CN117267821A - Energy-saving air purification device for clean laboratory decoration - Google Patents

Abstract

The invention relates to the technical field of air purification, in particular to an energy-saving air purification device for clean laboratory decoration, which comprises a support frame, wherein a collecting box is arranged on the support frame, a dust removing component is arranged in the collecting box and used for treating dust in dust-containing air, the top of the support frame is abutted to an indoor ceiling, the top of the support frame is provided with an exhaust pipe, the collecting box is communicated with the exhaust pipe, a heating component is arranged between the collecting box and the exhaust pipe, the heating component heats the air in the collecting box, the heated air is discharged to the high indoor position through the exhaust pipe, the air density is reduced after the air is heated, the hot air is distributed on the upper layer, the hot air does not generate convection with the dust-containing air which is not absorbed and treated, and the collecting box gradually absorbs and treats the dust-containing air from top to bottom, so that the dust-containing air at each indoor height can be absorbed and treated, and the purification of the air is more uniform.

Description

Energy-saving air purification device for clean laboratory decoration

Technical Field

The invention relates to the technical field of air purification devices, in particular to an energy-saving air purification device for clean laboratory decoration.

Background

The air purifying device (also called as air cleaning device and air refreshing machine) is a product which can filter or kill air pollutant and effectively improve air cleanliness, and mainly comprises household and commercial air purifying devices for cleaning indoor air pollution. The air purification device can filter pollutants such as air suspended particles, bacteria, viruses, fungal spores, pollen, asbestos, radon gas decay products and the like. The air purification device can be suitable for various scenes, such as decoration, dust particles and powder can float in the air to influence construction, and the air purification device can adsorb the dust particles and the powder in the air.

In the prior art, air purifying equipment is usually placed in one corner of a room, the air inlet position of the air purifying equipment is constant, the air purifying effect on the far distance from the air purifying equipment is poor, and the air cannot be uniformly purified.

Disclosure of Invention

Accordingly, it is necessary to provide an energy-saving air purification device for clean laboratory decoration, which solves the problem of non-uniformity of air purification by the conventional air purification device.

The above purpose is achieved by the following technical scheme:

an energy-saving clean laboratory finishing air purification device, comprising:

the dust collection device comprises a support frame, wherein a collection box is arranged on the support frame and used for collecting dust-containing air, a dust collection assembly is arranged in the collection box and used for filtering the dust-containing air, the top of the support frame is abutted to an indoor ceiling, and the collection box gradually moves downwards from the top of the support frame;

the exhaust pipe is positioned at the top of the support frame and is communicated with the collecting box, and the exhaust pipe discharges the gas in the collecting box from the top of the support frame;

and the heating assembly is used for heating the gas in the exhaust pipe.

Further, the support frame can stretch out and draw back in the vertical direction.

Further, the support frame comprises a first telescopic cylinder and a second telescopic cylinder, the second telescopic cylinder is inserted into the first telescopic cylinder, a first rack is fixedly arranged on the inner wall of the first telescopic cylinder, a vertical groove is formed in the first telescopic cylinder, a gear is rotatably arranged on the second telescopic cylinder and meshed with the first rack, and the gear is rotated to drive the first rack to move so as to drive the first telescopic cylinder to axially move.

Further, a driving roller and a driven roller are arranged in the first telescopic cylinder and the second telescopic cylinder, a belt is wound between the driving roller and the driven roller, and the collecting box is fixed on the belt.

Further, the energy-saving air purification device for clean laboratory decoration further comprises a driving mechanism, and the driving mechanism is used for driving the driving roller to rotate.

Further, a hand wheel is fixedly arranged on the rotating shaft of the gear.

Further, a water storage tank is connected between the heating component and the exhaust pipe, and the gas enters the exhaust pipe after passing through the water storage tank.

Further, the heating assembly comprises a heater, one end of the heater is communicated with the water storage tank, and the other end of the heater is communicated with the collecting tank.

Further, the dust removal assembly includes a filter.

Further, a nozzle is arranged on the supporting frame, and the nozzle is connected with the exhaust pipe.

The beneficial effects of the invention are as follows:

according to the invention, the collection box moving from top to bottom is arranged, dust-containing air collected in the collection box is treated and is discharged from the indoor top after being heated, the heated air and untreated dust-containing air are layered, and the heated air is low in density, so that the heated air is always positioned above the untreated dust-containing air, the discharged heated air is not easy to generate convection with the untreated dust-containing air, further, dust in the untreated dust-containing air can be better settled, and meanwhile, the collection box moving from top to bottom can absorb and treat dust-containing air at all indoor heights, so that the purification of the air is more uniform.

Through setting up liftable support frame for energy-saving clean laboratory decoration is with air purification device can adapt to the laboratory of different co-altitude, has improved energy-saving clean laboratory decoration greatly and has used air purification device's practicality.

Through setting up the water tank for in the air after the heating lets in the aquatic, can further get rid of harmful gas in the air, can carry a little moisture when the air discharge water tank of heating simultaneously, moisture can condense into the drop of water at the juncture of hot air and cold air, and the drop of water can adsorb the dust in the dust-laden air of unabsorbed processing to subaerial in-process, and wets ground when dropping to subaerial, can effectively prevent the dust raise dust on ground.

Drawings

FIG. 1 is a schematic diagram of an energy-saving air purifying device for clean laboratory decoration according to an embodiment of the present invention;

FIG. 2 is a front view of the energy-saving air cleaning device for clean laboratory decoration according to the embodiment shown in FIG. 1;

FIG. 3 is a cross-sectional view of the energy-saving clean laboratory finishing air cleaning device provided by the embodiment of FIG. 2 along line A-A;

FIG. 4 is a cross-sectional view of the energy-saving clean laboratory finishing air cleaning device provided by the embodiment of FIG. 2 along line B-B;

FIG. 5 is a top view of an energy-saving clean laboratory finishing air cleaning device according to one embodiment of FIG. 1;

FIG. 6 is a cross-sectional view of the energy-saving clean laboratory finishing air cleaning device provided by the embodiment of FIG. 5 along line C-C;

fig. 7 is an enlarged view of a portion D of the energy-saving type air cleaning device for clean laboratory decoration according to an embodiment of fig. 6.

Wherein:

100. a support frame; 110. a first telescopic cylinder; 120. a second telescopic cylinder; 130. a driving motor; 140. a hand wheel; 150. a support block; 160. a rubber pad; 170. a spray head;

200. a collection box; 201. a friction block; 202. a spring; 210. a hose; 211. a wind-up roll; 220. a heating assembly; 230. a water tank; 240. an exhaust pipe;

300. a first rack; 310. a second rack; 320. a vertical groove; 330. a gear; 340. a first roller; 350. a second drum; 360. a belt; 370. a drive roll; 380. driven roller.

Detailed Description

The present invention will be further described in detail below with reference to examples, which are provided to illustrate the objects, technical solutions and advantages of the present invention. It should be understood that the specific embodiments described herein are for purposes of illustration only and are not intended to limit the scope of the invention.

The numbering of components herein, such as "first," "second," etc., is used merely to distinguish between the described objects and does not have any sequential or technical meaning. The terms "coupled" and "connected," as used herein, are intended to encompass both direct and indirect coupling (coupling), unless otherwise indicated. In the description of the present invention, it should be understood that the terms "upper", "lower", "front", "rear", "left", "right", "vertical", "horizontal", "top", "bottom", "inner", "outer", "clockwise", "counterclockwise", etc. indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, are merely for convenience in describing the present invention and simplifying the description, and do not indicate or imply that the device or element in question must have a specific orientation, be configured and operated in a specific orientation, and thus should not be construed as limiting the present invention.

In the present invention, unless expressly stated or limited otherwise, a first feature "up" or "down" a second feature may be the first and second features in direct contact, or the first and second features in indirect contact via an intervening medium. Moreover, a first feature being "above," "over" and "on" a second feature may be a first feature being directly above or obliquely above the second feature, or simply indicating that the first feature is level higher than the second feature. The first feature being "under", "below" and "beneath" the second feature may be the first feature being directly under or obliquely below the second feature, or simply indicating that the first feature is less level than the second feature.

An energy-saving clean laboratory finishing air cleaning device provided by the present application is described below with reference to fig. 1 to 7.

The utility model provides an energy-saving clean air purification device for laboratory decoration, is applicable to various scenes, is particularly useful for the purification of air when the fitment, includes support frame 100, and support frame 100 sets up in the room, and the slip is provided with collecting box 200 on the support frame 100, has a plurality of through-holes on the collecting box 200, and collecting box 200 can inhale indoor dusty air and handle the dirty air of inhalant. The top of support frame 100 is provided with blast pipe 240, blast pipe 240 and collecting box 200 intercommunication, and the air of handling in the collecting box 200 is discharged through blast pipe 240, is provided with heating element 220 between blast pipe 240 and the collecting box 200, and heating element 220 is used for heating the air of handling in the collecting box 200, and the air after the heating is discharged from blast pipe 240.

In the initial state, the top of the supporting frame 100 is abutted against the indoor ceiling, the bottom of the supporting frame 100 is positioned on the ground, the collecting box 200 is positioned at the highest position of the supporting frame 100, the collecting box 200 starts to absorb dust-containing air at the higher position in the room, the dust-containing air is heated by the heating component 220 and then is discharged through the exhaust pipe 240, the temperature of the discharged gas is higher, the gas is distributed at the higher position in the room, the collecting box 200 starts to descend for a small distance after staying for a period of time at the highest position of the supporting frame 100, then stops for a period of time, and so on until the collecting box 200 moves to a position close to the ground.

It can be understood that the collecting box 200 starts to absorb dust-containing air from a higher position in the room, the absorbed dust-containing waste gas is heated and discharged to the higher position in the room after being treated, the discharged hot air fills the space remained by the absorbed dust-containing air at the higher position in the room, the collecting box 200 gradually descends, the dust-containing air at each height in the room is gradually absorbed, and the dust-containing air is discharged after being treated and heated after being absorbed. Because the density of the hot air relative to the cold air is small, the hot air can not easily generate relative flow between the discharged hot air and unabsorbed air above the cold air, the air fluidity is weak, and dust in the air is more easy to settle (if the hot air is below the cold air, the hot air can move upwards to generate convection, and the sedimentation of dust in dust-containing air is not facilitated after the convection). As the collection box 200 gradually moves downward, air at various heights in the room is absorbed, dust in dust-containing air at a lower position in the room gradually settles with the increase of time, and the dust gradually deposits on the ground.

The dust-containing air at each height in the room is absorbed by the collecting box 200 moving from top to bottom, and the treated air is heated and discharged to the height in the room, the heated air occupies the space above, the heated air and the unabsorbed air can be layered, that is, the discharged air is not easy to disturb the unabsorbed air, the collecting box 200 gradually moves downwards from the highest position, the dust in the dust-containing air at a lower position is settled for a longer time, the dust content in the air is reduced, the filtering pressure of the collecting box 200 can be reduced, and the filtering efficiency can be greatly improved.

Specifically, the dust removing assembly in the collecting box 200 includes a filter, and the filter sucks dust-containing air from outside the collecting box 200 into the collecting box 200 for treatment, so as to remove most of dust in the air. Of course, the dust removing assembly may have other structures, for example, a dust collector, and the dust collector may collect dust in the dust-containing air, and the dust removing assembly may be any device capable of removing the dust in the dust-containing air.

In a further embodiment, the support 100 is capable of telescoping in a vertical direction, i.e. the height of the support 100 is adjustable. The air purification device for energy-saving clean laboratory decoration works by abutting the top of the support frame 100 on an indoor ceiling, so that the height of the support frame 100 is consistent with the indoor height, the indoor heights of different laboratories are different, the heights of the support frame 100 can be adjusted to adapt to different laboratories, and the practicability of the air purification device for energy-saving clean laboratory decoration is greatly improved.

In order to avoid abrasion of the indoor ceiling by the support frame 100, a support block 150 is arranged at the top of the support frame 100, a rubber pad 160 is arranged above the support block 150, and the rubber pad 160 is in contact with the ceiling, so that friction is avoided.

Specifically, as shown in fig. 2 and fig. 3, the support frame 100 includes a first telescopic cylinder 110 and a second telescopic cylinder 120, the cross sections of the first telescopic cylinder 110 and the second telescopic cylinder 120 are rectangular, the first telescopic cylinder 110 is inserted into the second telescopic cylinder 120, a first rack 300 is fixedly arranged on the inner wall of the first telescopic cylinder 110, a gear 330 is rotatably arranged in the second telescopic cylinder 120, a vertical groove 320 is formed in the first telescopic cylinder 110, teeth on the first rack 300 face the vertical groove 320, the gear 330 on the second telescopic cylinder 120 stretches into the vertical groove 320 to be meshed with the first rack 300, the gear 330 drives the first rack 300 to slide in the second telescopic cylinder 120 to change the height of the integral support frame 100 when rotating, as shown in fig. 6 and fig. 7, the first rack 300 moves downwards when the gear 330 rotates clockwise, the first telescopic cylinder 110 descends relative to the second telescopic cylinder 120, and the integral support frame 100 shortens; when the gear 330 rotates counterclockwise, the first rack 300 moves upward, the first telescopic cylinder 110 moves upward relative to the second telescopic cylinder, and the support 100 extends as a whole.

For making first flexible section of thick bamboo 110 and the atress of second flexible section of thick bamboo 120 even, offered two perpendicular grooves 320 on first flexible section of thick bamboo 110, two perpendicular grooves 320 are located on the wall that first flexible section of thick bamboo 110 is relative, have also set up two first racks 300 in the first flexible section of thick bamboo 110 simultaneously, have set up two gears 330 on the second flexible section of thick bamboo 120, two gears 330 are coaxial, two gears 330 synchronous rotation drive two first racks 300 simultaneously and remove, and then make the even atress in first flexible section of thick bamboo 110 both sides, first flexible section of thick bamboo 110 and the flexible section of thick bamboo 120 of second rise and descend more steadily.

It should be noted that, there are many structures for realizing the expansion and contraction of the support frame 100, for example, the electric control expansion cylinder, the electric control hydraulic cylinder, etc. can all realize the relative movement of the first expansion cylinder 110 and the second expansion cylinder 120, so that the overall height of the support frame 100 is changed, and detailed descriptions thereof are omitted herein.

In a further embodiment, the first telescopic cylinder 110 and the second telescopic cylinder 120 are provided with grooves, the grooves are arranged on one surface where the vertical grooves 320 are not formed, the two grooves are communicated and extend along the vertical direction, one end of the collecting box 200 is clamped in the grooves, the collecting box 200 moves along the grooves, a driving roller 370 and a driven roller 380 are arranged in the first telescopic cylinder 110 and the second telescopic cylinder 120, a belt 360 is arranged between the driving roller 370 and the driven roller 380, the belt 360 is driven to rotate when the driving roller 370 rotates, the collecting box 200 is fixed on the belt 360, and therefore the collecting box 200 is driven to slide in the grooves when the belt 360 rotates, so that the collecting box 200 moves along the vertical direction.

Specifically, the position of the collecting box 200, which is clamped with the groove, is provided with a friction block 201 and a spring 202, as shown in fig. 3, the friction block 201 is located between the groove and the collecting box 200, the friction block 201 is in sliding abutting connection with the groove, the spring 202 is located between the friction block 201 and the collecting box 200, and the arrangement of the spring 202 and the friction block 201 enables the collecting box 200 not to shake severely in the sliding process, so that stability is improved.

Specifically, a driving mechanism is disposed on the support frame 100, and the driving mechanism drives the driving roller 370 to rotate, and the driving roller 370 rotates to drive the belt 360 to rotate and further drive the collecting box 200 to move.

Specifically, the driving mechanism includes a driving motor 130, the driving motor 130 is fixedly disposed on the second telescopic cylinder 120, a rotating shaft of the driving motor 130 is connected with a driving roller 370, the driving roller 370 is driven when the driving motor 130 is started, and the driving roller 370 drives the belt 360 to rotate so that the collecting box 200 starts to move.

In a further embodiment, a hand wheel 140 is disposed on the outer peripheral surface of the second telescopic cylinder 120, the hand wheel 140 is coaxially connected with the gear 330, and the constructor rotates the hand wheel 140 to further drive the gear 330 to rotate, so as to adjust the height of the support frame 100 to adapt to indoor decoration with different heights.

In this embodiment, in order to make the tension of the belt 360 not affected when the first telescopic cylinder 110 and the second telescopic cylinder 120 are telescopic, a second rack 310 is slidably disposed in the first telescopic cylinder 110, the second rack 310 and the first rack 300 are located on the same vertical plane, the second rack 310 and the first rack 300 are disposed in central symmetry with respect to the gear 330, and the second rack 310 is also meshed with the gear 330. The first telescopic cylinder 110 is provided with a chute (not shown) extending in the vertical direction, and the second rack 310 slides in the vertical direction in the chute. In this embodiment, there are two second racks 310, the top ends of the two second racks 310 are rotatably connected with a second roller 350, the top ends and the bottom ends of the two first racks 300 are rotatably connected with a first roller 340, and a driving roller 370 and a driven roller 380 are disposed on the same horizontal plane in the bottom of the second telescopic cylinder 120, as shown in fig. 6, the driving roller 370 is located on the left side of the driven roller 380. The belt 360 is wound from the driving roller 370, around the second drum 350 at the top end of the second rack 310, around the first drum 340 at the bottom end of the first rack 300, around the first drum 340 at the top end of the first rack 300, and finally around the driven roller 380 from the drum at the top end of the first rack 300, and then around the driving roller 370. As shown in fig. 6 and 7, when the gear 330 rotates clockwise, the first rack 300 and the second rack 310 approach each other, the top and the end of the first rack 300 are lowered, that is, the position of the first drum 340 is lowered, and the top of the second rack 310 is raised, that is, the position of the second drum 350 is raised, and the first rack 300 and the second rack 310 move synchronously, so that the belt 360 wound around the first rack 300 and the second rack 310 is always in a tensioned state, so that the relative movement of the first telescopic cylinder 110 and the second telescopic cylinder 120 does not affect the rotation of the belt 360, that is, the sliding of the collecting box 200 in the vertical direction.

Meanwhile, the collecting box 200 and the exhaust pipe 240 are connected through the hose 210, the winding roller 211 is arranged in the first telescopic cylinder 110, the hose 210 is wound on the winding roller 211, when the supporting frame 100 integrally stretches, the winding roller 211 starts to unwind, and when the supporting frame 100 integrally shortens, the winding roller 211 starts to wind.

In a further embodiment, the heating assembly 220 includes a heater connected between the hose 210 and the exhaust pipe 240, and the treated air in the collection box 200 is heated by the heater during the period of entering the exhaust pipe 240 through the hose 210, and after the air is heated, some harmful substances in the air are removed by heating.

In a further embodiment, a water tank 230 is disposed between the exhaust pipe 240 and the heater, hot water is contained in the water tank 230, heated air enters the water tank 230, and the air contacts with water to further remove harmful substances in the air (some harmful substances are easily dissolved in water), and the air entering the water tank 230 is discharged from the exhaust port.

In a further embodiment, the support 100 is provided with the spray nozzle 170, the spray nozzle 170 is located at the top of the support 100, the spray nozzle 170 is connected to the exhaust pipe 240, the heated air is discharged from the spray nozzle 170 and layered with the cold air when the heated air is discharged, a little moisture is carried by the heated air when the heated air is discharged from the water, the little moisture carried by the heated air is condensed into small water drops when the heated air is discharged indoors, the small water drops drop on the ground, dust in the air can be adsorbed by the small water drops in the dropping process, and meanwhile, the ground is wetted by the small water drops on the ground, so that ground dust can be avoided.

It should be noted that, the water may be supplied to the shower nozzle 170 alone, so that the shower nozzle 170 sprays water, thereby further reducing the dust content in the room.

The following describes a specific working procedure of the air purifying device for energy-saving clean laboratory decoration provided by the application in combination with the above embodiment:

the hand wheel 140 is rotated to adjust the heights of the first telescopic cylinder 110 and the second telescopic cylinder 120, so that the whole support frame 100 is adapted to the indoor height, the top of the support frame 100 is abutted against the ceiling, and the position of the collecting box 200 is adjusted, so that the position of the collecting box 200 is at the highest position of the support frame 100.

The driving motor 130 is started, the driving motor 130 drives the collecting box 200 to start to gradually move downwards from the highest position of the supporting frame 100, meanwhile, the collecting box 200 absorbs dust-containing air, a dust removing component in the collecting box 200 processes the dust-containing air, the dust-containing air enters the heater through the hose 210 after being processed, the air is introduced into the water tank 230 after being heated, the air contacts with hot water in the water tank 230, some harmful substances in the air can be dissolved in the water, the air enters the exhaust pipe 240 from the water and is discharged into the highest position in the room, and as the air is heated, the discharged air distributes at the high position in the room to fill the space left by the collecting box 200 for absorbing the dust-containing air, the heated air is layered with the air which is not absorbed, so that air convection is not easy to form, and the influence on the dust-containing air which is not absorbed is reduced. Meanwhile, a small amount of water can be carried when hot air is discharged, the water at the junction of the hot air and cold air can be condensed into small water drops, the small water drops drop to the ground to adsorb dust in the air, and the small water drops drop to the ground to wet the ground to further prevent dust emission.

The collecting box 200 continuously absorbs the lower dust-containing air by moving the lower dust-containing air downward after the high dust-containing air is absorbed, the lower dust-containing air is settled for a period of time during the upper dust-containing air treatment, and the dust content in the air is reduced. The collecting box 200 gradually moves downwards to absorb the indoor dust-containing air from top to bottom in sequence, and when the collecting box 200 moves to be close to the ground, the movement is stopped, which indicates that the indoor dust-containing air is processed.

The technical features of the above embodiments may be arbitrarily combined, and all possible combinations of the technical features in the above embodiments are not described for brevity of description, however, as long as there is no contradiction between the combinations of the technical features, they should be considered as the scope of the description.

The foregoing examples illustrate only a few embodiments of the invention and are described in detail herein without thereby limiting the scope of the invention. It should be noted that it will be apparent to those skilled in the art that several variations and modifications can be made without departing from the spirit of the invention, which are all within the scope of the invention. Accordingly, the scope of protection of the present invention is to be determined by the appended claims.

Claims (10)

1. An energy-saving clean laboratory decoration air purification device, which is characterized by comprising:

the dust collection device comprises a support frame, wherein a collection box is arranged on the support frame and used for collecting dust-containing air, a dust collection assembly is arranged in the collection box and used for filtering the dust-containing air, the top of the support frame is abutted to an indoor ceiling, and the collection box gradually moves downwards from the top of the support frame;

the exhaust pipe is positioned at the top of the support frame and is communicated with the collecting box, and the exhaust pipe discharges the gas in the collecting box from the top of the support frame;

and the heating assembly is used for heating the gas in the exhaust pipe.

2. The energy-saving type air cleaning device for clean laboratory decoration according to claim 1, wherein the support frame is retractable in a vertical direction.

3. The energy-saving air purification device for clean laboratory decoration according to claim 2, wherein the support frame comprises a first telescopic cylinder and a second telescopic cylinder, the second telescopic cylinder is inserted into the first telescopic cylinder, a first rack is fixedly arranged on the inner wall of the first telescopic cylinder, a vertical groove is formed in the first telescopic cylinder, a gear is rotatably arranged on the second telescopic cylinder, the gear is meshed with the first rack, and the gear is rotated to drive the first rack to move so as to drive the first telescopic cylinder to move axially.

4. The energy-saving air cleaning device for clean laboratory decoration according to claim 3, wherein a driving roller and a driven roller are arranged in the first telescopic cylinder and the second telescopic cylinder, a belt is wound between the driving roller and the driven roller, and the collecting box is fixed on the belt.

5. The energy efficient clean laboratory finishing air cleaning apparatus according to claim 4, further comprising a driving mechanism for driving the driving roller to rotate.

6. The energy-saving air purification device for clean laboratory decoration of claim 5, wherein a hand wheel is fixedly arranged on a rotating shaft of the gear.

7. The energy-saving air purification device for clean laboratory decoration according to claim 1, wherein a water storage tank is connected between the heating assembly and the exhaust pipe, and the gas enters the exhaust pipe after passing through the water storage tank.

8. The energy efficient clean laboratory finishing air cleaning device according to claim 7, wherein the heating assembly comprises a heater, one end of the heater is connected to the water storage tank, and the other end of the heater is connected to the collection tank.

9. The energy efficient clean laboratory finishing air cleaning device of claim 1, wherein the dust removal assembly comprises a filter.

10. The energy-saving air cleaning device for clean laboratory decoration according to claim 1, wherein a nozzle is arranged on the supporting frame, and the nozzle is connected with the exhaust pipe.