CN114688613A

CN114688613A - Air conditioner, control method thereof and storage medium

Info

Publication number: CN114688613A
Application number: CN202011589024.7A
Authority: CN
Inventors: 汤展跃
Original assignee: GD Midea Air Conditioning Equipment Co Ltd
Current assignee: GD Midea Air Conditioning Equipment Co Ltd
Priority date: 2020-12-29
Filing date: 2020-12-29
Publication date: 2022-07-01

Abstract

The invention discloses an air conditioner, which comprises a shell, wherein the shell is provided with an air inlet part and an air outlet part, and air deflectors are arranged on the air inlet part and the air outlet part; the fan assembly is arranged in the shell, air enters the shell from the air inlet part and is discharged from the air outlet part after passing through the fan assembly, and a heat dissipation air channel is formed; and the oxygen generation device comprises an oxygen generation compressor, and the oxygen generation compressor is positioned in the heat dissipation air duct. The invention also discloses a control method of the air conditioner and a storage medium. The invention utilizes natural air to radiate the oxygen making compressor, does not need to add a radiating device, has simple structure of a radiating system, and can fully utilize the heat energy of the oxygen making compressor by reasonably arranging the air inlet part and the air outlet part.

Description

Air conditioner, control method thereof and storage medium

Technical Field

The present invention relates to the field of household appliances, and in particular, to an air conditioner, a control method thereof, and a storage medium.

Background

Along with the environmental pollution, people pay more and more attention to the living environment, so that the air conditioner gradually enters a family.

Common air conditioners include air conditioners, air purifiers, oxygen generators, and the like. In order to save costs and the space occupied by the equipment, there are also air conditioners that combine an air conditioner, an air purifier, an oxygen generator, and the like. However, such air conditioners have disadvantages, such as the heat generated by the compressor of the oxygen generator is not easy to dissipate, and a heat dissipation device is required to dissipate the heat, which in turn increases the space occupied by the air conditioner, and makes the combination of the air purifier, the air purifier and the oxygen generator useless. Therefore, the air conditioner of the type has the problem that the heat dissipation system is not optimized.

Disclosure of Invention

The invention mainly aims to provide an air conditioner, a control method thereof and a storage medium, and aims to solve the technical problem that a heat dissipation system of the air conditioner is not optimized.

To achieve the above object, the present invention provides an air conditioner including:

the air conditioner comprises a shell, wherein an air inlet part and an air outlet part are arranged on the shell, and air deflectors are arranged on the air inlet part and the air outlet part;

the fan assembly is arranged in the shell, air enters the shell from the air inlet part and is discharged from the air outlet part after passing through the fan assembly, and a heat dissipation air channel is formed; and

the oxygen making device comprises an oxygen making compressor, and the oxygen making compressor is located in the heat dissipation air duct.

Optionally, the fan assembly includes a volute and a fan, the fan is disposed in the volute, and the oxygen generation compressor is located on an air outlet side of the volute.

Optionally, the air inlet portion includes a fresh air inlet, the air outlet portion includes a fresh air outlet, and outdoor fresh air enters the housing from the fresh air inlet and is discharged from the fresh air outlet after passing through the fan assembly, so as to form a first sub-cooling air duct; and/or the presence of a gas in the gas,

the air inlet portion comprises an indoor air return inlet, the air outlet portion comprises an outdoor air outlet, indoor air enters the shell from the indoor air return inlet, passes through the fan assembly and is discharged from the outdoor air outlet, and a second sub-cooling air duct is formed.

Optionally, a mounting plate is arranged in the housing, and the mounting plate divides the inner cavity of the housing into a first cavity and a second cavity; the mounting plate is provided with an opening, the fan assembly is positioned in the first cavity, and a fan air outlet of the fan assembly is positioned at the opening so as to communicate the first cavity with the second cavity; the fresh air inlet is communicated with the first cavity, and the fresh air outlet is communicated with the second cavity; or the indoor air return opening is communicated with the first cavity, and the outdoor air outlet is communicated with the second cavity.

Optionally, a mounting plate and a partition plate are arranged in the shell, the mounting plate and the partition plate are arranged at an included angle, the inner cavity of the shell is divided into a first cavity, a second cavity and a third cavity by the clapboard and the mounting plate, the mounting plate is provided with an opening, the fan component is positioned in the first cavity, the fan outlet of the fan component is positioned at the opening, so as to communicate the first cavity with the second cavity, a wind shield which is rotatably connected with the mounting plate is arranged on the mounting plate and is used for communicating or isolating the second cavity and the third cavity, wherein the fresh air outlet is communicated with the second cavity, the outdoor air outlet is communicated with the third cavity, the indoor air return opening is communicated with the first cavity, and the fresh air inlet is communicated with the first cavity or the fresh air inlet is communicated with the third cavity.

Optionally, the fresh air inlet is communicated with the third cavity, and the partition plate is rotatably connected with the shell.

Optionally, the oxygen generating device further comprises an oxygen output pipe, and the distance between an output pipe orifice of the oxygen output pipe and the fresh air outlet is 3 mm-50 mm.

Optionally, the air conditioner further includes a heat exchange air duct and a heat exchange assembly, the heat exchange assembly is located in the heat exchange air duct, and the heat exchange air duct is communicated with the heat dissipation air duct.

Optionally, the air conditioner further comprises an air treatment module, wherein the air treatment module is arranged in the heat dissipation air duct and is positioned between the air outlet part and the oxygen generation compressor.

The present invention also provides a control method of an air conditioner based on the above air conditioner, the control method of the air conditioner including the steps of:

when an oxygen generation instruction is received, the air guide plate of the air inlet part and the air guide plate of the air outlet part of the air conditioner are controlled to be opened;

and controlling the starting of a fan assembly and an oxygen generating device of the air conditioner.

Optionally, the step of controlling the opening of the air deflector of the air inlet portion and the air deflector of the air outlet portion of the air conditioner includes:

acquiring the indoor temperature of an air conditioner;

when the indoor temperature is lower than or equal to a preset temperature, executing a first preset operation, wherein the first preset operation comprises the step of controlling the opening of an air deflector of a fresh air inlet and an air deflector of a fresh air outlet of the air conditioner;

when the indoor temperature is higher than the preset temperature, executing a second preset operation, wherein the second preset operation comprises the step of controlling the opening of an air deflector of an indoor air return inlet and an air deflector of an outdoor air outlet of the air conditioner;

the air inlet portion comprises a fresh air inlet and an indoor air return opening, and the air outlet portion comprises a fresh air outlet and an outdoor air outlet.

Optionally, after the step of performing the second preset operation, the method further includes:

after the oxygen generating device is started for a first preset time interval, switching to execute the first preset operation;

and after a second preset time interval, returning to execute the second preset operation.

The present invention also provides an air conditioner comprising a memory, a processor and a control program stored in the memory and executable on the processor, the control program, when executed by the processor, implementing the steps of the control method of the air conditioner as described above.

The present invention also provides a storage medium storing a control program that, when executed by a processor, implements the steps of the control method of the air conditioner as described above.

The air conditioner comprises a shell, an air inlet part and an air outlet part are arranged on the shell, a fan assembly is arranged in the shell, air can enter the shell from the air inlet part through the fan assembly and is discharged from the air outlet part after passing through the fan assembly, so that a heat dissipation air duct is formed, an oxygen generation compressor of an oxygen generation device is arranged in the heat dissipation air duct, the air in the heat dissipation air duct is utilized to realize heat dissipation of the oxygen generation compressor, the heat dissipation device does not need to be additionally arranged, the structure of a heat dissipation system is simple, the heat energy of the oxygen generation compressor can be fully utilized due to reasonable arrangement of the air inlet part and the air outlet part, and the purpose of optimizing the heat dissipation system is achieved.

Drawings

Fig. 1 is a schematic perspective view of an air conditioner according to an embodiment of the present invention;

FIG. 2 is a schematic view of a portion A of FIG. 1;

FIG. 3 is a schematic cross-sectional view of one embodiment of the slicing along B-B in FIG. 2;

FIG. 4 is a schematic cross-sectional view of another embodiment of the planer shown at B-B in FIG. 2;

FIG. 5 is an external view of the portion A of FIG. 1;

FIG. 6 is a perspective view of a portion A of FIG. 1;

FIG. 7 is a schematic view of the interior of portion A of FIG. 1;

FIG. 8 is a schematic view of the structure of FIG. 7 from another perspective;

FIG. 9 is a schematic view of the air treatment module of FIG. 7 from another perspective with the air treatment module removed;

fig. 10 is a schematic flowchart of an embodiment of a control method for an air conditioner according to the present invention;

fig. 11 is a detailed flowchart of step S10 in another embodiment of the control method of an air conditioner according to the embodiment of the present invention.

The implementation, functional features and advantages of the objects of the present invention will be further explained with reference to the accompanying drawings.

Detailed Description

It should be understood that the specific embodiments described herein are merely illustrative of the invention and are not intended to limit the invention.

For a better understanding of the above technical solutions, exemplary embodiments of the present disclosure will be described in more detail below with reference to the accompanying drawings. While exemplary embodiments of the present disclosure are shown in the drawings, it should be understood that the present disclosure may be embodied in various forms and should not be limited to the embodiments set forth herein. Rather, these embodiments are provided so that this disclosure will be thorough and complete, and will fully convey the scope of the disclosure to those skilled in the art.

The air conditioner provided by the invention is used for adjusting the indoor environment, such as adjusting the temperature, the humidity, the oxygen concentration, the freshness and the like. Based on the fact that the air conditioner has more functions, the fact that the number of functional modules is large means that the number of functional modules is large, therefore, due to the fact that the heat dissipation system is reasonably arranged, the service life of the air conditioner can be prolonged, the size of the air conditioner can be reduced, the reasonable heat dissipation system of the air conditioner can fully utilize heat energy, and the utilization rate of energy is improved.

Specifically, referring to fig. 1 to 3, the air conditioner includes:

the air conditioner comprises a shell 10, wherein an air inlet portion 11 and an air outlet portion 12 are arranged on the shell 10, and air deflectors (not marked in the figure) are arranged on the air inlet portion 11 and the air outlet portion 12. The air deflector is used for opening or closing the air inlet part 11 and the air outlet part 12.

The fan assembly 20 is arranged in the shell 10, air enters the shell 10 from the air inlet part 11 and is discharged from the air outlet part 12 after passing through the fan assembly 20, and a heat dissipation air channel is formed; and

the oxygen generating device (not labeled in the figure) comprises an oxygen generating compressor 30, and the oxygen generating compressor 30 is positioned in the heat dissipation air duct.

What need explain, what oxygenerator adopted is that molecular sieve pressure swing adsorption principle produces oxygen, oxygenerator includes molecular sieve part (do not mark in the figure) and oxygenerator compressor 30 to outdoor air is as the raw materials, oxygenerator compressor 30 passes through the pipe connection outdoor air, and outdoor air gets into behind the oxygenerator compressor 30, passes through the molecular sieve part is carried to oxygenerator compressor 30 compression back, and nitrogen gas and carbon dioxide etc. in the molecular sieve part adsorbed air realize with nitrogen gas, carbon dioxide and the oxygen separation in the air, arrange nitrogen gas, carbon dioxide etc. outdoor, arrange oxygen indoor, realize making oxygen to indoor.

Oxygen compressor 30 can produce the heat in the course of the work, and this embodiment is through setting up oxygen compressor 30 air conditioner 100 in the heat dissipation wind channel, in oxygen compressor 30 course of the work, through the air that flows in the heat dissipation wind channel is right oxygen compressor 30 dispels the heat, so, need not to increase heat abstractor on oxygen compressor 30 and dispel the heat to oxygen compressor 30.

When the air deflectors of the air inlet portion 11 and the air outlet portion 12 in this embodiment are opened, air enters from the air inlet portion 11 under the action of the fan assembly 20, and is discharged from the air outlet portion 12 after the oxygen generation compressor 30 is cooled in the cooling air duct. Adopt the forced air cooling heat dissipation based on this embodiment, and utilize natural air to dispel the heat, need not to increase the energy in addition, and pass through air inlet portion 11 with air-out portion 12 realizes the air cycle heat dissipation.

In addition, the air conditioner 100 in this embodiment further includes a controller and a temperature sensor, the temperature sensor is used for collecting an ambient temperature, if the indoor air is adopted for heat dissipation in this embodiment, the temperature sensor is disposed indoors, the air inlet portion 11 communicates with the indoor and the heat dissipation air duct, and the air outlet portion 12 can communicate with the outdoor or the indoor, if the indoor temperature collected by the controller is lower than the working temperature of the oxygen generation compressor 30, the air guide plates of the air inlet portion 11 and the air outlet portion 12 are controlled to be opened, the fan assembly 20 is controlled to be started, heat dissipation is performed by using the indoor air, and if the air outlet portion 12 communicates with the indoor, heat dissipation of the oxygen generation compressor 30 can be utilized to a certain extent, the indoor temperature is increased, and the energy output of the heat exchange assembly for air conditioning is reduced. When adopting outdoor air to dispel the heat if this embodiment, temperature sensor sets up outdoors, the gold phoenix does not communicate outdoors, and go out wind portion 12 can communicate indoorly, also can communicate outdoors, when the outdoor temperature that the controller was gathered was low relatively the operating temperature of oxygen generation compressor 30, then control air inlet portion 11 with the aviation baffle of wind portion 12 is opened, and control fan subassembly 20 starts, utilizes outdoor air to dispel the heat, if it is outdoor that wind portion 12 communicates, then discharges outdoors after utilizing outdoor air heat dissipation, if it is indoor that wind portion 12 communicates, then to a certain extent, utilizes the heat dissipation to oxygen generation compressor 30, improves indoor temperature, reduces air conditioning's heat exchange assemblies's energy output, make full use of heat energy, avoids the waste of the energy.

In an alternative embodiment, referring to fig. 3, the air inlet portion 11 includes a fresh air inlet 111, the air outlet portion 12 includes a fresh air outlet 121, and outdoor fresh air enters the housing 10 through the fresh air inlet 111, passes through the fan assembly 20, and is discharged through the fresh air outlet 121, so as to form a first sub heat dissipation air duct.

That is the air inlet portion 11 communicates outdoors, the air outlet portion 12 communicates indoors, and the oxygen generation compressor 30 is cooled by outdoor air, and the air after absorbing heat is discharged indoors, so that indoor temperature is increased (when the indoor temperature is low, the indoor temperature is increased, and indoor comfort can be increased).

Or, in an alternative embodiment, referring to fig. 4, the air inlet portion 11 includes an indoor air return opening 112, the air outlet portion 12 includes an outdoor air outlet 122, and the indoor air enters the casing 10 from the indoor air return opening 112, passes through the fan assembly 20, and is discharged from the outdoor air outlet 122 to form a second sub-cooling air duct.

That is the air inlet portion 11 communicates indoorly, it is outdoor that the portion 12 intercommunication of going out adopts the room air to dispel the heat to oxygen generation compressor 30, then will absorb the air behind the heat and discharge outdoors, for discharging indoorly, this embodiment can avoid indoor temperature constantly to rise to influence the radiating effect of room air to oxygen generation compressor 30.

In an alternative embodiment, please refer to fig. 2 to 5 in combination, the air inlet portion 11 includes a fresh air inlet 111 and an indoor air return opening 112, the air outlet portion 12 includes the fresh air outlet 121 and the outdoor air outlet 122, outdoor fresh air enters the casing 10 from the fresh air inlet 111, passes through the fan assembly 20, and is discharged from the fresh air outlet 121, so as to form a first sub-heat dissipation air duct; indoor air enters the casing 10 through the indoor air return opening 112, passes through the fan assembly 20, and is discharged through the outdoor air outlet 122, so as to form a second sub-heat dissipation air duct.

That is, in the embodiment, two heat dissipation air ducts are provided, and one of the heat dissipation air ducts can be selected to dissipate heat of the oxygen generation compressor 30 according to the conditions of the outdoor environment and the indoor environment, so that the air conditioner 100 is adapted to more use scenes, and the adaptability of the air conditioner 100 is improved.

For example, when indoor temperature is lower, it is right to can be through first sub-heat dissipation wind channel system oxygen compressor 30 dispels the heat, first sub-heat dissipation wind channel is arranged the air after the heat absorption indoor, can promote indoor comfort level, in addition, when adopting first sub-heat dissipation wind channel to dispel the heat, can also introduce outdoor new trend, and the oxygen of oxygen output tube 31 output of oxygenerator system oxygen forms the oxygen boosting air with the new trend and joins the back, discharges indoor, improves the system oxygen effect. And when the indoor temperature is higher, the second sub-cooling air duct is used for cooling the oxygen generation compressor 30, so that the indoor temperature is prevented from being increased continuously.

In the embodiment of the invention, the air conditioner 100 is provided with the air inlet portion 11 and the air outlet portion 12 on the casing 10, the fan assembly 20 is arranged in the casing 10, air can enter the casing 10 from the air inlet portion 11 through the fan assembly 20 and is discharged from the air outlet portion 12 after passing through the fan assembly 20, so that a heat dissipation air duct is formed, the oxygen generation compressor 30 of the oxygen generation device is arranged in the heat dissipation air duct, heat dissipation of the oxygen generation compressor 30 is realized by utilizing the air in the heat dissipation air duct, a heat dissipation device is not required to be additionally arranged, the structure of the heat dissipation system is simple, and the heat energy of the oxygen generation compressor 30 can be fully utilized by reasonably arranging the air inlet portion 11 and the air outlet portion 12, so as to achieve the purpose of optimizing the heat dissipation system.

In an alternative embodiment, referring to fig. 2, 7 to 9 in combination, the fan assembly 20 includes a volute 21 and a fan 22, the fan 22 is disposed in the volute 21, and the oxygen generation compressor 30 is located on an air outlet side of the volute 21. The fan 22 during operation, fan 22 drives wind in the radiating air duct is followed the air-out side blows to air-out portion 12, will system oxygen compressor 30 sets up air-out side based on the wind speed of air-out side is great for air and system oxygen compressor 30 fully contact, improve heat exchange efficiency.

It can be understood that the air inlet portion 11 and the air outlet portion 12 can be isolated based on the fan assembly 20, so that air flows from the air inlet portion 11 to the air outlet portion 12, and air backflow is avoided. If the air inlet of the volute casing 21 is connected with the air inlet part 11 in a butt joint mode, and the air outlet of the volute casing 21 is connected with the air outlet part 12 in a butt joint mode. Alternatively, in order to increase the air flowing space and make the heat dissipation effect of the oxygen generation compressor 30 better, the embodiment of the invention includes, but is not limited to, the following two forming structures of the heat dissipation air duct.

As in the first embodiment, a mounting plate 13 is provided in the housing 10, and the mounting plate 13 divides the inner cavity of the housing 10 into a first cavity 16 and a second cavity 17; the mounting plate 13 is provided with an opening, the fan assembly 20 is located in the first cavity 16, and a fan air outlet 23 of the fan assembly 20 is located at the opening to communicate the first cavity 16 with the second cavity 17; the fresh air inlet 111 is communicated with the first cavity 16, and the fresh air outlet 121 is communicated with the second cavity 17; alternatively, the indoor air return opening 112 is communicated with the first cavity 16, and the outdoor air exhaust opening 122 is communicated with the second cavity 17.

That is, the mounting plate 13 separates the air inlet portion 11 and the air outlet portion 12 into two cavities, and after the air enters the first cavity 16 of the housing 10 from the air inlet portion 11, the air is transmitted into the second cavity 17 through the fan assembly 20, and then is discharged based on the air outlet portion 12 in the second cavity 17, wherein the oxygen generation compressor 30 is installed in the second cavity 17 and located at the fan outlet 23 of the fan assembly 20 or at the edge of the fan outlet 23. Thus, the heat dissipation air duct in this embodiment forms a structure, which can prevent the air entering from the air inlet portion 11 from being discharged from the air outlet portion 12 without passing through the oxygen generation compressor 30 or without fully contacting and exchanging heat with the oxygen generation compressor 30, thereby reducing the heat dissipation effect.

As in the second embodiment, the present embodiment is suitable for the embodiment in which the air inlet portion 11 includes the fresh air inlet 111 and the indoor air return opening 112, and the air outlet portion 12 includes the fresh air outlet 121 and the outdoor air outlet 122. Based on the casing 10 has more wind gaps, in order to form the above-mentioned first sub-cooling wind channel and the second sub-cooling wind channel, in this embodiment, a mounting plate 13 and a partition plate 15 are arranged in the casing 10, the mounting plate 13 and the partition plate 15 are arranged at an included angle, based on the partition plate 15 and the mounting plate 13, the inner cavity of the casing 10 is divided into a first cavity 16, a second cavity 17 and a third cavity 18, the mounting plate 13 is provided with an opening, the fan assembly 20 is located in the first cavity 16, the fan outlet 23 of the fan assembly 20 is located at the opening to communicate the first cavity 16 with the second cavity 17, the mounting plate 13 is provided with a wind shield 14 rotatably connected with the mounting plate 13, the wind shield 14 is used for communicating or isolating the second cavity 17 and the third cavity 18, wherein the fresh air outlet 121 is communicated with the second cavity 17, the outdoor air outlet 122 is communicated with the third cavity 18, the indoor air return opening 112 is communicated with the first cavity 16, the fresh air inlet 111 is communicated with the first cavity 16, or the fresh air inlet 111 is communicated with the third cavity 18.

If, the fresh air inlet 111 is communicated with the first cavity 16, the air deflector of the fresh air inlet 111 is opened, the air deflector 14 rotates, so that the second cavity is isolated from the third cavity, outdoor fresh air enters the first cavity 16 from the fresh air inlet 111, the air in the first cavity 16 is transmitted to the second cavity 17 through the fan outlet 23 based on the fresh air component, and the air in the second cavity 17 is fully subjected to heat exchange with the oxygen generation compressor 30 and then is discharged from the fresh air outlet 121 in the second cavity 17 (at this time, the air deflector 14 isolates the second cavity 17 from the third cavity 18, so that the air in the second cavity is prevented from being discharged outdoors through the outdoor air outlet 122), and the first sub-cooling air duct is formed.

If the indoor air return opening 112 is communicated with the first cavity 16, the air deflector of the indoor air return opening 112 is opened, the air deflector 14 rotates to communicate the second cavity 17 with the third cavity 18, indoor air enters the first cavity 16 from the indoor air return opening 112, the air in the first cavity 16 is transmitted into the second cavity 17 through the fan air outlet 23 of the fresh air component, and the air in the second cavity 17 is transmitted into the third cavity 18 from the second cavity 17 after sufficient heat exchange with the oxygen generation compressor 30 and then is exhausted through the outdoor air outlet 122 in the third cavity 18 (at this time, the air deflector of the fresh air outlet 121 closes the fresh air outlet 121), so that the second sub-cooling air duct is formed.

It can be seen that this embodiment forms through simple structural arrangement first sub-heat dissipation wind channel with the sub-heat dissipation wind channel of second can reduce structural design space greatly, realizes miniaturized setting.

In a further embodiment, the fresh air inlet 111 and the fresh air outlet 121 may be disposed on a same side of the housing 10, and the indoor air return port 112 may be disposed on two opposite sides adjacent to the side where the fresh air inlet 111 is located. Based on this, referring to fig. 5, the fresh air inlet 111 is communicated with the third cavity 18, at this time, the partition plate 15 needs to be disposed to be rotatably connected to the housing 10, so that the third cavity 18 and the first cavity 16 can be conducted or closed, when the first sub-cooling air duct is formed, the partition plate 15 is rotated to conduct the first cavity 16 and the third cavity 18, and at this time, after entering from the fresh air inlet 111, the outdoor air can be transmitted to the first cavity 16 to be transmitted into the second cavity 17 through the fan assembly 20, so as to cool the oxygen generation compressor 30.

In an optional embodiment, referring to fig. 6, the oxygen generator further includes an oxygen output tube 31, and a distance between an output tube opening of the oxygen output tube 31 and the fresh air outlet 121 is 3mm to 50 mm. In a preferred embodiment, the distance between the pipe orifice and the fresh air outlet 121 is 3mm to 10 mm. The pipe orifice is close to the fresh air outlet 121, so that the difference between the oxygen concentration at the fresh air outlet 121 and the indoor oxygen concentration is greater than a preset value, the oxygen enrichment effect at the fresh air outlet 121 is obvious, meanwhile, the distance between the pipe orifice and the fresh air outlet 121 is avoided being too small, and the fire risk caused by the fact that the fresh air outlet 121 meets open fire is avoided.

The air conditioner 100 further includes a heat exchange air duct and a heat exchange assembly (not labeled in the figure), the heat exchange assembly is located in the heat exchange air duct, and the heat exchange air duct is communicated with the heat dissipation air duct. It can be understood that air conditioner 100 in this embodiment is the air conditioner, the air conditioner includes heat transfer subassembly and oxygenerator, oxygenerator sets up heat transfer subassembly's below, indoor return air inlet 112 fan subassembly 20 and heat transfer air outlet form the heat transfer wind channel, it is thus visible, in the fan subassembly 20 working process, not only can drive the air and dispel the heat to oxygenerator compressor 30 in the wind channel that dispels the heat, can also drive the air and carry out the heat transfer in heat transfer subassembly. The heat dissipation air duct of the oxygen generation compressor 30 is communicated with the heat exchange air duct of the heat exchange assembly, and the same set of fan assemblies 20 can be adopted to drive the air in the heat dissipation air duct and the air in the heat exchange air duct to flow, so that compared with the exemplary technology, the air conditioner 100 in the embodiment reduces the production cost and the installation cost of the heat dissipation fan assembly 20 of one oxygen generation compressor 30, and can reduce the occupied space of the heat dissipation fan assembly 20.

The air conditioner in this embodiment can make oxygen function and refrigeration function go on simultaneously, if start the refrigeration function, then explain that indoor initial temperature is higher, need reduce the comfort that indoor temperature promoted indoor environment this moment, consequently, when starting the system oxygen function, adopt the sub-heat dissipation wind channel of second is right system oxygen compressor 30 dispels the heat, avoids promoting indoor temperature. Namely, the air deflectors of the indoor air return opening 112 and the outdoor air outlet 122 are opened, and the indoor temperature is utilized to dissipate the heat of the oxygen generation compressor 30. And based on the air conditioner still starts the refrigeration function, then the room air gets into casing 10 based on indoor return air inlet 112 to after dispelling the heat to oxygenerator compressor 30 in the second sub-heat dissipation wind channel, partly follow outdoor air exit 122 discharges, partly blow to the heat transfer subassembly department in heat transfer wind channel, with the heat transfer subassembly heat transfer back is discharged to indoor by the heat transfer air outlet. Therefore, the indoor temperature of the heat exchange assembly is reduced, so that the indoor temperature entering from the indoor air return opening 112 is low, and the heat exchange efficiency is improved when the oxygen generation compressor 30 passes through.

In a further embodiment, the air conditioner 100 further includes an air processing module 40, the air processing module 40 includes but is not limited to a filter screen, and the air processing module 40 is disposed on the heat dissipation air duct, and is located between the air outlet portion 12 and the oxygen generation compressor 30, so that the air in the heat dissipation air duct passes through the oxygen generation compressor 30 and absorbs the heat of the oxygen generation compressor 30 to form high temperature air, and the high temperature air passes through the air processing module 40, and then the air processing module 40 can be sterilized at high temperature, or the air processing module 40 can be dried.

Therefore, based on the reasonable layout of the functional components of the air conditioner 100, the heat of the oxygen generation compressor 30 is fully utilized, the heat dissipation problem of the oxygen generation compressor 30 can be solved, and the use effect of the air conditioner 100 can be effectively improved.

The present invention also proposes the following respective embodiments of the control method of the air conditioner of the present invention based on the structures of the air conditioners in the respective embodiments described above.

In an embodiment, referring to fig. 10, a control method of an air conditioner according to the embodiment includes the following steps:

step S10, when receiving an oxygen making instruction, controlling the opening of an air deflector of an air inlet part and an air deflector of an air outlet part of the air conditioner;

and step S20, controlling the starting of the fan assembly and the oxygen generator of the air conditioner.

The air conditioner in this embodiment may be an air conditioner, or may be an air purifier, and so on, and as long as the equipment for processing air is within the protection range of this embodiment, the details are not repeated herein.

The air conditioner comprises a shell, a fan assembly and an oxygen generating device. The shell is provided with an air inlet portion and an air outlet portion, and air guide plates are arranged on the air inlet portion and the air outlet portion. The air deflector is used for opening or closing the air inlet part and the air outlet part. The fan assembly is arranged in the shell, air enters the shell from the air inlet part and is discharged from the air outlet part after passing through the fan assembly, and a heat dissipation air channel is formed. The oxygen generation device comprises an oxygen generation compressor, and the oxygen generation compressor is located in the heat dissipation air duct.

Air conditioner when opening, perhaps trigger during air conditioner's system oxygen function, judge and receive system oxygen instruction, system oxygen instruction can trigger based on the remote controller, also can trigger through the pronunciation that the user sent, perhaps based on air conditioner operation after predetermineeing time length automatic triggering. Receive the oxygen generation instruction, then judge and start oxygenerator, oxygenerator starts the back, through oxygen generation compressor compression outdoor air, then adsorb nitrogen gas and carbon dioxide based on the molecular sieve, realize oxygen separation, carry oxygen indoor again, reach the purpose to indoor oxygen generation.

The oxygen generation compressor can generate heat in the working process, the air conditioner is arranged in the heat dissipation air duct, when an oxygen generation instruction is received, the air deflector of the air inlet portion and the air deflector of the air outlet portion of the air conditioner are controlled to be opened, so that the air inlet portion and the air outlet portion of the heat dissipation air duct are conducted, at the moment, the fan assembly and the oxygen generation device of the air conditioner are controlled to be started, the fan assembly drives the air flow channel in the heat dissipation air duct, the oxygen generation compressor is cooled through flowing air in the heat dissipation air duct, and therefore the oxygen generation compressor is not required to be cooled by adding the heat dissipation device on the oxygen generation compressor, and in addition, the heat generated by the oxygen generation compressor is reasonably utilized, and the utilization rate of energy is improved.

It can be understood that, in this embodiment, the air inlet portion includes a fresh air inlet and/or an indoor air return inlet, and the air outlet portion includes a fresh air outlet and/or an outdoor air outlet.

In this embodiment, when receiving the system oxygen instruction, through control the aviation baffle that air conditioner was equipped with air inlet portion and air-out portion on the casing is opened, combines control fan subassembly work for logical air gets into in the casing from air inlet portion, and warp behind the fan subassembly by air-out portion discharges, with this formation heat dissipation wind channel, and with the system oxygen compressor of oxygenerator in the course of the work, based on it is located in the heat dissipation wind channel, utilize the flowing air in the heat dissipation wind channel to realize the heat dissipation to the system oxygen compressor, need not to increase heat abstractor in addition, and cooling system's simple structure, air inlet portion with the reasonable setting of air-out portion can make full use of the heat energy of system oxygen compressor, reaches the purpose of optimizing cooling system.

In a further embodiment, referring to fig. 11, based on the above embodiments, the step of controlling the opening of the air deflectors of the air inlet portion and the air deflectors of the air outlet portion of the air conditioner includes:

step S11, obtaining the indoor temperature of the air conditioner;

step S12, judging whether the indoor temperature is less than or equal to a preset temperature;

when the indoor temperature is less than or equal to a preset temperature, step S13, executing a first preset operation, where the first preset operation includes controlling an air deflector of a fresh air inlet and an air deflector of a fresh air outlet of the air conditioner to open;

and when the indoor temperature is higher than the preset temperature, step S14, executing a second preset operation, where the second preset operation includes controlling the opening of the air deflector of the indoor air return inlet and the air deflector of the outdoor air outlet of the air conditioner.

In this embodiment, the air conditioner the air inlet portion includes fresh air inlet and indoor return air inlet, the air outlet portion includes fresh air outlet and outdoor air outlet. And the air deflector of the fresh air inlet and the air deflector of the fresh air outlet are controlled simultaneously, and the air deflector of the indoor air return inlet and the air deflector of the outdoor air outlet are controlled simultaneously. Specifically, when the air deflector of the fresh air inlet and the air deflector of the fresh air outlet are opened simultaneously (i.e., the first preset operation is executed), outdoor fresh air enters the housing from the fresh air inlet, and is discharged from the fresh air outlet after passing through the fan assembly to form a first sub-heat dissipation air duct, so that the flowing air (outdoor fresh air) of the oxygen generation compressor in the first sub-heat dissipation air duct dissipates heat. When the air deflector of the indoor air return inlet and the air deflector of the outdoor air outlet are opened simultaneously (namely, the second preset operation is executed), indoor air enters the shell from the indoor air return inlet, and is discharged from the outdoor air outlet after passing through the fan assembly to form a second sub-heat-dissipation air duct, so that the flowing air (indoor air) in the second sub-heat-dissipation air duct of the oxygen generation compressor dissipates heat.

This embodiment is based on the structural feature of air conditioner's the sub-wind channel that looses of first heat dissipation and the sub-wind channel that looses of second combines the radiating mode of air conditioner place environment rational selection adaptation current environment right the system oxygen compressor dispels the heat, when improving the radiating effect, avoids the comfort level to the system oxygen compressor heat dissipation in-process influence environment.

Specifically, after receiving the oxygen generation instruction, the indoor temperature is acquired, and whether the air after absorbing the heat of the oxygen generation compressor is discharged indoors or outdoors is determined based on the indoor temperature. If when indoor temperature is lower, discharge the heat indoor this moment, can promote indoor temperature for indoor temperature is more comfortable, and can make heat exchange assembly reduce energy output (heat exchange assembly can be other heat transfer device's heat exchange assembly, also can be the inside heat exchange assembly who sets up of air conditioner). If when indoor temperature was higher, discharge the heat outdoor this moment, avoid the heat to make indoor temperature more and more high, influence indoor environment comfort level.

It can be seen that this embodiment combines air conditioner's structure, and the aviation baffle of reasonable control air conditioner's air inlet portion and air-out portion reaches more excellent heat utilization effect, and based on the heat with the lower air absorption oxygen generation compressor of temperature, the radiating effect is more excellent.

It can be understood that the air after absorbing the heat of the oxygen generation compressor is discharged to indoor or to outdoor judgment basis and is the comparison result of indoor temperature and preset temperature, wherein, preset temperature can be the critical temperature obtained according to experimental test, if the indoor temperature is lower than the critical temperature, switch on the heat dissipation of the first sub-heat dissipation air channel, the heat dissipation effect of the air conditioner is good, and the adverse effect to the indoor environment comfort level is small, otherwise switch on the heat dissipation of the second sub-heat dissipation air channel.

Or, the preset temperature may also be an outdoor temperature, that is, the indoor temperature is compared with the outdoor temperature, and if the indoor temperature is lower than the outdoor temperature, it indicates that the indoor environment is not affected when heat is discharged indoors. On the contrary, if the indoor temperature is higher than the outdoor temperature, it means that the indoor environment temperature is higher if the heat is discharged indoors, which seriously affects the indoor comfort.

Therefore, in this embodiment, when the indoor temperature is less than or equal to the preset temperature, the air deflector of the fresh air inlet and the air deflector of the fresh air outlet of the air conditioner are controlled to be opened; and when the indoor temperature is higher than the preset temperature, controlling the air deflector of the indoor air return inlet and the air deflector of the outdoor air outlet of the air conditioner to be opened. The heat dissipation mode that rationally selects adaptation current environment according to air conditioner place environment is right the system oxygen compressor dispels the heat, improves the radiating effect.

In a further embodiment, after the step of executing the second preset operation, the method further includes:

When the second preset operation is executed, namely when the air deflector of the indoor air return inlet and the air deflector of the outdoor air outlet are opened, the air deflector of the fresh air inlet and the air deflector of the fresh air outlet are closed, and at the moment, in the oxygen generation process of the oxygen generation device, oxygen cannot be discharged into the room through the fresh air inlet. Thus, in some embodiments, the oxygen output conduit of the oxygen generator can be connected to a snout device and extend out of the housing. In this embodiment, the first preset operation and the second preset operation are periodically switched to be executed, so that the air conditioner can open the air deflector based on the fresh air outlet to discharge oxygen and fresh air into the room when executing the first preset operation; and when the second preset operation is executed, the heat of the oxygen generation compressor is radiated.

Specifically, after the oxygen generation device is started for a first preset time interval, the air deflector of the fresh air inlet and the air deflector of the fresh air outlet are controlled to be opened, and the air deflector of the outdoor air outlet is controlled to be closed (or the air deflectors of the outdoor air outlet and the indoor air return inlet are both closed), so that oxygen and fresh air are conveyed indoors while the oxygen generation compressor is cooled based on air in the first sub cooling air duct; and after the air deflector of the fresh air outlet is opened for a second preset time interval, the outdoor air outlet is controlled to be opened, and the air deflectors of the fresh air inlet and the fresh air outlet are controlled to be closed, so that the oxygen generation compressor is cooled based on the air in the second sub cooling air duct.

This embodiment is through the mode that the first operation of predetermineeing of periodic switch execution and the second operation of predetermineeing, for the mode that sets up the nasal smell device, this embodiment structure is more simplified, and new trend and oxygen collect into the oxygen-enriched air in new trend air outlet department, directly carry indoorly, can satisfy the requirement of indoor all people to the air (the nasal smell device can only personally use).

Furthermore, the present invention also provides a storage medium storing a control program that realizes the respective steps of the control method of the air conditioner as described above when executed by a processor.

It should be noted that the above is only a preferred embodiment of the present invention, and not intended to limit the scope of the present invention, and all equivalent structures or equivalent flow transformations made by using the contents of the specification and the drawings, or applied directly or indirectly to other related technical fields, are included in the scope of the present invention.

Claims

1. An air conditioner characterized by comprising:

2. The air conditioner of claim 1, wherein the fan assembly includes a volute and a fan disposed within the volute, the oxygen generation compressor being located on an air outlet side of the volute.

3. The air conditioner according to claim 1, wherein the air inlet portion comprises a fresh air inlet, the air outlet portion comprises a fresh air outlet, and outdoor fresh air enters the housing from the fresh air inlet and is discharged from the fresh air outlet after passing through the fan assembly to form a first sub-cooling air duct; and/or the presence of a gas in the gas,

4. The air conditioner of claim 3, wherein a mounting plate is disposed within the housing, the mounting plate dividing the interior chamber of the housing into a first cavity and a second cavity; the mounting plate is provided with an opening, the fan assembly is positioned in the first cavity, and a fan air outlet of the fan assembly is positioned at the opening so as to communicate the first cavity with the second cavity; the fresh air inlet is communicated with the first cavity, and the fresh air outlet is communicated with the second cavity; or the indoor air return opening is communicated with the first cavity, and the outdoor air outlet is communicated with the second cavity.

5. The air conditioner of claim 3, wherein a mounting plate and a partition plate are provided in the housing, the mounting plate and the clapboard are arranged at an included angle, the clapboard and the mounting plate divide the inner cavity of the shell into a first cavity, a second cavity and a third cavity, the mounting plate is provided with an opening, the fan component is positioned in the first cavity, the fan outlet of the fan component is positioned at the opening, so as to communicate the first cavity with the second cavity, a wind shield which is rotatably connected with the mounting plate is arranged on the mounting plate and is used for communicating or isolating the second cavity and the third cavity, wherein the fresh air outlet is communicated with the second cavity, the outdoor air outlet is communicated with the third cavity, the indoor air return opening is communicated with the first cavity, and the fresh air inlet is communicated with the first cavity or the fresh air inlet is communicated with the third cavity.

6. The air conditioner of claim 5, wherein said fresh air intake opening is in communication with said third cavity, and said partition is rotatably connected to said housing.

7. The air conditioner as claimed in claim 3, wherein the oxygen generator further comprises an oxygen output tube, and the distance between the outlet orifice of the oxygen output tube and the fresh air outlet is 3mm to 50 mm.

8. The air conditioner of claim 1, further comprising a heat exchange air duct and a heat exchange assembly, wherein the heat exchange assembly is located within the heat exchange air duct, and the heat exchange air duct is in communication with the heat dissipation air duct.

9. The air conditioner of claim 1, further comprising an air handling module disposed within the cooling air duct between the air outlet portion and the oxygen generation compressor.

10. A control method of an air conditioner, characterized in that the control method of the air conditioner is applied to the air conditioner of any one of claims 1 to 9, and the control method of the air conditioner includes the steps of:

11. The method of claim 10, wherein the step of controlling the opening of the air guide plate of the inlet portion and the air guide plate of the outlet portion of the air conditioner comprises:

acquiring the indoor temperature of an air conditioner;

12. The control method of an air conditioner according to claim 11, further comprising, after the step of performing the second preset operation:

13. An air conditioner, characterized in that the air conditioner includes a memory, a processor, and a control program stored in the memory and executable on the processor, the control program, when executed by the processor, implementing the steps of the control method of the air conditioner according to any one of claims 10 to 12.

14. A storage medium characterized by storing a control program which, when executed by a processor, realizes each step of the control method of an air conditioner according to any one of claims 10 to 12.