CN109980529B

CN109980529B - Hydrated negative oxygen ion generating device

Info

Publication number: CN109980529B
Application number: CN201810591089.1A
Authority: CN
Inventors: 徐维跃; 俞凝; 陈猛
Original assignee: Ningbo Fotile Kitchen Ware Co Ltd
Current assignee: Ningbo Fotile Kitchen Ware Co Ltd
Priority date: 2017-12-28
Filing date: 2018-06-10
Publication date: 2024-01-19
Anticipated expiration: 2038-06-10
Also published as: CN208886950U; CN109980528B; CN208806476U; CN208886946U; CN109980515A; CN208797355U; CN109980521B; CN109980510A; CN109980524A; CN109980512A; CN208886947U; CN109980528A; CN208797356U; CN109980522A; CN109980532A; CN109980527B; CN208316026U; CN208797357U; CN109980522B; CN109980506A

Abstract

The invention relates to a hydrated negative oxygen ion generating device, which comprises a negative oxygen ion generating module, a water mist component, a tourmaline component and an oxygen conveying pipe, wherein the negative oxygen ion generating module is provided with an ion generating cavity capable of generating negative oxygen ions; the water mist assembly is communicated with the ion generation cavity; the tourmaline component is arranged in the ion generation cavity and is provided with a first side wall which can cover the output port of the water mist component, and the first side wall is provided with a first opening; the oxygen delivery tube is disposed in the ion generating chamber. The water mist generated by the water mist component is upwards conveyed into the tourmaline component, the water mist with larger particles contacts with tourmaline to release hydrated negative oxygen ions, the refined water mist enters the ion generation cavity, and under the high-oxygen environment generated by inputting oxygen into the oxygen conveying pipe, the negative ions excited in the ion generation cavity are converted into the hydrated negative oxygen ions, so that the hydrated negative oxygen ions with high concentration and long service life are formed, and the propagation distance is prolonged, so that a high-concentration negative ion environment can be created in a large space.

Description

Hydrated negative oxygen ion generating device

Technical Field

The invention relates to the technical field of air purification devices, in particular to a hydrated negative oxygen ion generating device.

Background

Negative ions (negative oxygen ions) are negatively charged gas ions in air, and when the concentration of the negative oxygen ions in the air is not less than 1000 to 1500 per cubic centimeter according to the regulations of the world health organization, such air is regarded as fresh air.

The Chinese patent application with publication number CN105526640A (application number CN 201610023392.2) and the Chinese patent application with application number CN105650752A (application number CN 201610001146.7) are respectively provided with an anion generating module, the anion generating module mainly adopts a tip corona discharge mode to generate anions, and then the anions are directly blown out by a fan. Chinese patent with publication number CN101214390B (application number: cn20080010137. X) discloses a specific similar anion generating structure, which comprises a base, a shell, a needle strip plate, a control loop and a needle ring, wherein the shell is assembled on the base, the needle strip plate is fixed between a baffle plate and a window grid, homopolar discharge needles are vertically and equidistantly arranged, the shell consists of a rear shell and a front shell, the window grid is movably connected with the rear shell, homopolar tungsten alloy discharge needles which are vertically and equidistantly arranged are fixed between the needle strip plate and the pressing plate by adopting a primary packaging process, carbon fibers fixed on the needle strip plate are communicated with the small high-pressure block, a closed carbon fiber ring is arranged in an annular groove at the periphery of the needle strip plate, a high-pressure block assembly fixed in the shell is packaged in a shielding cover, and the base and the shell are hinged together through a rotary positioning device.

The negative ion generation principle and structure are mature, but the service life of the negative ions generated by the corona discharge mode is extremely short, the negative ions disappear soon, long-distance transmission cannot be performed, and a high-concentration negative ion environment is difficult to build in a large space. In life, people feel fresh after thunder rain passes and beside a waterfall because a large amount of hydrated negative oxygen ions exist in the air, and the negative ions are O ₂ ^- (H ₂ O) _n The form has half-life of 60s, the life of hydrated negative oxygen ions is longer, and rapid propagation is expected to improve indoor ringAnd (5) an environment. Therefore, it is particularly desirable to provide a device that can generate hydrated negative oxygen ions.

In the prior art, the structure capable of generating the hydrated negative oxygen ions is also available, but the generation amount of the hydrated negative oxygen ions is low due to the fact that water mist particles are large, and the effect of purifying air is difficult to really realize.

Disclosure of Invention

The invention aims to solve the technical problem of providing a hydrated negative oxygen ion generating device which can prolong the service life of negative ions and prolong the propagation distance by combining the negative ions with oxygen in a high-humidity environment.

Aiming at the current state of the art, the invention provides the hydrated negative oxygen ion generating device which can refine water mist and greatly improve the generating effect of hydrated negative oxygen ions.

The technical scheme adopted for solving the technical problems is as follows: a hydrated negative oxygen ion generating device comprises

A negative oxygen ion generating module having an ion generating chamber capable of generating negative oxygen ions;

the method is characterized in that: and also comprises

The water mist assembly is used for generating water mist, and an output port of the water mist assembly is communicated with the ion generation cavity;

the tourmaline component is arranged in the ion generation cavity and is provided with a first side wall which can cover the output port of the water mist component, and the first side wall is provided with a first opening;

the oxygen delivery pipe is arranged in the ion generation cavity and provided with an input end which can extend out of the ion generation cavity, and the second side wall of the tourmaline component is arranged close to the oxygen delivery pipe and is provided with a second opening;

the third side wall of the tourmaline component is provided with a third opening which is opposite to the second opening, and the negative oxygen ion generation module is provided with an output port which is arranged close to the third opening and is used for outputting the water supply negative oxygen ions.

Preferably, the aperture of the second opening is larger than the aperture of the third opening. By adopting the structure, the refined water mist after passing through the tourmaline can flow into one side of the negative ion emission head in a large amount, which is beneficial to generating hydrated negative oxygen ions.

In the above scheme, the negative oxygen ion generating module comprises a body and a negative ion emitting head, wherein the body is hollow so as to form the ion generating cavity, and the negative ion emitting head is arranged in the ion generating cavity. The anion emission head can excite and produce oxygen-enriched ions, thereby producing hydrated oxygen-enriched ions in a high-humidity and high-oxygen environment.

In order to facilitate the output of hydrated negative oxygen ions, an inlet for air to enter is formed in a first side wall of the body, the inlet is arranged close to the oxygen conveying pipe, the output port is formed in a second side wall of the body, and the second side wall is arranged opposite to the first side wall.

Preferably, a bracket for fixing the negative ion emission head is arranged in the inlet, and the negative ion emission head is arranged in the middle of the inlet through the bracket; the support is cross-shaped, a through hole arranged along the air inlet direction is formed in the center of the support, and the negative ion emission head is inserted into the through hole.

Preferably, the tourmaline component comprises a box body and tourmaline which can emit negative oxygen ions in a state of being contacted with water mist, wherein the tourmaline is spherical particles and is distributed in the box body in a dispersing way. By adopting the structure, the water mist can enter the ion generation cavity only by penetrating through the tourmaline, the tourmaline is spherical particles and is distributed in the box body in a dispersed way, the structure can reduce the wind resistance of the tourmaline component, more air is stored simultaneously, negative ions released after the electric stone contacts the water mist are combined with oxygen to form hydrated negative oxygen ions, the oxygen-enriched water mist particles entering the ion generation cavity can be thinned, the negative ions generated in the negative ion generation cavity are further combined with oxygen to form hydrated negative oxygen ions, the generation quantity and efficiency of the hydrated negative oxygen ions are improved, and the purification effect is further improved.

As an improvement, the atomization assembly comprises a water storage tank, an ultrasonic atomization sheet and a water absorbing piece, wherein the ultrasonic atomization sheet is arranged at the top of the water storage tank and is connected with the water storage tank through the water absorbing piece, and a water mist input port corresponding to the ultrasonic atomization sheet is arranged at the bottom of the ion generation cavity. By adopting the structure, the ultrasonic atomizing sheet atomizes the water sucked by the water suction piece from the water storage tank and inputs the atomized water into the ion generation cavity, so that a high-humidity environment is provided for the ion generation cavity, and the hydrated negative ions with long service life and long propagation distance can be obtained.

Preferably, the atomization assembly further comprises an assembly plate, the top of the water storage tank is opened, the assembly plate is covered on the top of the water storage tank, the upper surface of the assembly plate is tightly propped against the lower surface of the ion generation module, the upper surface of the assembly plate is provided with a containing groove for installing an ultrasonic atomization sheet, the bottom of the containing groove is provided with a clamping hole penetrating through the assembly plate downwards, the upper end of the water absorbing piece is inserted into the clamping hole, and the lower end of the water absorbing piece extends into the water storage tank. The absorbent member is preferably a absorbent cotton swab.

Preferably, an air guide channel for air to enter the accommodating groove is formed in the upper surface of the assembly plate, a first end of the air guide channel is communicated with the accommodating groove, and a second end of the air guide channel extends from the accommodating groove to the edge of the assembly plate. The structure makes assembly structure compact on the one hand, on the other hand, can provide the air for the atomizing process, is favorable to atomizing process to go on effectively fast.

As improvement, be provided with the diffusion subassembly that enables the anion to take place circumferential deflection in the delivery outlet, this diffusion subassembly includes collar, installation axle and has the magnetic sheet subassembly of N utmost point and S utmost point, the collar cover is arranged in the installation axle periphery and is arranged with this installation axle coaxial, the magnetic sheet subassembly locate the installation epaxial and be arranged in the collar, the magnetic sheet subassembly have at least two sets of and the N utmost point and the S utmost point of each set of magnetic sheet be located the both sides of installation axle respectively, the N utmost point of each set of magnetic sheet is adjacent to be arranged, the S utmost point of each set of magnetic sheet is adjacent to be arranged. When negative ions pass through the diffusion assembly at the outlet end of the negative oxygen ion generation module, the electrified diffusion assembly can generate a magnetic field, so that negative oxygen ions with negative electricity are subjected to Lorentz force when axially passing through the mounting ring, the negative oxygen ions deflect to the periphery from the original axial direction due to the action force, and then the negative ions are rapidly diffused and dispersed indoors, so that air with good uniformity and carrying the negative ions is formed, and a better air purification effect is achieved.

For the installation of being convenient for, open on the inner wall of collar has the first draw-in groove along axial arrangement, corresponding, open on the periphery wall of installation axle has the second draw-in groove along axial arrangement, the magnetic sheet subassembly is radial arrangement between collar and installation axle through first draw-in groove, second draw-in groove.

Compared with the prior art, the invention has the advantages that: the water mist generated by the water mist component is upwards conveyed into the tourmaline component, the water mist with larger particles contacts with tourmaline to release hydrated negative oxygen ions, the refined water mist enters the ion generation cavity, and under the high-oxygen environment generated by inputting oxygen into the oxygen conveying pipe, the negative ions excited in the ion generation cavity are converted into the hydrated negative oxygen ions, so that the hydrated negative oxygen ions with high concentration and long service life are formed, and the propagation distance is prolonged, so that a high-concentration negative ion environment can be created in a large space.

Drawings

FIG. 1 is a schematic diagram of an embodiment of the present invention;

FIG. 2 is a schematic view of the structure of FIG. 1 at another angle;

FIG. 3 is a cross-sectional view of FIG. 2 (hidden diffusion member);

FIG. 4 is an exploded view of FIG. 2 (concealing the diffusion component);

FIG. 5 is a schematic view of a diffusion assembly according to an embodiment of the present invention;

fig. 6 is an exploded view of fig. 5.

Detailed Description

The invention is described in further detail below with reference to the embodiments of the drawings.

As shown in fig. 1 to 6, the hydrated negative oxygen ion generating device of the present embodiment includes a negative oxygen ion generating module 2, a water mist component 5, a tourmaline component 3 and an oxygen delivery pipe 1, wherein the negative oxygen ion generating module 2 has an ion generating cavity 20 capable of generating negative oxygen ions, the bottom of the ion generating cavity 20 has an input port 221 for supplying water mist, the water mist component 5 is used for generating water mist, and the output port of the water mist component 5 is connected with the input port 221 of the ion generating cavity 20; the tourmaline assembly 3 is arranged in the ion generation cavity 20 and is provided with a first side wall which can cover the input port 221 of the ion generation cavity 20 and the output port of the water mist assembly 5, the first side wall is the bottom wall of the tourmaline assembly 3, and the first side wall is provided with a first opening 31. The oxygen delivery pipe 1 is arranged in the ion generation cavity 20 and is provided with an input end 11 which can extend out of the ion generation cavity 20, the input end 11 is connected with an external oxygen supply device, the oxygen delivery pipe 1 extends in the ion generation cavity 20 along the length direction of the ion generation cavity 20, a plurality of vent holes 12 which are arranged at intervals are formed in the oxygen delivery pipe 1, the input end 11 is the middle part of the oxygen delivery pipe 1, and the aperture of the vent holes 12 is gradually enlarged from the middle to two ends of the oxygen delivery pipe 1 so as to keep the concentration of oxygen everywhere consistent. The second side wall 32 of the tourmaline assembly 3 is arranged close to the oxygen delivery pipe 1 and is provided with a second opening 321, the third side wall 33 of the tourmaline assembly 3 is provided with a third opening 331 which is arranged opposite to the second opening 321, and the aperture of the third opening 331 is larger than that of the second opening 321, so that refined water mist can burst into one side of the anion emission head in a large amount after passing through tourmaline, and hydrated negative oxygen ions can be generated. The negative oxygen ion generating module 2 is provided with an output port 220 which is arranged near the third opening 331 and is used for outputting the water supply negative oxygen ions.

The negative oxygen ion generating module 2 comprises a body 22 and a negative ion emitting head 23, wherein the body 22 is hollow so as to form an ion generating cavity 20, and the negative ion emitting head 23 is arranged in the ion generating cavity 20. The anion emitter head 23 can be activated to produce oxygen-enriched ions, thereby producing hydrated oxygen-enriched ions in a high humidity, high oxygen environment. In order to facilitate the output of hydrated negative oxygen ions, the first side wall of the body 22 is provided with an inlet 21 for air to enter, which is arranged close to the oxygen delivery pipe 1, and the output port 220 is arranged on the second side wall of the body 22, which is arranged opposite to the first side wall. A bracket 222 for fixing the anion emission head is arranged in the inlet 21, and the anion emission head 23 is arranged in the middle of the inlet 21 through the bracket 222; the bracket 222 is cross-shaped, and a through hole arranged along the air inlet direction is formed in the center of the bracket 222, and the anion emitter 23 is inserted into the through hole.

The tourmaline component 3 comprises a box body 301 and tourmaline 302 which can emit negative oxygen ions in a state of being contacted with water mist, wherein the tourmaline 302 is spherical particles and is distributed in the box body 301. By adopting such a structure, water mist can enter the ion generation cavity 20 after penetrating through the tourmaline 302, the tourmaline 302 in the embodiment is spherical particles and is distributed in the box body 301 in a dispersing way, the wind resistance of the tourmaline component 3 can be reduced, more air is stored simultaneously, negative ions released after the power supply stone 302 contacts the water mist are combined with oxygen to form hydrated negative oxygen ions, the water mist particles entering the ion generation cavity 20 can be thinned, the negative ions generated in the negative ion generation cavity 20 are further combined with oxygen to form hydrated negative oxygen ions, the generation quantity and efficiency of the hydrated negative oxygen ions are improved, and the purifying effect is further improved.

The atomizing assembly 5 comprises a water storage tank 51, an ultrasonic atomizing sheet 52, an assembly plate 53 and a water absorbing member 54, wherein the ultrasonic atomizing sheet 52 is arranged at the top of the water storage tank 51 and is connected with the water storage tank 51 through the water absorbing member 54, and a water mist input port 221 at the bottom of the ion generating cavity 20 corresponds to the ultrasonic atomizing sheet 52. The top of the water storage tank 51 of this embodiment is arranged open, the assembly plate 53 is covered on the top of the water storage tank 51, the upper surface of the assembly plate 53 abuts against the lower surface of the ion generating module body 22, the upper surface of the assembly plate 53 is provided with a containing groove 531 for installing the ultrasonic atomizing sheet 52, the bottom of the containing groove 531 is provided with a clamping hole 532 penetrating the assembly plate 53 downwards, the upper end of the water absorbing member 54 is inserted into the clamping hole 532, and the lower end of the water absorbing member 54 extends into the water storage tank 51. The absorbent member 54 is a absorbent cotton swab. An air guide channel 533 for air to enter the accommodating groove 531 is formed on the upper surface of the assembling plate 53, a first end of the air guide channel 533 is communicated with the accommodating groove 531, and a second end of the air guide channel 533 extends from the accommodating groove 531 to the edge of the assembling plate 53. The structure makes assembly structure compact on the one hand, on the other hand, can provide the air for the atomizing process, is favorable to atomizing process to go on effectively fast. The ultrasonic atomizing sheet 52 atomizes the water sucked from the water storage tank 51 by the water suction member 54 and inputs the atomized water into the ion generation chamber 20, thereby providing a high humidity environment for the ion generation chamber 20 and facilitating the acquisition of hydrated anions having a long life and propagation distance.

The inlet 21 side of the body 22 is covered with a diffusion plate 6 capable of generating a negative electric field in a negatively charged state to promote negative ions to be output toward the outlet 220, and ventilation holes 61 are formed in the diffusion plate 6. The outlet 220 is provided with a diffusion component 4 capable of circumferentially deflecting negative ions, the diffusion component 4 comprises a mounting ring 41, a mounting shaft 42 and magnetic sheet components 43 with N poles and S poles, the mounting ring 41 is sleeved on the periphery of the mounting shaft 42 and is coaxially arranged with the mounting shaft 42, the magnetic sheet components 43 are arranged on the mounting shaft 42 and are positioned in the mounting ring 41, the magnetic sheet components 43 are provided with three groups, the N poles and the S poles of each group of magnetic sheet components 43 are respectively positioned on two sides of the mounting shaft 42, the N poles and the S poles of each group of magnetic sheet components 43 are adjacently arranged, and the S poles of each group of magnetic sheet components 43 are adjacently arranged. The diffusing member 4 of the present embodiment is disposed in the output port 220, and the mounting ring 41 is disposed coaxially with the output port 220. The inner wall of the mounting ring 41 is provided with a first clamping groove 411 which is arranged along the axial direction, correspondingly, the outer peripheral wall of the mounting shaft 42 is provided with a second clamping groove 421 which is arranged along the axial direction, and the magnetic sheet component 43 is radially arranged between the mounting ring 41 and the mounting shaft 42 through the first clamping groove 411 and the second clamping groove 421. When the diffusion plate 6 drives negative oxygen ions with negative electricity to pass through the mounting ring 41 along the axial direction, the negative oxygen ions are deflected from the original axial direction by the action of Lorentz force and are rapidly diffused indoors, so that air with good uniformity and carrying negative ions is formed, and a better air purifying effect is achieved.

Claims

1. A hydrated negative oxygen ion generating device comprises

A negative oxygen ion generation module (2), the negative oxygen ion generation module (2) having an ion generation chamber (20) capable of generating negative oxygen ions;

the method is characterized in that: and also comprises

The water mist assembly (5) is used for generating water mist, and an output port of the water mist assembly (5) is communicated with the ion generation cavity (20);

the tourmaline component (3) is arranged in the ion generation cavity (20) and is provided with a first side wall which can cover the output port of the water mist component (5), and the first side wall is provided with a first opening (31);

an oxygen delivery tube (1) disposed in the ion generating chamber (20) and having an input end (11) capable of extending out of the ion generating chamber (20), the second side wall (32) of the tourmaline assembly (3) being disposed adjacent to the oxygen delivery tube (1) and having a second opening (321);

a third opening (331) which is arranged opposite to the second opening (321) is formed in the third side wall (33) of the tourmaline component (3), and an output port (220) for outputting water supply negative oxygen ions which is arranged close to the third opening (331) is formed in the negative oxygen ion generation module (2);

the negative oxygen ion generation module (2) comprises a body (22) and a negative ion emission head (23), wherein the body (22) is hollow so as to form the ion generation cavity (20), and the negative ion emission head (23) is arranged in the ion generation cavity (20);

the tourmaline component (3) comprises a box body and tourmaline which can emit negative oxygen ions in a state of being contacted with water mist, wherein the tourmaline is spherical particles and is distributed in the box body in a dispersing way;

the utility model provides a negative oxygen ion output' S that hydrates delivery outlet (220) is provided with diffusion subassembly (4) that enable the anion to take place circumferential deflection, and this diffusion subassembly (4) are including collar (41), installation axle (42) and have magnetic sheet subassembly (43) of N utmost point and S utmost point, collar (41) cover are arranged in installation axle (42) periphery and with this installation axle (42) coaxial arrangement, magnetic sheet subassembly (43) locate on installation axle (42) and lie in collar (41), magnetic sheet subassembly (43) have at least two sets of and the N utmost point and the S utmost point of each magnetic sheet subassembly (43) of group are located the both sides of installation axle (42) respectively, the N utmost point of each magnetic sheet subassembly (43) of group is adjacent to be arranged, the S utmost point of each magnetic sheet subassembly (43) of group is adjacent to be arranged.

2. The negative oxygen ion-generating device for hydration according to claim 1, wherein: an inlet (21) for air to enter is formed in the first side wall of the body (22), the inlet is arranged close to the oxygen conveying pipe (1), and the output port (220) is formed in the second side wall of the body (22), and the second side wall is arranged opposite to the first side wall.

3. The negative oxygen ion-generating device for hydration according to claim 2, wherein: a bracket (222) for fixing the negative ion emission head (23) is arranged in the inlet (21), and the negative ion emission head (23) is arranged in the middle of the inlet (21) through the bracket (222); the bracket (222) is cross-shaped, a through hole arranged along the air inlet direction is formed in the center of the bracket (222), and the negative ion emission head (23) is inserted into the through hole.

4. A hydrated negative oxygen ion generating device according to any one of claims 1 to 3, characterized in that: the water mist assembly (5) comprises a water storage tank (51), an ultrasonic atomization sheet (52) and a water absorbing piece (54), wherein the ultrasonic atomization sheet (52) is arranged at the top of the water storage tank (51) and is connected with the water storage tank (51) through the water absorbing piece (54).

5. The negative oxygen ion generator according to claim 4, wherein: the water mist assembly (5) further comprises an assembly plate (53), the top of the water storage tank (51) is opened, the assembly plate (53) is covered on the top of the water storage tank (51) and the upper surface of the assembly plate is tightly propped against the bottom of the ion generation module body (22), the upper surface of the assembly plate (53) is provided with a containing groove (531) for installing an ultrasonic atomization sheet (52), the bottom of the containing groove (531) is provided with a clamping hole (532) penetrating through the assembly plate (53) downwards, the upper end of the water absorbing piece (54) is inserted into the clamping hole (532), and the lower end of the water absorbing piece (54) stretches into the water storage tank (51).

6. The negative oxygen ion generator according to claim 5, wherein: an air guide channel (533) for air to enter the accommodating groove (531) is formed in the upper surface of the assembly plate (53), a first end of the air guide channel (533) is communicated with the accommodating groove (531), and a second end of the air guide channel (533) extends from the accommodating groove (531) to the edge of the assembly plate (53).

7. The negative oxygen ion-generating device for hydration according to claim 1, wherein: the inner wall of the mounting ring (41) is provided with a first clamping groove (411) which is axially arranged, the outer peripheral wall of the mounting shaft (42) is provided with a second clamping groove (421) which is axially arranged, and the magnetic sheet component (43) is radially arranged between the mounting ring (41) and the mounting shaft (42) through the first clamping groove (411) and the second clamping groove (421).