CN214276032U - Fresh air system - Google Patents
Fresh air system Download PDFInfo
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- CN214276032U CN214276032U CN202023249700.4U CN202023249700U CN214276032U CN 214276032 U CN214276032 U CN 214276032U CN 202023249700 U CN202023249700 U CN 202023249700U CN 214276032 U CN214276032 U CN 214276032U
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Abstract
The utility model discloses a new trend system, it includes anion excitation device, anion excitation device includes barrel, ponding dish and shower nozzle, the barrel has the inner chamber, the shower nozzle with the ponding dish sets up the inner chamber, new trend system still includes the compressor, the compressor sets up the inner chamber, the shower nozzle the compressor with the ponding dish is from last to arranging in proper order down. This new trend system utilizes anion excitation device's current structure and space, sets up the compressor in the barrel, reduces the part setting for the compact structure of new trend system. Because the compressor sets up in the below of shower nozzle, on the compressor can be spouted to some of shower nozzle spun aquatic, carries out the watering cooling to the compressor, improves the operational environment of compressor, prolongs the life of compressor.
Description
Technical Field
The utility model relates to a new trend system.
Background
In modern life, people have increasingly high requirements on health, and particularly in cities, people cannot feel fresh and pollution-free, like clean air in forest. Typically, the average concentration of negative oxygen ions in air on land is 650/cm3The average concentration of negative oxygen ions in the air in the forest community is 5000/cm3Up to 10000 pieces/cm3The above. Therefore, more and more new fans or air purifiers are appearing in the market to create comfortable air environment indoors in a man-made manner. Generally, the inside of the fresh air fan of the type can be provided with the negative oxygen ion exciter to emit a certain amount of negative oxygen ions into the air, so that the environment of the nature negative oxygen ions is simulated, the air can be purified, dust can be adsorbed, and the air quality in the environment is improved.
The negative oxygen ion exciter can generate more negative oxygen ions by adopting a water excitation mode, and the propagation distance and the concentration of the negative oxygen ions are better than those of the negative oxygen ions generated by an electric excitation mode, so the negative ion exciter of the existing fresh air system usually adopts the water excitation mode. Specifically, the spray head is used for spraying water into the air duct, so that water is impacted on the inner wall of the air duct to generate a large amount of negative oxygen ions. The existing fresh air system also comprises a compressor, the compressor is arranged in the fresh air system, and the compressor can generate a large amount of heat during working. How to rapidly dissipate heat of the compressor in a narrow space inside the fresh air system is a key point of attention of research and development designers.
SUMMERY OF THE UTILITY MODEL
The utility model relates to a solve the heat dissipation problem of the compressor in the new trend system, provide a new trend system.
The utility model discloses an above-mentioned technical problem is solved through following technical scheme:
the utility model provides a new trend system, its includes anion excitation device, anion excitation device includes barrel, ponding dish and shower nozzle, the barrel has the inner chamber, the shower nozzle with the ponding dish sets up the inner chamber, new trend system still includes the compressor, the compressor sets up the inner chamber, the shower nozzle the compressor with the ponding dish is from last to arranging down in proper order.
In this scheme, this new trend system utilizes anion excitation device's current structure and space, with the compressor setting in the barrel, reduces the part setting for the compact structure of new trend system. Because the compressor sets up in the below of shower nozzle, on the compressor can be spouted to some of shower nozzle spun aquatic, carries out the watering cooling to the compressor, improves the operational environment of compressor, prolongs the life of compressor. Meanwhile, a small amount of water is gasified on the surface of the hot compressor, and the gasified hot steam flows indoors along with fresh air, so that the temperature of the fresh air input indoors is increased, and a warm air effect can be achieved.
Preferably, the fresh air system further comprises a dehumidifying device, and the compressor is a compressor of the dehumidifying device.
In the scheme, the fresh air system integrates the dehumidifying device and the negative ion excitation device in the system. When the air humidity is high, the air can be dehumidified by using a condensing plate of the dehumidifying device, the dehumidified dry air enters the negative ion excitation device, and the negative ion excitation device generates negative oxygen ions and adjusts the air humidity to a reasonable range in a water spraying mode. If when air humidity is big, directly produce negative oxygen ion through water excitation's mode, then can cause the further increase of air humidity or produce water smoke, influence people's travelling comfort.
Preferably, the fresh air system further comprises a water storage tank arranged below the water collecting disc, a water outlet is arranged at the bottom of the water collecting disc, and the water outlet is communicated to the water storage tank through a pipeline.
In this scheme, shower nozzle spun water is collected by establishing the ponding dish of below, at last the pipeline flows into the storage water tank, and the water pump in with the storage water tank is to the shower nozzle, and the water is realized to reciprocal circulation, the water economy resource. Preferably, a purifying device is arranged before water in the water collecting disc flows into the water storage tank, and the water flows into the water storage tank after being purified by the purifying device, so that the quality of the water is improved. In the process of spraying water by the spray head, as the air can take away a part of water quantity, in order to keep enough water in the water storage tank, the water storage tank can be communicated with an external water source, and when the water level in the water storage tank is lower than a set water level, water can be supplemented into the water storage tank through an intelligent control system.
Preferably, the anion excitation device further comprises a water pump, one end of the water pump is connected with the spray head, and the other end of the water pump is used for being connected with the water storage tank.
Preferably, the dehumidifying apparatus further comprises:
the condensation plate is arranged at an air inlet of the negative ion excitation device;
and the condensation pipe penetrates through the condensation plate and is communicated to the compressor.
In the scheme, the refrigerant is conveyed in the condensing pipe, the refrigerant exchanges heat with air through the condensing pipe and the condensing plate, and after hot air meets the condensing plate, water vapor in the air can be condensed into liquid water drops to be separated from the air, so that the aim of dehumidification is fulfilled.
Preferably, the air inlet of the negative ion excitation device is arranged at the lower end of the cylinder, the air outlet of the negative ion excitation device is arranged at the upper end of the cylinder, the air inlet and the air outlet are communicated through the inner cavity, and the condensation plate is obliquely arranged in the inner cavity and positioned above the air inlet of the negative ion excitation device.
In this scheme, the air intake setting is at the lower extreme of barrel, and the air outlet setting can utilize the siphon effect of passageway, is convenient for exhaust in the upper end of barrel. The condensation plate is obliquely arranged above the air inlet, so that air flowing in from the air inlet flows through the surface of the condensation plate, and the dehumidification effect is improved.
Preferably, the nozzle and the air inlet of the negative ion excitation device are arranged on the same side of the inner cavity.
In this scheme, adopt above-mentioned structural style, prevent that shower nozzle spun rivers from flowing into anion excitation device's air intake, and then damage or corrosion set up the equipment at the air intake lower extreme.
Preferably, the dehumidification device further comprises a water baffle, and the water baffle is arranged between the spray head and the condensation plate and covers above the air inlet of the negative ion excitation device.
In this scheme, the shower nozzle has a small amount of water from the spout water clock sometimes near the nozzle when spraying water, owing to be provided with the condensing plate in the below of nozzle, avoids water direct flow to on the condensing plate. In addition, an air inlet is arranged below the condensing plate, and water can directly flow into the air inlet if the condensing plate is not shielded by a water baffle. The condensate water can be drained to the upper part of the water accumulation disc through the water baffle, so that a smaller water accumulation disc can be arranged, and the structure is optimized.
Preferably, a plurality of heat exchange fins are stacked to form the condensation plate, the condensation pipe penetrates through the heat exchange fins along the stacking direction, and a gap is formed between every two adjacent heat exchange fins.
In this scheme, adopt above-mentioned structural style to the surface area of increase condensing plate, the air can flow through along the clearance between adjacent heat transfer fin, and the air fully contacts with a plurality of heat transfer fins, improves dehumidification effect.
Preferably, the inner wall of barrel is equipped with excites the board, excite the one end of board connect in the inner wall of barrel, excite the other end of board to the inner chamber of barrel extends the setting, shower nozzle spun water cover in excite the board, the compressor setting is in excite the below of board.
In the scheme, water sprayed from the spray head impacts on the excitation plate to generate negative oxygen ions. The compressor is arranged below the excitation plate, and the space of the same cylinder can be utilized, so that the structure is compact; and the water sprayed by the spray head falls nearby the compressor more to reduce the temperature, so that the energy consumption is saved.
On the basis of the common knowledge in the field, the above preferred conditions can be combined at will to obtain the preferred embodiments of the present invention.
The utility model discloses an actively advance the effect and lie in: this new trend system utilizes anion excitation device's current structure and space, sets up the compressor in the barrel, reduces the part setting for the compact structure of new trend system. Because the compressor sets up in the below of shower nozzle, on the compressor can be spouted to some of shower nozzle spun aquatic, carries out the watering cooling to the compressor, improves the operational environment of compressor, prolongs the life of compressor. Meanwhile, a small amount of water is gasified on the surface of the hot compressor, and the gasified hot steam flows indoors along with fresh air, so that the temperature of the fresh air input indoors is increased, and a warm air effect can be achieved.
Drawings
Fig. 1 is a schematic structural diagram of a first view angle of a fresh air system according to a preferred embodiment of the present invention.
Fig. 2 is a schematic structural diagram of a second view angle of the fresh air system according to a preferred embodiment of the present invention.
Fig. 3 is a schematic structural diagram of a first internal view angle of the fresh air system with the dehumidifying device removed according to a preferred embodiment of the present invention.
Fig. 4 is a schematic structural diagram of a second internal view angle of the fresh air system with the dehumidifying device removed according to a preferred embodiment of the present invention.
Fig. 5 is a schematic structural diagram of a first view angle of the dehumidifying apparatus and the anion generating apparatus according to a preferred embodiment of the present invention.
Fig. 6 is a schematic structural diagram of a second viewing angle of the dehumidifying apparatus and the anion generating apparatus according to a preferred embodiment of the present invention.
Fig. 7 is a schematic structural diagram of a third viewing angle of the dehumidification device and the negative ion generation device according to a preferred embodiment of the present invention.
Fig. 8 is a schematic structural view of a dehumidifying apparatus and an anion generating apparatus with a barrel removed according to a preferred embodiment of the present invention.
Fig. 9 is a partial schematic structural view of a first viewing angle of the heat exchange fin and the condenser tube according to a preferred embodiment of the present invention.
Fig. 10 is a partial schematic structural view of a second viewing angle of the heat exchange fin and the condenser tube according to a preferred embodiment of the present invention.
Description of reference numerals:
Anion excitation device 10
Fresh air device inlet 301
Return air inlet 302
Fresh air system outlet 100
Detailed Description
The present invention will be more clearly and completely described below by way of examples and with reference to the accompanying drawings, but the present invention is not limited thereto.
As shown in fig. 1 to 10, the present embodiment discloses a fresh air system, and the fresh air system 1 includes an anion excitation device 10 and a dehumidification device 20. The negative ion excitation device 10 comprises a cylinder body 101, a water accumulation disc 204 and a spray head 102. Barrel 101 has an interior chamber in which spray head 102 and drip tray 204 are disposed. The dehumidifying device 20 of the fresh air system 1 comprises a compressor 203, the compressor 203 is arranged in an inner cavity, and the spray head 102, the compressor 203 and the water accumulation disc 204 are sequentially arranged from top to bottom. The air flow direction 200 is indicated by the arrows labeled in fig. 3-5. In other embodiments, the compressor may also be a compressor of a refrigeration system.
In this embodiment, this new trend system 1 utilizes the existing structure and the space of anion excitation device 10, sets up compressor 203 in barrel 101, reduces the component setting for new trend system 1's compact structure. Because the compressor 203 is arranged below the nozzle 102, a part of the water sprayed by the nozzle 102 can be sprayed onto the compressor 203, so as to spray water to the compressor 203 for cooling, improve the working environment of the compressor 203, and prolong the service life of the compressor 203. Meanwhile, a small amount of water is gasified on the surface of the hot compressor 203, and the gasified hot steam flows indoors along with fresh air, so that the temperature of the fresh air input indoors is increased, and a warm air effect can be achieved.
When the air humidity is high, the condensing plate 201 of the dehumidifying device 20 can be used for firstly dehumidifying the air, the dehumidified dry air enters the negative ion excitation device 10, and the negative ion excitation device 10 not only generates negative oxygen ions, but also adjusts the air humidity to a reasonable range in a water spraying manner. If when air humidity is big, directly produce negative oxygen ion through water excitation's mode, then can cause the further increase of air humidity or produce water smoke, influence people's travelling comfort.
As shown in fig. 5-7, the air inlet 106 of the negative ion excitation device 10 is disposed at the lower end of the cylinder 101, the air outlet 107 of the negative ion excitation device 10 is disposed at the upper end of the cylinder 101, and the air inlet 106 and the air outlet 107 are communicated through an inner cavity. The air inlet 106 is arranged at the lower end of the cylinder body 101, and the air outlet 107 is arranged at the upper end of the cylinder body 101, so that the siphon effect of the channel can be utilized to facilitate air exhaust.
The dehumidifying apparatus 20 further includes a condensing plate 201 and a condensing duct 202. The condensing plate 201 is disposed at the air inlet 106 of the anion excitation device 10, and the condensing tube 202 penetrates through the condensing plate 201 and communicates with the compressor 203. The condensing pipe 202 carries the refrigerant, the refrigerant exchanges heat with the air through the condensing pipe 202 and the condensing plate 201, and after the hot air meets the condensing plate 201, the water vapor in the air is condensed into liquid water drops to be separated from the air, so that the purpose of dehumidification is achieved. Preferably, the condensation plate 201 is obliquely arranged in the inner cavity and above the air inlet 106 of the negative ion excitation device 10, so that the air flowing from the air inlet 106 flows through the surface of the condensation plate 201, and the dehumidification effect is improved; at the same time, the inner space of the cylinder 101 can be fully utilized to arrange the condensing plate 201 as large as possible.
As shown in fig. 9 and 10. A plurality of heat transfer fins 206 pile up the setting in order to form condensing plate 201, and heat transfer fins 206 are worn to locate along piling up the direction by condenser pipe 202, are equipped with the clearance between the adjacent heat transfer fins 206 to increase condensing plate 201's surface area, the air can follow the clearance between adjacent heat transfer fins 206 and flow through, and the air fully contacts with a plurality of heat transfer fins 206, improves dehumidification effect.
As shown in fig. 8. The spray head 102 is arranged in the inner cavity of the cylinder 101, and the spray opening of the spray head 102 faces the inner wall of the cylinder 101. The nozzle 102 and the air inlet 106 of the anion excitation device 10 are disposed on the same side of the inner cavity, so as to prevent water sprayed from the nozzle 102 from flowing into the air inlet 106 of the anion excitation device 10 and damaging or rusting equipment disposed at the lower end of the air inlet 106.
Preferably, the inner wall of the cylinder 101 is provided with an excitation plate 103, one end of the excitation plate 103 is connected to the inner wall of the cylinder 101, the other end of the excitation plate 103 extends towards the inner cavity of the cylinder 101, the water sprayed from the spray head 102 covers the excitation plate 103, and the compressor 203 is arranged below the excitation plate 103. The water ejected from the nozzle 102 strikes the excitation plate 103, and negative oxygen ions are generated. The compressor 203 is arranged below the exciting plate 103, the space of the same cylinder 101 can be utilized, the structure is compact, and meanwhile, more water sprayed by the spray head 102 falls near the compressor 203 for cooling, so that the energy consumption is saved.
Furthermore, the dehumidifying apparatus 20 further includes a water baffle 104, and the water baffle 104 is disposed between the spray head 102 and the condensation plate 201 and covers above the air inlet 106 of the negative ion excitation device 10. When the spray head 102 sprays water, a small amount of water may leak from the spray opening near the spray nozzle, and the condensation plate 201 is disposed below the spray nozzle, so that the water is prevented from directly flowing onto the condensation plate 201. In addition, an air inlet 106 is arranged below the condensation plate 201, and if the condensation plate is not shielded by the water baffle plate 104, water can directly flow into the air inlet 106. The condensate water can be drained to the upper part of the water accumulation disc 204 by arranging the water baffle 104, and the structure can be optimized by arranging the small water accumulation disc 204.
As shown in fig. 3, the negative ion excitation device 10 further includes a water pump 105, one end of the water pump 105 is connected to the spray head 102, and the other end of the water pump 105 is used for connecting to the water storage tank 40. The fresh air system 1 further comprises a water storage tank 40 arranged below the water accumulation disc 204, a water outlet is arranged at the bottom of the water accumulation disc 204 and communicated to the water storage tank 40 through a pipeline 205. The water sprayed from the spray head 102 is collected by the water collecting tray 204 arranged below and finally flows into the water storage tank 40 through the pipeline 205, the water pump 105 pumps the water in the water storage tank 40 to the spray head 102 for reciprocating circulation, thereby realizing the cyclic utilization of the water and saving the water resource.
Further, a purifying device is arranged before water in the water accumulation plate 204 flows into the water storage tank 40, and the water flows into the water storage tank 40 after being purified by the purifying device, so that the quality of the water is improved. In the process of spraying water by the spray head 102, since a part of water quantity can be taken away by air, in order to keep enough water in the water storage tank 40, the water storage tank 40 can be communicated with an external water source, and when the water level in the water storage tank 40 is lower than a set water level, water can be supplemented into the water storage tank 40 through an intelligent control system.
The fresh air system 1 further comprises a fresh air device 30, an outlet of the fresh air device 30 is communicated with an inlet of the anion excitation device 10, and an inlet 301 of the fresh air device is formed in the outer surface of the fresh air system 1. The fresh air from outside enters the internal channel of the fresh air system 1 through the fresh air device inlet 301 and is finally discharged from the fresh air system outlet 100. A return air inlet 302 and a return air outlet 303 are also arranged on the outer surface of the fresh air system 1. Dirty indoor air enters the fresh air device 30 through the return air inlet 302 and is then discharged to the outside through the return air outlet 303. In the fresh air device 30, the dirty air and the fresh air exchange heat at the total heat exchanger 304, and the energy saving effect is improved.
This new trend system 1 is with new trend device 30, dehydrating unit 20 and anion excitation device 10 integration an organic whole, and anion excitation device 10, dehydrating unit 20 and new trend device 30 from last down stacking gradually the setting for whole new trend system 1 compact structure, the modularization of being convenient for has expanded the function of new trend system 1, has improved user experience. Wherein, the fresh air device 30 of this embodiment can utilize the device that can carry the new trend among the prior art.
Although specific embodiments of the present invention have been described above, it will be understood by those skilled in the art that this is by way of example only and that the scope of the invention is defined by the appended claims. Various changes and modifications to these embodiments may be made by those skilled in the art without departing from the spirit and the principles of the present invention, and these changes and modifications are all within the scope of the present invention.
Claims (10)
1. The utility model provides a new trend system, its includes anion excitation device, anion excitation device includes barrel, ponding dish and shower nozzle, the barrel has the inner chamber, the shower nozzle with the ponding dish sets up the inner chamber, a serial communication port, new trend system still includes the compressor, the compressor sets up the inner chamber, the shower nozzle the compressor with the ponding dish is from last to arranging in proper order down.
2. The fresh air system as claimed in claim 1, further comprising a dehumidifier device, wherein the compressor is a compressor of the dehumidifier device.
3. The fresh air system as claimed in claim 1, further comprising a water storage tank disposed below the water tray, wherein a water outlet is disposed at the bottom of the water tray and is communicated to the water storage tank through a pipeline.
4. The fresh air system as claimed in claim 3, wherein the negative ion excitation device further comprises a water pump, one end of the water pump is connected with the spray head, and the other end of the water pump is used for being connected with the water storage tank.
5. The fresh air system as claimed in claim 2, wherein the dehumidifying device further comprises:
the condensation plate is arranged at an air inlet of the negative ion excitation device;
and the condensation pipe penetrates through the condensation plate and is communicated to the compressor.
6. The fresh air system as claimed in claim 5, wherein the air inlet of the negative ion excitation device is disposed at the lower end of the cylinder, the air outlet of the negative ion excitation device is disposed at the upper end of the cylinder, the air inlet and the air outlet are communicated through the inner cavity, and the condensation plate is disposed in the inner cavity in an inclined manner and above the air inlet of the negative ion excitation device.
7. The fresh air system as claimed in claim 5, wherein the nozzle and the air inlet of the negative ion excitation device are disposed on the same side of the inner cavity.
8. The fresh air system as claimed in claim 5, wherein the dehumidifying device further comprises a water baffle, and the water baffle is disposed between the spray head and the condensing plate and covers above the air inlet of the negative ion excitation device.
9. The fresh air system as claimed in claim 5, wherein a plurality of heat exchange fins are stacked to form the condensing plate, the condensing tube is inserted through the heat exchange fins along a stacking direction, and a gap is formed between adjacent heat exchange fins.
10. The fresh air system as claimed in any one of claims 1 to 9, wherein an excitation plate is provided on an inner wall of the cylinder, one end of the excitation plate is connected to the inner wall of the cylinder, the other end of the excitation plate extends towards the inner cavity of the cylinder, the water sprayed from the spray head covers the excitation plate, and the compressor is provided below the excitation plate.
Priority Applications (1)
| Application Number | Priority Date | Filing Date | Title |
|---|---|---|---|
| CN202023249700.4U CN214276032U (en) | 2020-12-29 | 2020-12-29 | Fresh air system |
Applications Claiming Priority (1)
| Application Number | Priority Date | Filing Date | Title |
|---|---|---|---|
| CN202023249700.4U CN214276032U (en) | 2020-12-29 | 2020-12-29 | Fresh air system |
Publications (1)
| Publication Number | Publication Date |
|---|---|
| CN214276032U true CN214276032U (en) | 2021-09-24 |
Family
ID=77784791
Family Applications (1)
| Application Number | Title | Priority Date | Filing Date |
|---|---|---|---|
| CN202023249700.4U Active CN214276032U (en) | 2020-12-29 | 2020-12-29 | Fresh air system |
Country Status (1)
| Country | Link |
|---|---|
| CN (1) | CN214276032U (en) |
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2020
- 2020-12-29 CN CN202023249700.4U patent/CN214276032U/en active Active
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