phenomenon that the condensed water drops formed on the lower wall surface of the top cover fall on the ultrasonic atomization sheet to influence the water mist to generate an effect is avoided.

Compared with the prior art, the utility model has the advantages of: the utility model discloses set up the input port in ion generation chamber on the base lateral wall of slope, when the air flows from bottom to top, can be easier, rapid entering ion generation chamber to improve the oxygen concentration in ion generation chamber, simultaneously, the water smoke is from the base bottom diffusion that makes progress under the air current drives, thereby is favorable to the water smoke to wrap up the hydrated negative oxygen ion that produces high concentration with negative oxygen ion fast, thereby improves the air purification effect.

Drawings

Fig. 1 is a schematic structural diagram of embodiment 1 of the present invention;

FIG. 2 is a cross-sectional view of FIG. 1;

fig. 3 is a schematic structural view of a base in embodiment 1 of the present invention;

fig. 4 is a schematic structural view of a top cover in embodiment 1 of the present invention;

fig. 5 is a partial sectional view of embodiment 2 of the present invention.

Detailed Description

The present invention will be described in further detail with reference to the following embodiments.

Example 1:

as shown in fig. 1 to 4, the hydrated negative oxygen ion generating device of the present embodiment includes a base 1, a negative ion needle 2 and a water mist generating assembly 3 capable of generating water mist, the base 1 is hollow to form an ion generating chamber 10, the negative ion needle 2 is disposed in the ion generating chamber 10, and an output port 30 of the water mist generating assembly 3 is communicated with the ion generating chamber 10.

The lower part of the side wall of the base 1 is gradually inclined outwards from bottom to top, an input port 12 for air to enter the ion generating cavity 10 is arranged on the inclined side wall 11 of the base 1, and the negative ion needle 2 is arranged close to the input port 12. An opening 13 for inputting water mist into the ion generating cavity 10 is arranged on the bottom wall of the base 1, and an output port 14 for outputting water-closing negative oxygen ions is arranged on the top of the base 1.

The upper part of the water mist generating assembly 3 is arranged corresponding to the opening 13, and the bottom wall of the base 1 is gradually inclined downwards from the outer edge to the opening 13 to form a flow guide surface 15 which can guide condensed water downwards so as to flow back to the water mist generating assembly 3. The structure is convenient for the backflow and reuse of condensed water generated by water mist in the anion cavity 10, and the problem of short circuit caused by excessive condensed water is avoided. The bottom wall of the base 1 extends downwards from the edge of the opening 13 to form an assembly sleeve 16, the assembly sleeve 16 is connected with the flow guide surface 15 through a flow guide arc surface 151 in smooth transition, and the upper part of the water mist generation assembly 3 extends into the assembly sleeve 16 from bottom to top so as to improve the backflow effect of condensed water.

Specifically, the top of the water mist generating assembly 3 is provided with a water mist outlet port 30, the outlet port 30 is arranged corresponding to the opening 13, and a backflow structure for backflow of condensed water in the assembling sleeve 16 to the water mist generating assembly 3 is arranged on the side wall of the upper part of the water mist generating assembly 3. The water mist generating assembly 3 of the embodiment comprises a water tank 31, an ultrasonic atomizing sheet 32 and a water absorbing member 33, wherein the bottom of the base 1 is provided with an assembly seat 5, the assembly seat 5 is provided with an installation bin 51, and a circuit board 4 for controlling the operation of the hydrated negative oxygen ion generating device is arranged in the installation bin 51.

The water tank 31 is in threaded connection with the bottom of the assembly seat 5, the ultrasonic atomization sheet 32 is located on the top of the assembly sleeve 16 and is connected with the water tank 31 through the water absorption piece 33, the water absorption piece 33 is constrained at the lower port of the assembly sleeve 16 through the assembly seat 34 and covers the lower port, the assembly seat 34 is fixed on the bottom wall of the assembly seat 5 through screws, and the backflow structure is a backflow port 341 formed in the side wall of the assembly seat 34.

In the present embodiment, the lower end of the negative ion needle 2 is connected to the circuit board 4, and the upper portion of the negative ion 2 passes through the bottom wall of the base 1 and is vertically arranged in the negative ion generating chamber 10 and close to the input port 12.

The top of the base 1 of this embodiment has a top cover 17 detachably connected thereto by a plug-in structure, and the outlet 14 is opened in the top cover 17. The lower wall surface of the top cover 17 is provided with a flow guiding rib 171 which gradually extends downwards from the edge to the middle, and the lower end of the flow guiding rib 171 is arranged corresponding to the inner edge of the opening 13. This structure is favorable to further improving the backward flow effect of comdenstion water, avoids the comdenstion water droplet that the wall formed under top cap 17 to drop on ultrasonic atomization piece 32 and influence water smoke production effect. The lower wall surface of the top cover 17 is provided with a baffle 172 at the position corresponding to the opening 13, the edge of the baffle 172 is provided with an arc-shaped flow guide strip 173 gradually arched upwards from the edge to the middle, and the lower end of the flow guide strip 173 is connected with the lower end of the flow guide rib 172. The baffle 172 is arranged right opposite to the ultrasonic atomization sheet 32, so that water mist is uniformly dispersed in the ion generation cavity 10, the diversion strips 173 can guide water drops condensed by the water mist to flow back to the edge of the opening 13, and the phenomenon that condensed water drops formed on the lower wall surface of the top cover 17 fall on the ultrasonic atomization sheet 32 to influence the water mist generation effect is avoided.

In this embodiment, the input port 12 of the ion generating chamber 10 is opened on the inclined sidewall 11 of the base, so that air can flow from bottom to top more easily and rapidly into the ion generating chamber 10, thereby increasing the oxygen concentration in the ion generating chamber, and being suitable for air flowing from bottom to top in an air purifier. Meanwhile, the water mist is driven by the airflow to upwards diffuse from the bottom of the base 1, so that the water mist can fast wrap the negative oxygen ions 2 to generate high-concentration hydrated negative oxygen ions, and the air purification effect is improved.

Example 2:

this example differs from example 1 only in that: as shown in fig. 5, the upper portion of the negative ion needle 2 'in this embodiment is bent obliquely upward to be disposed close to the lower edge of the input port 12' at the upper end. The structure enables the negative ions excited by the negative ion needle 2' to rapidly enter a high-humidity environment along with the outside air, thereby generating high-concentration hydrated negative oxygen ions.

Claims (10)

1. The utility model provides a hydration negative oxygen ion produces device, includes base (1), anion needle (2) and can produce water smoke generation assembly (3) of water smoke, base (1) inside cavity forms ion generation chamber (10), anion needle (2) are located in ion generation chamber (10), output port (30) and the ion generation chamber (10) of water smoke generation assembly (3) are linked together, its characterized in that: at least part of base (1) lateral wall leans out gradually from bottom to top, it has input port (12) that supply the air to get into in ion generation chamber (10) to open on lateral wall (11) of base slope, it has opening (13) that supply water smoke input ion generation chamber (10) to open on base (1) diapire, open at base (1) top has delivery outlet (14) that supply the output of hydrated negative oxygen ion.

2. The hydrated negative oxygen ion generating device of claim 1, wherein: the upper part of the water mist generating assembly (3) is arranged corresponding to the opening (13), and the bottom wall of the base (1) is gradually inclined downwards from the outer edge to the opening (13) to form a flow guide surface (15) capable of guiding condensed water downwards so as to enable the condensed water to flow back to the water mist generating assembly (3).

3. The hydrated negative oxygen ion generating device of claim 2, wherein: the water mist generator is characterized in that an assembly sleeve (16) is formed by downwards extending the edge of the opening (13) on the bottom wall of the base (1), the assembly sleeve (16) is connected with the flow guide surface (15) through a flow guide arc surface (151) in smooth transition, and the upper part of the water mist generation assembly (3) extends into the assembly sleeve (16) from bottom to top.

4. The hydrated negative oxygen ion generating device of claim 3, wherein: the output port (30) is positioned at the top of the water mist generation assembly (3), the output port (30) is arranged corresponding to the opening (13), and a backflow structure for backflow of condensed water in the assembly sleeve (16) into the water mist generation assembly (3) is arranged on the side wall of the upper portion of the water mist generation assembly (3).

5. The hydrated negative oxygen ion generating device of claim 4, wherein: subassembly (3) take place including water tank (31), ultrasonic atomization piece (32) and water absorption piece (33), base (1) below is located in water tank (31) shirks the formula, ultrasonic atomization piece (32) are located the assembly cover (16) top and are connected with water tank (31) through water absorption piece (33), water absorption piece (33) retrain the lower port department of the assembly cover (16) and cover this lower port through assembly seat (34), backflow structure is for seting up backward flow mouth (341) on assembly seat (34) lateral wall.

6. A hydrated negative oxygen ion generating device according to any one of claims 1 to 5, wherein: a circuit board (4) is arranged below the base (1), and the lower end of the negative ion needle (2) is connected to the upper end of the circuit board (4) and the upper end of the negative ion needle extends to the input port (12).

7. The hydrated negative oxygen ion generating device of claim 6, wherein: the upper part of the negative ion needle (2) penetrates through the bottom wall of the base (1) and is vertically arranged in the negative ion generating cavity (10) and close to the input port (12).

8. The hydrated negative oxygen ion generating device of claim 6, wherein: the upper part of the negative ion needle is bent upwards in an inclined way to the upper end and is arranged close to the lower edge of the input port.

9. A hydrated negative oxygen ion generating device according to any one of claims 1 to 5, wherein: the top of the base (1) is provided with a top cover (17) detachably connected with the base, the output port (14) is arranged on the top cover (17), the lower wall surface of the top cover (17) is provided with a flow guide rib (171) gradually extending downwards from the edge to the middle, and the lower end of the flow guide rib (171) is arranged corresponding to the inner edge of the opening (13).

10. The hydrated negative oxygen ion generating device of claim 9, wherein: the lower wall surface of the top cover (17) is provided with a baffle (172) at the position corresponding to the opening (13), the edge of the baffle (172) is provided with an arc-shaped flow guide strip (173) which gradually arches upwards from the edge to the middle, and the lower end of the flow guide strip (173) is connected with the lower end of the flow guide rib (171).

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