CN117053335A - Negative ion indoor air purifier - Google Patents

Abstract

The invention relates to an anion indoor air purifier, which belongs to the technical field of air purifiers, wherein a supporting sleeve is sleeved outside an anion generating host with a gap, the supporting sleeve is connected with the bottom of a floor frame, a reciprocating mechanism is arranged in the gap between the anion generating host and the supporting sleeve, a piston structure for increasing the injection height of generated anions is formed between the reciprocating mechanism and the supporting sleeve, the reciprocating mechanism is arranged in the supporting sleeve, the piston structure is formed between the reciprocating mechanism and the supporting sleeve, the reciprocating movement of the piston structure enables the injection range of anions injected into the air between the top of the supporting sleeve and the anion generating host to be increased, and the reciprocating mechanism enables the injection travel to be continuously increased in a reciprocating manner, so that when the anion generating indoor air purifier is used in a room with a large room height, the anions can be injected to the roof, the air close to the roof can be cleaned rapidly, and the air purifying efficiency is accelerated.

Description

Negative ion indoor air purifier

Technical Field

The invention belongs to the technical field of air purifiers, and particularly relates to an anion indoor air purifier.

Background

The utility model provides an anion air purifier is an environment optimization electrical apparatus that utilizes the anion that self produced to purify, remove dust, remove flavor, disinfect to the air, its core function is the anion that generates, utilize the dust removal dust fall that anion itself had, disinfect and detoxify's characteristic to optimize indoor air, and along with technological development, ecological anion air purifier has appeared on the market at present, ecological anion air processor comprises four parts, the floor frame, anion generates host computer, pollutant collector, the protection casing is constituteed, the host computer releaser releases ecological anion to the space, the anion combines with PM2.5 and less particulate matter bacterium, the virus of suspension in the air, and this ecological anion air purifier simple structure, and is with low costs, more be fit for people and use.

However, the negative ion air purifier has some problems in the use process:

the anion air purifier diffuses into the air through anion that anion generated host computer was sprayed out, can make the great pollutant subsides in the air, the less pollutant that does not have the coagulation subsidence is adsorbed by the pollutant collector that charges positively because of negatively charged and is collected, but when present anion air purifier used, all vertically upwards emit when anion generated host computer was sent out, then anion along spraying center to both sides divergence, and the fixed range of most anion generated host computers at present is about 1.5 meters, but when using in the great room of room height, can lead to the unable quick clean of air that is close to roof department.

In view of this, the present invention has been made.

Disclosure of Invention

In order to solve the problems in the prior art, the invention provides the negative ion indoor air purifier, which solves the problems that when the negative ion indoor air purifier is used, negative ions emitted by a negative ion generating main machine are emitted vertically upwards and then are dispersed to two sides along an injection center, and the fixed injection range of most negative ion generating main machines is about 1.5 m at present, but when the negative ion indoor air purifier is used in a room with a larger room height, air near the roof cannot be cleaned better.

The aim of the invention can be achieved by the following technical scheme: the utility model provides an indoor air purifier of anion, includes the floor frame, overlaps and establishes at the anion of floor frame top and generate the host computer, set up the pollutant collector of anion generation host computer below and overlap and establish at the outside protection casing of pollutant collector, the anion generates the host computer outside and leaves the clearance ground cover and be equipped with support sleeve, support sleeve and floor frame bottom to be connected, the anion generate the host computer with be equipped with round trip mechanism in the clearance between the support sleeve, round trip mechanism and support sleeve between form and be used for increasing the piston structure that generates anion injection height.

As a further aspect of the present invention, the reciprocating mechanism includes a sliding assembly slidably disposed in a gap between the negative ion generating host and the support sleeve, the sliding assembly and the support sleeve forming a piston structure, and an injection chamber being formed inside the support sleeve, the sliding assembly sliding inside the support sleeve to compress the injection chamber.

As a further scheme of the invention, the reciprocating mechanism further comprises a transmission adjusting assembly, wherein the transmission adjusting assembly comprises a crank part and a connecting rod part, the crank part is rotationally connected to the bottom of the supporting sleeve, one end of the connecting rod part is hinged with the crank part, and the other end of the connecting rod part is hinged with the sliding assembly;

the crank part comprises an outer disc, an inner disc and a limiting block, the inner disc is rotationally connected with the outer disc, the connecting rod part is hinged with the inner disc, a plurality of limiting grooves are formed in the edge of the inner disc, and the limiting block is slidably arranged on the edge of the outer disc and matched with any limiting groove.

As a further scheme of the invention, the supporting sleeve is connected with the bottom of the floor stand through a plurality of supporting rods, a supporting plate is arranged between two supporting rods, the outer disc is rotatably arranged on the supporting plate, and the outer disc is driven by a driving piece.

As a further aspect of the present invention, the link portion is hinged to an eccentric position of the inner disc.

As a further scheme of the invention, the sliding assembly comprises a sliding plug and a fixed block arranged at the bottom of the sliding plug, the sliding plug is arranged in a gap between the negative ion generating host and the supporting sleeve in a sliding manner, the sliding plug, the negative ion generating host and the supporting sleeve form a piston structure, and the supporting sleeve right above the output end of the negative ion generating host is provided with an injection port.

As a further scheme of the invention, the device also comprises a vibration power generation mechanism, wherein the vibration power generation mechanism is connected with the sliding plug, the vibration power generation mechanism and the injection port are respectively positioned at two sides of the sliding plug, so that the sliding plug reciprocates between the injection port and the vibration power generation mechanism, the sliding plug drives the vibration power generation mechanism to generate electric charge, and the vibration power generation mechanism is electrically connected with the pollutant collector.

As a further scheme of the invention, the vibration power generation mechanism comprises a piezoelectric ceramic plate, a spring arranged on the piezoelectric ceramic plate and a pressing plate arranged on the spring, wherein the piezoelectric ceramic plate is sleeved on the negative ion generation host through a fixed rod, the piezoelectric ceramic plate is electrically connected with the pollutant collector, a movable rod is arranged below the sliding plug, and the movable rod is connected with the pressing plate.

As a further scheme of the invention, one side of the pollutant collector is provided with a flapping mechanism for flapping dust to the pollutant collector, the flapping mechanism is arranged on one of the supporting rods, and the flapping mechanism is in transmission connection with the outer disc.

As a further scheme of the invention, the flapping mechanism comprises a flapping rod, a guide wheel, a connecting rope and a rotating wheel, wherein the rotating wheel is in transmission connection with an outer disc, the rotating wheel and the guide wheel are both rotatably arranged on a supporting rod, one end of the connecting rope is connected with the eccentric position of the rotating wheel, the other end of the connecting rope is connected with the flapping rod, one end of the flapping rod is hinged with the supporting rod, and the other end of the flapping rod can be attached to the outer side wall of the pollutant collector.

The beneficial effects of the invention are as follows:

through installing round trip mechanism in supporting sleeve for forming the piston structure between round trip mechanism and the supporting sleeve, firstly negative ion that the negative ion produced main machine blowout can independently spray a section distance along supporting sleeve upwards, afterwards enter into the air, secondly round trip mechanism and supporting sleeve between the piston structure that forms, when negative ion produced main machine sprays the negative ion, piston structure round trip motion makes the pressure change between supporting sleeve's top and the negative ion produced main machine, thereby make the negative ion range of spraying into the air between supporting sleeve's top and the negative ion produced main machine become high, round trip mechanism can make the stroke of spraying also constantly round trip become high, thereby can realize when the room that the room height is great uses, also can make the negative ion spray to roof department, can make the air that is close to the roof clean fast, air purification efficiency has been accelerated.

Drawings

The present invention is further described below with reference to the accompanying drawings for the convenience of understanding by those skilled in the art.

FIG. 1 is a schematic diagram of the overall structure of the present invention;

FIG. 2 is a schematic view of the mounting of the support plate of the present invention;

FIG. 3 is a schematic view of a sliding assembly according to the present invention;

FIG. 4 is a schematic view of a transmission adjustment assembly of the present invention;

FIG. 5 is a schematic view of the crank structure of the present invention;

FIG. 6 is a schematic diagram of a vibration power generation mechanism according to the present invention;

fig. 7 is a schematic structural view of the flapping mechanism of the present invention.

Description of main reference numerals:

in the figure: 1. a floor stand; 11. a support rod; 12. a support plate; 2. a negative ion generating host; 3. a pollutant trap; 4. a support sleeve; 5. a round trip mechanism; 51. a sliding assembly; 511. a sliding plug; 512. a fixed block; 52. a transmission adjustment assembly; 521. a curved handle portion; 5211. an outer disk; 5212. an inner disk; 5213. a limiting block; 513. a movable rod; 61. a piezoelectric ceramic sheet; 62. a spring; 63. a pressing plate; 71. beating the rod; 72. a guide wheel; 73. a connecting rope; 74. and rotating the wheel.

Detailed Description

In order to further describe the technical means and effects adopted by the invention for achieving the preset aim, the following detailed description is given below of the specific implementation, structure, characteristics and effects according to the invention with reference to the attached drawings and the preferred embodiment.

Referring to fig. 1-7, the present embodiment provides an anion indoor air purifier, including a landing frame 1, an anion generating host 2 sleeved on the top of the landing frame 1, a pollutant collector 3 disposed below the anion generating host 2, and a protective cover sleeved outside the pollutant collector 3, the anion host is fixedly connected with the landing frame 1, the pollutant collector 3 is usually designed on the landing frame 1 below the anion generating host 2 or fixedly sleeved on one end far from the output end of the anion generating host 2, a supporting sleeve 4 is sleeved outside the anion generating host 2 with a gap, a round trip mechanism 5 is installed in the gap between the anion generating host 2 and the supporting sleeve 4, the supporting sleeve 4 is fixedly connected with the bottom of the landing frame 1, a piston structure for increasing the spraying height of the generated anions is formed between the round trip mechanism 5 and the supporting sleeve 4, the height of the supporting sleeve 4 is higher than the whole height of the anion generating host 2, and when the round trip mechanism 5 moves, the piston structure moves within the height range of the supporting sleeve 4 without being separated from the supporting sleeve 4.

The current anion indoor air purifier consists of four parts, namely a floor frame 1, an anion generating host machine 2, a pollutant collector 3 and a protective cover, when the anion indoor air purifier is used, the anion generating host machine 2 releases ecological anions to the space, the anions are combined with PM2.5 suspended in the air and smaller particulate bacteria and viruses, so that the pollutants such as PM2.5 are negatively charged, partial agglomeration and sedimentation are carried out, the smaller pollutants such as agglomeration and sedimentation are not adsorbed and collected by the pollutant collector 3 with a positive point due to the negative charge, a pollutant negative pressure cavity is formed near the anion air processor, the pollutants at a distance are rapidly filled and diffused, and the diffused pollutants are purified as well, but when the current anion air purifier is used, the anions emitted by the anion generating host machine 2 are emitted vertically upwards, and then the anions are dispersed to two sides along an ejection center, and the fixed range of most of the anion generating host machine 2 is about 1.5 m, but when the room is used at a larger room height, the room is more difficult to clean.

In order to solve the above problem, a reciprocating mechanism 5 is installed in the support sleeve 4, so that a piston structure is formed between the reciprocating mechanism 5 and the support sleeve 4, firstly, negative ions sprayed by the negative ion generating host 2 can be automatically sprayed upwards along the support sleeve 4 for a certain distance and then enter the air, secondly, when the negative ions are sprayed by the negative ion generating host 2, the piston structure is formed between the reciprocating mechanism 5 and the support sleeve 4, and the reciprocating motion of the piston structure enables the pressure between the top of the support sleeve 4 and the negative ion generating host 2 to change, so that the negative ion range sprayed into the air between the top of the support sleeve 4 and the negative ion generating host 2 is high, the reciprocating mechanism 5 can enable the spraying travel to be continuously and reciprocally high, and therefore, when the negative ion generating host is used in a room with a large room height, the negative ion can be sprayed to the roof, the air close to the roof can be quickly cleaned, and the air purification efficiency is improved.

In order to better make the travel of the negative ion injection go back and forth higher, the round trip mechanism 5 needs to be implemented, in this embodiment, the round trip mechanism 5 includes a sliding component 51, the sliding component 51 is slidably disposed in a gap between the negative ion generating host 2 and the supporting sleeve 4, and the sliding component 51 and the supporting sleeve 4 form a piston structure, and an injection chamber is formed in the supporting sleeve 4, all negative ions generated by the negative ion generating host 2 pass through the injection chamber first and then into the air, and when the negative ions pass through the injection chamber, the travel of the injection of the negative ions is increased, the sliding component 51 slides towards the inside of the supporting sleeve 4 to compress the injection chamber, and the volume of the injection chamber is changed by compressing the injection chamber, so that the pressure is changed, and the travel of the injection of the negative ions is increased.

To better drive the sliding component 51 to slide and adjust the sliding stroke of the sliding component 51, in this embodiment, the reciprocating mechanism 5 further includes a transmission adjusting component 52, where the transmission adjusting component 52 includes a crank portion 521 and a connecting rod portion, the crank portion 521 is rotatably connected to the bottom of the supporting sleeve 4, where in order to facilitate installation of the crank portion 521, the bottom of the supporting sleeve 4 and the bottom of the landing rack 1 are connected by a plurality of support rods 11, a support plate 12 is installed between two support rods 11 in the plurality of support rods 11, a specific position of the crank portion 521 is rotatably disposed on the support plate 12, one end of the connecting rod portion is hinged with the crank portion 521, the other end is hinged with the sliding component 51, the crank portion 521 moves to drive the connecting rod portion to move together, specifically, the crank portion 521 includes an outer disc 5211, an inner disc 5212 and a stopper 5213, the inner disc 5212 is rotatably connected with the outer disc 5211, the outer disk 5211 is rotatably arranged on the supporting plate 12, the outer disk 5211 is driven by a driving piece, the driving piece is a motor, the connecting rod part is hinged with the eccentric position of the inner disk 5212, the reciprocating motion of the sliding component 51 can be realized only by being hinged with the eccentric position, a plurality of limit grooves are formed in the edge of the inner disk 5212, the limit block 5213 is slidably arranged on the edge of the outer disk 5211 and matched with any limit groove, the limit block 5213 is not subjected to outward pushing force when being clamped in the limit grooves, therefore, the limit block 5213 does not need to be further limited, but in order to ensure that the limit block 5213 is more stably limited, the limit block 5213 in figure 4 adopts a spring 62 which is slidably sleeved on the limit block 5213, when the limit block 5213 is pulled by hand and is clamped in the limit groove when the hand is released, and the limit block 5213 is particularly moved, the sliding component 51 slides inside the supporting sleeve 4 at a speed which is not required to be too fast, namely, the rotating speed of the motor is not required to be too fast and can be slowly performed, the negative ion air purifier is always green and low-noise equipment, the rotating speed of the motor is slow to avoid too loud, the advantages of the negative ion air purifier are weakened, the sliding component 51 is convenient to adjust the sliding stroke of the sliding component 51, the limiting block 5213 and the limiting groove are convenient to separate and fix, before the sliding stroke is adjusted, the motor rotates to drive the outer disc 5211 to rotate, the outer disc 5211 rotates to drive the limiting block 5213 to rotate, the limiting block 5213 and the limiting groove are clamped to drive the inner disc 5212 and the outer disc 5211 to rotate together, the inner disc 5212 and the outer disc 5211 at the moment are equivalent to a whole, the inner disc 5212 drives the connecting rod part to move through the hinging point of the eccentric position, the connecting rod part drives the sliding component 51 to slide back and forth, when the stroke is adjusted, the limiting block 5213 is manually pulled, so that the limiting block 5213 is separated from the limiting groove, at the moment, the motor slowly rotates to drive the outer disc 5211 to slowly rotate, the inner disc 5212 does not rotate, at the moment, the relative positions of the inner disc 5212 and the outer disc 5211 change, when the motor rotates to a proper position, the limiting block 5213 is released, the limiting block 5213 is clamped into the limiting groove, at the moment, the limiting groove clamped by the limiting block 5213 is different from the limiting groove at the initial position, by clamping into different limiting grooves, the position of a hinging point of the eccentric position of the inner disc 5212 is changed, so that the inner disc 5212 drives the connecting rod part to do different back and forth movements, namely, the connecting rod part drives the sliding component 51 to slide in the supporting sleeve 4 to change the stroke, at the moment, which limiting block 5213 is clamped into the limiting groove is determined according to the actual height of a room, to achieve a specific height, the design here can make the application range wider, and is applicable to all rooms with different heights.

In order to better change the volume of the injection chamber by compressing the injection chamber, in an embodiment, the sliding assembly 51 comprises a sliding plug 511 and a fixed block 512 arranged at the bottom of the sliding plug 511, the sliding plug 511 is slidably arranged in a gap between the negative ion generating host 2 and the supporting sleeve 4, the sliding plug 511, the negative ion generating host 2 and the supporting sleeve 4 form a piston structure, the sliding plug 511 is slidably sleeved on the negative ion generating host 2, and when the sliding plug 511 moves, the sliding plug 511 only moves between the output end and the other end of the negative ion generating host 2, does not separate from the negative ion generating host 2, and does not block the output of negative ions at the output end of the negative ion generating host 2, and the sliding plug 511 is made of rubber, because the sliding plug 511 made of rubber can ensure that the sealing performance between the sliding plug 511 and the outer wall of the negative ion generating host 2 and the inner wall of the supporting sleeve 4 is good, the sliding plug 511 is convenient for sliding, the supporting sleeve 4 over the output end of the negative ion generating host 2 is provided with a smooth injection port, and the negative ion generating host 2 is provided with the negative ion generating injection port.

In order to better enable the pollutant collector 3 to collect pollutants, avoid the situation that after a period of time, the amount of charges of the pollutant collector 3 is reduced due to the blocking of the pollutants, and the capability of collecting the pollutants is reduced.

In order to better realize energy saving and energy utilization, a part of mechanical energy of the motion of the sliding plug 511 is converted into electric energy, in this way, in an embodiment, the vibration power generation mechanism comprises a piezoelectric ceramic piece 61, a spring 62 arranged on the piezoelectric ceramic piece 61 and a pressing plate 63 arranged on the spring 62, the piezoelectric ceramic piece 61 is sleeved on the negative ion generation host 2 through a fixed rod sliding sleeve, the spring 62 increases the extrusion and vibration of the movable rod 513 on the piezoelectric ceramic piece 61 when the sliding plug 511 moves back and forth, the generation of electric charge quantity is increased, the piezoelectric ceramic piece 61 is fixedly connected with the fixed rod, the movable rod 513 is installed below the sliding plug 511, the movable rod 513 is connected with the pressing plate 63, when the sliding plug 511 moves to one end far away from an output end along the negative ion generation host 2, the movable rod 513 presses the piezoelectric ceramic piece 61 downwards, the fixed rod is simultaneously driven to slide downwards along the negative ion generation host 2, the spring 62 is compressed, the piezoelectric ceramic piece 61 generates electric charge, the piezoelectric ceramic piece 61 is electrically connected with the pollutant collector 3, the electric charge can reach the pollutant collector 3, the mechanical energy conversion of the part is realized, the electric charge quantity is reduced, and the pollutant collector cannot be blocked for a period of time, and the pollutant collector cannot be caused.

In order to further enable the pollutant trap 3 to avoid that dust adhered to the surface of the pollutant trap 3 affects the adsorption capacity of the pollutant trap 3 when the electric charge is added, in an embodiment, a beating mechanism for beating dust to the pollutant trap 3 is installed on one side of the pollutant trap 3, the beating mechanism is arranged on one supporting rod 11, the supporting rod 11 only provides an impetus for the beating mechanism, the beating mechanism is in transmission connection with the outer disc 5211, the pollutant trap 3 needs to be beaten from the side surface of the pollutant trap 3, the beating mechanism and the outer disc 5211 are driven by the same motor, the steering of the beating mechanism and the outer disc 5211 is different, the transmission is realized between the beating mechanism and the outer disc 5211 through a bevel gear, the motor drives the outer disc 5211 to rotate, and meanwhile, the beating mechanism is driven to move to the pollutant trap 3, so that the pollutant adhered to the surface of the pollutant trap 3 continuously and reciprocally slides, the pollutant trap 3 is prevented from being dropped, and the pollutant trap 3 is further affected by the adsorption capacity of the pollutant trap 3 is further increased.

In order to better remove pollutants on the surface of the pollutant collector 3 after a period of time is collected, in an embodiment, the patting mechanism comprises a patting rod 71, a guide wheel 72, a connecting rope 73 and a rotating wheel 74, the rotating wheel 74 is in transmission connection with an outer disc 5211, the rotating wheel 74 and the guide wheel 72 are both rotatably arranged on a supporting rod 11, the supporting rod 11 provides a supporting point for the rotating wheel 74 and the guide wheel 72, one end of the connecting rope 73 is connected with the eccentric position of the rotating wheel 74, the other end of the connecting rope 73 is connected with the patting rod 71, one end of the patting rod 71 is hinged with the supporting rod 11, the other end of the patting rod 71 is hinged with the outer side wall of the pollutant collector 3, the connecting rope 73 is an elastic rope, the purpose is to prevent the connecting rope 73 from driving the patting rod 71 to leave the pollutant collector 3 and then unable to return to the position where the pollutant collector 3 is attached, the rotating wheel 74 and the outer disc 5211 are in transmission, when the outer disc 5211 rotates to drive the rotating wheel 74 to rotate, one end of the connecting rope 73 is driven by the eccentric position, the other end of the connecting rope 73 moves, the other end of the connecting rope 73 is connected with the bevel gear 73 is driven by the bevel gear 72, the other end of the connecting rope 73 is connected with the other end of the patting rod 71 to slide the pollutant collector 3, the pollutant collector 71 is continuously to slide on the intermediate position of the patting rod 71, and the pollutant collector 71 can be removed, and the pollutant collector can be removed.

The working principle and the using flow of the invention are as follows:

when the anion air purifier is used, the anion air purifier is placed at a proper position of a room, the anion air purifier can be selectively placed at the center of the room or near the position away from the center, a motor and an anion generating host machine 2 are started, the motor rotates to drive an outer disc 5211 to rotate, the outer disc 5211 rotates to drive a limiting block 5213 to rotate, the limiting block 5213 and a limiting groove are clamped to drive an inner disc 5212 and the outer disc 5211 to rotate together, the inner disc 5212 drives a connecting rod part to move through a hinging point at an eccentric position, the connecting rod part drives a sliding plug 511 to slide up and down along the anion generating host machine 2, a compression injection cavity is formed, the volume of the injection cavity is changed through the compression injection cavity, the pressure is changed, the injection stroke of anions is increased, at the moment, the anion injection stroke can be adjusted according to the height of the room, when the regulating stroke is performed, the limiting block 5213 is pulled by hand, the limiting block 5213 is separated from a limiting groove, the motor slowly rotates to drive the outer disc 5211 to slowly rotate at the moment, the inner disc 5212 is not rotated, the relative position of the inner disc 5212 is changed through the hinging point at the eccentric position, the eccentric position is changed, namely, the connecting rod part is driven to move to the proper position of the limiting block 5213 to the proper position is not to slide in the limiting groove, and the corresponding position is changed, and the sliding part is moved to the proper position of the limiting block 5213, and the sliding part is moved to the proper position is moved to the position, and the proper position is changed to the position of the limiting block 5213, and is moved to the position to the proper position, and is moved to the position inside the position, and is moved to the position to move the position to and is correspondingly to the position to move the position inside the position, and is correspondingly to and is moved to move the position;

meanwhile, when the sliding plug 511 moves towards one end far away from the output end along the negative ion generating host 2, the movable rod 513 presses the piezoelectric ceramic plate 61 downwards at this time, the piezoelectric ceramic plate 61 drives the fixed rod to slide downwards along the negative ion generating host 2, the spring 62 compresses, the piezoelectric ceramic plate 61 generates charges, the piezoelectric ceramic plate 61 is electrically connected with the pollutant collector 3, the charges can reach the pollutant collector 3, partial mechanical energy is converted into electric energy, energy saving is achieved, the pollutant collector 3 is prevented from being blocked by pollutants after a period of collecting time, the electric charge is insufficient, and the pollutant collecting capacity is reduced;

when the outer disc 5211 rotates to drive the rotating wheel 74 to rotate, the rotating wheel 74 drives one end of the connecting rope 73 to move through the eccentric position, the other end of the connecting rope 73 pulls the beating rod 71 away from the pollutant collector 3, the rotating wheel 74 continues to rotate, the other end of the connecting rope 73 drives the beating rod 71 to beat the pollutant collector 3, in the process, the middle position of the connecting rope 73 slides on the guide wheel 72, the pollutant collector 3 is beaten back and forth through the beating rod 71, so that the pollutant on the surface of the pollutant collector 3 slides into the ground to clean the pollutant collector, and the whole working process is completed.

The present invention is not limited to the above embodiments, but is capable of modification and variation in detail, and other modifications and variations can be made by those skilled in the art without departing from the scope of the present invention.

Claims (10)

1. The utility model provides an indoor air purifier of anion, its characterized in that includes the floor frame, overlaps and establish at the anion generation host computer at floor frame top, sets up the pollutant collector of anion generation host computer below and overlaps the protection casing of establishing in the pollutant collector outside, and the anion generation host computer outside leaves the clearance ground cover and is equipped with support sleeve, and support sleeve and floor frame bottom are connected, the anion generation host computer with be equipped with round trip mechanism in the clearance between the support sleeve, round trip mechanism and support sleeve have formed the piston structure that is used for increasing and generates anion injection height between.

2. The negative ion indoor air cleaner according to claim 1, wherein the traverse mechanism comprises a slide assembly slidably disposed in a gap between the negative ion generating host and the support sleeve, the slide assembly and the support sleeve forming a piston structure and forming an ejection chamber inside the support sleeve, the slide assembly sliding inside the support sleeve to compress the ejection chamber.

3. The negative ion indoor air cleaner according to claim 2, wherein the round trip mechanism further comprises a transmission adjusting assembly, the transmission adjusting assembly comprises a crank part and a connecting rod part, the crank part is rotatably connected to the bottom of the support sleeve, one end of the connecting rod part is hinged with the crank part, and the other end of the connecting rod part is hinged with the sliding assembly;

the crank part comprises an outer disc, an inner disc and a limiting block, the inner disc is rotationally connected with the outer disc, the connecting rod part is hinged with the inner disc, a plurality of limiting grooves are formed in the edge of the inner disc, and the limiting block is slidably arranged on the edge of the outer disc and matched with any limiting groove.

4. The negative ion indoor air purifier according to claim 3, wherein the bottom of the supporting sleeve is connected with the bottom of the landing frame through a plurality of supporting rods, a supporting plate is arranged between two supporting rods, the outer disc is rotatably arranged on the supporting plate, and the outer disc is driven by a driving piece.

5. A negative ion indoor air cleaner according to claim 3, wherein the link portion is hinged to the eccentric position of the inner disc.

6. The negative ion indoor air purifier of claim 2, wherein the sliding assembly comprises a sliding plug and a fixed block arranged at the bottom of the sliding plug, the sliding plug is arranged in a gap between the negative ion generating host and the supporting sleeve in a sliding manner, the sliding plug, the negative ion generating host and the supporting sleeve form a piston structure, and the supporting sleeve right above the output end of the negative ion generating host is provided with an injection port.

7. The anion indoor air cleaner of claim 6, further comprising a vibration power generation mechanism, wherein the vibration power generation mechanism is connected with the sliding plug, the vibration power generation mechanism and the injection port are respectively located at two sides of the sliding plug, the sliding plug reciprocates between the injection port and the vibration power generation mechanism, the sliding plug drives the vibration power generation mechanism to generate electric charges, and the vibration power generation mechanism is electrically connected with the pollutant collector.

8. The negative ion indoor air purifier of claim 7, wherein the vibration power generation mechanism comprises a piezoelectric ceramic plate, a spring arranged on the piezoelectric ceramic plate and a pressing plate arranged on the spring, the piezoelectric ceramic plate is sleeved on the negative ion generation host through a fixed rod, the piezoelectric ceramic plate is electrically connected with the pollutant collector, a movable rod is arranged below the sliding plug, and the movable rod is connected with the pressing plate.

9. The negative ion indoor air cleaner according to claim 4, wherein a beating mechanism for beating dust to the pollutant trap is provided at one side of the pollutant trap, the beating mechanism is provided on one of the support rods, and the beating mechanism is in transmission connection with the outer disc.

10. The negative ion indoor air purifier of claim 9, wherein the beating mechanism comprises a beating rod, a guide wheel, a connecting rope and a rotating wheel, the rotating wheel is in transmission connection with the outer disc, the rotating wheel and the guide wheel are both rotatably arranged on the support rod, one end of the connecting rope is connected with the eccentric position of the rotating wheel, the other end of the connecting rope is connected with the beating rod, one end of the beating rod is hinged with the support rod, and the other end of the beating rod is in fit with the outer side wall of the pollutant collector.