CN113310199B - Air conditioner, control method of air conditioner, and computer-readable storage medium - Google Patents

Abstract

The invention provides an air conditioner, a control method of the air conditioner and a computer readable storage medium, wherein the air conditioner comprises: the air conditioner comprises an air conditioner body, wherein an air outlet is formed in the air conditioner body; the air outlet assembly is configured to adjust the air outlet of the air outlet and is provided with a plurality of forms; a detection device configured to be adapted to obtain an ambient temperature; and the controller is electrically connected with the air outlet assembly and controls the switching mode of the air outlet assembly according to the ambient temperature. The air outlet is provided with an air outlet component which has a plurality of modes and can change the air supply mode by switching the modes. According to the corresponding switching form of ambient temperature control air supply subassembly, and then realize multiple air supply mode through air supply subassembly, realize "long-range air supply" or "warm sufficient" air supply, and then can satisfy user's multiple demand through this air conditioner, improve user's use experience.

Description

Air conditioner, control method of air conditioner, and computer-readable storage medium

Technical Field

The present invention relates to the field of air conditioning technology, and in particular, to an air conditioner, a control method of the air conditioner, and a computer readable storage medium.

Background

In the related art, in order to avoid uneven room temperature during cooling, some air conditioners are provided with a "far air supply cooling" function. Meanwhile, in order to ensure the heating effect, part of the air conditioners are also provided with a foot warming and heating function. However, the functions of far air supply and refrigeration and foot warming and heating are required to be supported by independent structures, and are difficult to realize on one air conditioner at the same time.

Disclosure of Invention

The present invention aims to solve at least one of the technical problems existing in the prior art or related art.

To this end, a first aspect of the present invention proposes an air conditioner.

A second aspect of the present invention provides a control method of an air conditioner.

A third aspect of the present invention proposes a computer-readable storage medium.

In view of this, a first aspect of the present invention provides an air conditioner, comprising: the air conditioner comprises an air conditioner body, wherein an air outlet is formed in the air conditioner body; the air outlet assembly is configured to adjust the air outlet of the air outlet and is provided with a plurality of forms; a detection device configured to be adapted to obtain an ambient temperature; and the controller is electrically connected with the air outlet assembly and controls the switching mode of the air outlet assembly according to the ambient temperature.

In this technical scheme, the air conditioner includes the air conditioner body, is provided with the air outlet on the air conditioner body, will blow out with the air after the heat transfer of indoor heat exchanger through the air outlet in order to realize refrigeration or heating. The air outlet is provided with an air outlet component which has a plurality of modes and can change the air supply mode by switching the modes.

Specifically, the air conditioner is provided with a detection device capable of detecting the ambient temperature of the current room. According to the corresponding switching form of ambient temperature control air supply subassembly, and then realize multiple air supply mode through air supply subassembly, realize "long-range air supply" or "warm sufficient" air supply, and then can satisfy user's multiple demand through this air conditioner, improve user's use experience.

In addition, the air conditioner in the technical scheme provided by the invention can also have the following additional technical characteristics:

In the above technical solution, the plurality of modes includes a first mode and a second mode, and the controller acquires an operation mode of the air conditioner, determines the operation mode as a refrigeration mode, and controls the air outlet assembly to work in the first mode; and determining the operation mode as a heating mode, and controlling the air outlet assembly to work in a second mode.

In this embodiment, the plurality of modes includes a first mode and a second mode, and corresponds to a default air supply mode of the cooling mode and a default air supply mode of the heating mode, respectively. The first mode is a "far air supply" mode, in which rapid cooling can be achieved. The second form is a conventional heating form. When the air conditioner is operated in the cooling mode, the air outlet assembly defaults to operate in the first mode. When the air conditioner is operated in the heating mode, the air outlet component defaults to work in the second mode.

In any of the foregoing technical solutions, the multiple aspects further include a third aspect, where the determining that the operation mode is a cooling mode, and the controller controls the air outlet assembly to switch modes according to an ambient temperature, and specifically includes: acquiring a preset temperature, and calculating a difference value between the environment temperature and the preset temperature; determining that the difference value is in a first difference value range, and controlling the air outlet assembly to be switched from a first mode to a third mode; and determining that the difference value is in a second difference value range, and controlling the air outlet assembly to maintain the first form.

In this embodiment, the third mode is a normal cooling mode in which the air conditioner supplies air into the room at average. In the refrigeration mode, a difference value between the ambient temperature and a preset temperature is calculated in real time, wherein the preset temperature is a comfortable temperature. When the difference value is in the first difference value range, the fact that the temperature difference between the current room temperature and the comfortable temperature is smaller is indicated, the air outlet assembly is switched to the third mode, the air supply quantity and the air supply area are reduced, noise is reduced, and the influence of cold air on a human body is reduced. If the difference is in the second difference range, the temperature difference between the room temperature and the comfortable temperature is larger, and the air outlet component is maintained in the first form at the moment, so that the rapid refrigeration effect is ensured.

In any of the above embodiments, the obtaining device is adapted to obtain a first ambient temperature in a first range and obtain a second ambient temperature in a second range; the controller controls the switching mode of the air outlet assembly according to the ambient temperature, and the controller further comprises: determining that the first ambient temperature is less than the second ambient temperature, and controlling the air outlet assembly to work in a first mode; and determining that the first ambient temperature is greater than the second ambient temperature, and controlling the air outlet assembly to work in a third mode.

In this technical scheme, the first range is specifically a distance range closer to the air conditioner, and the second range is specifically a distance range farther from the air conditioner. When the first ambient temperature is smaller than the second ambient temperature, the remote temperature of the room is higher, and the air outlet assembly is controlled to work in a first mode so as to realize 'remote air supply', and further lower the remote temperature. And if the first ambient temperature is higher than the second ambient temperature, controlling the air outlet assembly to work in a third mode, and supplying air to the room evenly. When the air is sent averagely, the cooling capacity loss is smaller in the first range, namely in the range which is closer to the air conditioner, so that the cooling capacity in the first range is higher than that in the second range, and the room temperature balance is further realized.

In any of the above technical solutions, the plurality of modes further includes a fourth mode, and the controller controls the air outlet assembly to switch modes according to an ambient temperature, and further includes: and determining that the difference value is in a third difference value range, and controlling the air outlet assembly to work in a fourth mode.

In this embodiment, the fourth mode is a "no-sense-of-wind" mode, and in the fourth mode, the full house "no-sense-of-wind" can be realized. When the difference value is in the third difference value range, the current room temperature is in accordance with the comfortable temperature, the air outlet assembly is switched to the fourth form, the cold air is prevented from directly blowing the human body, the influence of the air conditioner on the human body is reduced on the premise that the room temperature is comfortable, and the product use experience is improved.

In any of the above technical solutions, the multiple modes further include a fifth mode, the working mode is determined to be a heating mode, and the controller controls the air outlet assembly to switch modes according to the ambient temperature, and the method further includes: and determining that the difference value is in a third difference value range, and controlling the air outlet assembly to work in a fifth mode.

In this embodiment, the fifth mode is specifically a "warm foot" air-blowing mode. When the air conditioner is operated in the heating mode, if the ambient temperature accords with the comfortable temperature, the air outlet component of the air conditioner is switched to a fifth mode, hot air is sent to the floor of a room, and the heating requirement of a user in winter is met.

In any of the above technical solutions, the air outlet assembly includes: the first air deflector is arranged in the air outlet and is suitable for rotating relative to the direction of the air outlet so as to change the air supply direction of the air outlet; the second air deflector is connected with the air conditioner body and is suitable for moving relative to the air conditioner body along the first direction so as to shade or open the air outlet air dispersing component along the second direction, is connected with the air conditioner body and is suitable for moving relative to the air conditioner body along the second direction so as to shade or open the air outlet along the first direction, and the air dispersing component is provided with an air dispersing structure which is suitable for allowing air to flow through and for allowing the air to flow through in a dispersing way.

In this embodiment, the first direction is substantially horizontal and the second direction is substantially vertical for a wall-mounted air conditioner that is mounted in standard. The air outlet assembly comprises a first air deflector, a second air deflector and an air dispersing assembly. The first air deflector is arranged in the air outlet, can rotate along an axis parallel to the air outlet, and further changes the air supply direction of the air outlet to realize 'far' air supply or 'near' air supply. The second air deflector is used for opening or closing the air outlet or shielding the air outlet in the horizontal direction. Specifically, when the second air deflector is retracted, the air outlet is completely opened, and the air outlet can be used for discharging air to the whole house. When the second air deflector stretches out, the lower side part of the air outlet is shielded, and the air outlet faces the front air outlet at the moment, so that the effect is that air is blown to the far distance of a room.

The air dispersing component can move relative to the air conditioner body, and is stored in the air conditioner body when the no-wind-sensation mode is not started. When the mode without wind sense is started, the wind dispersing component stretches out, abuts against one end of the second air deflector and shields the air outlet. The wind dispersing component is also provided with a wind dispersing structure, and the air flow passing through the wind dispersing component can be dispersed through the wind dispersing structure and can be diffused and flowed, so that no wind sense and direct blowing prevention are realized.

In any of the above technical solutions, the air conditioner body includes a casing, the casing has a front side wall and a lower side wall, and an air outlet is formed at a transition position of the front side wall of the casing and the lower side wall of the casing; the first direction faces the direction corresponding to the lower side wall, and the second direction faces the direction corresponding to the front side wall.

In this technical scheme, the air outlet specifically faces the "lower front" side of the air conditioner, and the first direction faces the direction corresponding to the lower side wall, i.e. faces the lower side of the air conditioner, and the second direction faces the direction corresponding to the front side wall, i.e. faces the front side of the air conditioner. By adjusting the air output in the first direction and the second direction, the whole air output of the air conditioner can be increased on the premise of ensuring that the air output does not directly blow the human body and realizing no wind sensation, and the refrigerating or heating efficiency of the air conditioner is improved.

In some embodiments, the housing further comprises a left end cover and a right end cover, and side air outlets are respectively arranged on the left end cover and the right end cover for lateral air outlet.

In any of the above technical solutions, the air supply assembly is in the first form, the second air deflector shields the air outlet in the second direction, the air dispersing assembly opens the air outlet in the first direction, and the first air deflector guides the air blown out from the air outlet to the first direction; the air supply assembly is in a second state, the second air deflector opens the air outlet in a second direction, the air dispersing assembly opens the air outlet in a first direction, and the first air deflector guides the air blown out from the air outlet to the direction of an included angle between the plane of the second air deflector and the plane of the air dispersing assembly; the air supply assembly is in a third form, the second air deflector opens the air outlet in the second direction, the air dispersing assembly opens the air outlet in the first direction, and the first air deflector guides the air blown out from the air outlet to the first direction; the air supply assembly is in a fourth mode, the second air deflector shields the air outlet in the second direction, the air dispersing assembly shields the air outlet in the first direction, and the first air deflector guides the air blown out from the air outlet to the first direction; the air supply assembly is in a fifth mode, the second air deflector opens the air outlet in the second direction, the air dispersing assembly shields the air outlet in the first direction, and the first air deflector guides the air blown out from the air outlet to the second direction.

In this technical scheme, when air supply assembly is in the first form, refrigerates when sending wind far away promptly, the second aviation baffle stretches out and shelters from the air outlet lower part, and the wind subassembly withdraws that looses, and the first aviation baffle guides the air-out of air outlet to the direction far away towards the room.

When the air supply assembly is in the second form, namely, the conventional heating, the second air guide plate and the air dispersing assembly are retracted, the air outlet is completely opened, and the first air guide plate guides the air outlet of the air outlet to the direction of obliquely downward, so that hot air is conveyed to the whole house.

When the air outlet assembly is in a third form, namely conventional refrigeration, the second air guide plate and the air dispersing assembly are both retracted, the air outlet is completely opened, the first air guide plate guides the air outlet of the air outlet to the direction far away from the room, and at the moment, the air conditioner conveys cold air to the whole house because of no shielding of the second air guide plate.

When the air outlet assembly is in a fourth mode, namely in a no-wind-sense mode, the second air deflector and the air dispersing assembly are both extended to shield the air outlet, the first air deflector guides the air blown by the air outlet to the direction of the air dispersing assembly, at the moment, cold air blown by the air conditioner air outlet can be dispersed by the air dispersing assembly and form disordered small air flow, the high-flow-rate cold air is prevented from directly blowing into a human body, and no wind sense of a whole house is realized.

When the air outlet assembly is in a fifth mode, namely in a foot warming mode, the second air guide plate is retracted, the air dispersing assembly extends out to shield the air outlet in the horizontal direction, and meanwhile, the first air guide plate guides the air outlet direction to the downward direction. At this time, the hot air blown out from the air outlet of the air conditioner can blow down to sound the floor, thereby realizing the foot warming effect.

In any of the above technical solutions, the second air deflector and the air dispersing component are spliced to define a cavity which is located at the outer side of the air outlet of the air conditioner and is communicated with the air outlet of the air conditioner, and two ends of the cavity along the length direction of the splicing line of the second air deflector and the air dispersing component are respectively provided with side openings, and the side openings are communicated with the cavity.

In the technical scheme, after the second air deflector is spliced with the air dispersing component, a cavity positioned outside the air outlet is formed, and side openings are formed in two sides of the cavity, so that air supply in two sides is realized. In some embodiments, a side fan can be arranged at the side opening to ensure the air output of the side air outlet.

In any of the above embodiments, the first difference range is greater than 2.5; the second difference range is greater than 1.5 and less than or equal to 2.5; the third difference range is greater than or equal to 0 and less than or equal to 1.5.

In the technical scheme, when the difference between the ambient temperature and the comfort temperature is larger than 2.5, the room temperature and the comfort temperature are determined to have larger difference. When the difference between the ambient temperature and the comfort temperature is between 1.5 and 2.5, the room temperature and the comfort temperature are considered to be less apart. When the difference between the ambient temperature and the comfort temperature is between 0 and 1.5, the room temperature is considered to correspond to the comfort temperature.

It will be appreciated that the comfort temperature and difference ranges may be freely adjusted according to the actual situation and are not limited to the numerical ranges provided above.

A second aspect of the present invention provides a control method for controlling an air conditioner provided in any one of the foregoing technical solutions, where the control method includes: acquiring an ambient temperature; and controlling the switching mode of the air outlet component of the air conditioner according to the ambient temperature.

In the technical scheme, the air outlet assembly of the air conditioner has a plurality of modes, and the air supply mode can be changed by switching the modes. Specifically, the air conditioner is provided with a detection device capable of detecting the ambient temperature of the current room. According to the corresponding switching form of ambient temperature control air supply subassembly, and then realize multiple air supply mode through air supply subassembly, realize "long-range air supply" or "warm sufficient" air supply, and then can satisfy user's multiple demand through this air conditioner, improve user's use experience.

In the above technical solution, the air outlet assembly has a first configuration and a second configuration, and before the step of obtaining the ambient temperature, the control method further includes: acquiring an operation mode of an air conditioner; determining the operation mode as a refrigeration mode, and controlling the air outlet assembly to work in a first mode; and determining the operation mode as a heating mode, and controlling the air outlet assembly to work in a second mode.

In this embodiment, the plurality of modes includes a first mode and a second mode, and corresponds to a default air supply mode of the cooling mode and a default air supply mode of the heating mode, respectively. The first mode is a "far air supply" mode, in which rapid cooling can be achieved. The second form is a conventional heating form. When the air conditioner is operated in the cooling mode, the air outlet assembly defaults to operate in the first mode. When the air conditioner is operated in the heating mode, the air outlet component defaults to work in the second mode.

In any of the above technical solutions, the air outlet assembly further has a third mode, and the step of determining that the operation mode is a refrigeration mode and controlling the switching mode of the air outlet assembly according to the ambient temperature specifically includes: acquiring a preset temperature, and calculating a difference value between the environment temperature and the preset temperature; determining that the difference value is in a first difference value range, and controlling the air outlet assembly to be switched from a first mode to a third mode; and determining that the difference value is in a second difference value range, and controlling the air outlet assembly to maintain the first form.

In this embodiment, the third mode is a normal cooling mode in which the air conditioner supplies air into the room at average. In the refrigeration mode, a difference value between the ambient temperature and a preset temperature is calculated in real time, wherein the preset temperature is a comfortable temperature. When the difference value is in the first difference value range, the fact that the temperature difference between the current room temperature and the comfortable temperature is smaller is indicated, the air outlet assembly is switched to the third mode, the air supply quantity and the air supply area are reduced, noise is reduced, and the influence of cold air on a human body is reduced. If the difference is in the second difference range, the temperature difference between the room temperature and the comfortable temperature is larger, and the air outlet component is maintained in the first form at the moment, so that the rapid refrigeration effect is ensured.

In any of the above technical solutions, the step of obtaining the ambient temperature specifically includes: acquiring a first ambient temperature in a first range and acquiring a second ambient temperature in a second range; the step of controlling the switching mode of the air outlet assembly according to the ambient temperature further comprises the following steps: determining that the first ambient temperature is less than the second ambient temperature, and controlling the air outlet assembly to work in a first mode; and determining that the first ambient temperature is greater than the second ambient temperature, and controlling the air outlet assembly to work in a third mode.

In this technical scheme, the first range is specifically a distance range closer to the air conditioner, and the second range is specifically a distance range farther from the air conditioner. When the first ambient temperature is smaller than the second ambient temperature, the remote temperature of the room is higher, and the air outlet assembly is controlled to work in a first mode so as to realize 'remote air supply', and further lower the remote temperature. And if the first ambient temperature is higher than the second ambient temperature, controlling the air outlet assembly to work in a third mode, and supplying air to the room evenly. When the air is sent averagely, the cooling capacity loss is smaller in the first range, namely in the range which is closer to the air conditioner, so that the cooling capacity in the first range is higher than that in the second range, and the room temperature balance is further realized.

In any of the above technical solutions, the air outlet assembly further has a fourth form, and the controller controls the air outlet assembly to switch forms according to the ambient temperature, and the method further includes: and determining that the difference value is in a third difference value range, and controlling the air outlet assembly to work in a fourth mode.

In this embodiment, the fourth mode is a "no-sense-of-wind" mode, and in the fourth mode, the full house "no-sense-of-wind" can be realized. When the difference value is in the third difference value range, the current room temperature is in accordance with the comfortable temperature, the air outlet assembly is switched to the fourth form, the cold air is prevented from directly blowing the human body, the influence of the air conditioner on the human body is reduced on the premise that the room temperature is comfortable, and the product use experience is improved.

In any of the above technical solutions, the air outlet assembly further has a fifth mode, determines that the working mode is a heating mode, and controls the step of switching modes of the air outlet assembly according to the ambient temperature, and further includes: and determining that the difference value is in a third difference value range, and controlling the air outlet assembly to work in a fifth mode.

In this embodiment, the fifth mode is specifically a "warm foot" air-blowing mode. When the air conditioner is operated in the heating mode, if the ambient temperature accords with the comfortable temperature, the air outlet component of the air conditioner is switched to a fifth mode, hot air is sent to the floor of a room, and the heating requirement of a user in winter is met.

In any of the above embodiments, the step of obtaining the ambient temperature is performed after the air outlet assembly is operated in the first or second mode for a predetermined period of time.

In the technical scheme, after the air conditioner is started and starts to operate in a refrigerating or heating mode, the air outlet component is controlled to maintain the initial form to work for a preset time length so as to ensure that the refrigerating and heating effects are reflected, and then the switching form of the air outlet component is controlled according to the ambient temperature so as to ensure the operation effect of the air conditioner.

In any of the above embodiments, the first difference range is greater than 2.5; the second difference range is greater than 1.5 and less than or equal to 2.5; the third difference range is greater than or equal to 0 and less than or equal to 1.5.

In the technical scheme, when the difference between the ambient temperature and the comfort temperature is larger than 2.5, the room temperature and the comfort temperature are determined to have larger difference. When the difference between the ambient temperature and the comfort temperature is between 1.5 and 2.5, the room temperature and the comfort temperature are considered to be less apart. When the difference between the ambient temperature and the comfort temperature is between 0 and 1.5, the room temperature is considered to correspond to the comfort temperature.

It will be appreciated that the comfort temperature and difference ranges may be freely adjusted according to the actual situation and are not limited to the numerical ranges provided above.

A third aspect of the present invention provides a computer-readable storage medium, on which a computer program is stored, which when executed by a processor, implements a control method of an air conditioner as provided in any one of the above-mentioned aspects, and therefore, the computer-readable storage medium includes all the advantageous effects of the control method of an air conditioner as provided in any one of the above-mentioned aspects, which are not described in detail herein.

Drawings

The foregoing and/or additional aspects and advantages of the invention will become apparent and may be better understood from the following description of embodiments taken in conjunction with the accompanying drawings in which:

fig. 1 illustrates a schematic structure of an air conditioner according to an embodiment of the present invention;

fig. 2 illustrates another structural schematic view of an air conditioner according to an embodiment of the present invention;

Fig. 3 illustrates still another structural schematic view of an air conditioner according to an embodiment of the present invention;

fig. 4 illustrates still another structural diagram of an air conditioner according to an embodiment of the present invention;

Fig. 5 illustrates still another structural diagram of an air conditioner according to an embodiment of the present invention;

fig. 6 illustrates a flowchart of a control method of an air conditioner according to an embodiment of the present invention;

fig. 7 illustrates another flowchart of a control method of an air conditioner according to an embodiment of the present invention;

fig. 8 illustrates still another flowchart of a control method of an air conditioner according to an embodiment of the present invention;

fig. 9 illustrates still another flowchart of a control method of an air conditioner according to an embodiment of the present invention;

fig. 10 illustrates still another flowchart of a control method of an air conditioner according to an embodiment of the present invention.

The correspondence between the reference numerals and the component names in fig. 1 to 5 is:

100 air conditioner body, 102 air outlet, 200 air-out subassembly, 202 first aviation baffle, 204 second aviation baffle, 206 air-out subassembly.

Detailed Description

In order that the above-recited objects, features and advantages of the present application will be more clearly understood, a more particular description of the application will be rendered by reference to the appended drawings and appended detailed description. It should be noted that, without conflict, the embodiments of the present application and features in the embodiments may be combined with each other.

In the following description, numerous specific details are set forth in order to provide a thorough understanding of the present invention, but the present invention may be practiced in other ways than those described herein, and therefore the scope of the present invention is not limited to the specific embodiments disclosed below.

An air conditioner, a control method of the air conditioner, and a computer-readable storage medium according to some embodiments of the present invention are described below with reference to fig. 1 to 10.

Example 1

As shown in fig. 1,2,3, 4 and 5, in one embodiment of the present invention, there is provided an air conditioner including: the air conditioner comprises an air conditioner body 100, wherein an air outlet 102 is formed in the air conditioner body 100; the air outlet assembly 200 is configured to adjust the air outlet of the air outlet 102, and the air outlet assembly 200 has a plurality of forms; a detection device configured to be adapted to obtain an ambient temperature; the controller is electrically connected with the air outlet assembly 200 and controls the air outlet assembly 200 to switch modes according to the ambient temperature.

In this embodiment, the air conditioner includes an air conditioner body 100, and an air outlet 102 is provided on the air conditioner body 100, and air after heat exchange with the indoor heat exchanger is blown out through the air outlet 102 to realize cooling or heating. The air outlet 102 is provided with an air outlet assembly 200, and the air outlet assembly 200 has a plurality of modes and can change the air supply mode by switching the modes.

Specifically, the air conditioner is provided with a detection device capable of detecting the ambient temperature of the current room. According to the corresponding switching form of ambient temperature control air supply subassembly, and then realize multiple air supply mode through air supply subassembly, realize "long-range air supply" or "warm sufficient" air supply, and then can satisfy user's multiple demand through this air conditioner, improve user's use experience.

Wherein "no wind sensation" is defined as follows: the "no wind sensation" is considered at this time when the wind speed is on average lower than 0.1m/s in the range of 2.5m to 3m from the air outlet of the air conditioner, or when the DR (air output ratio) value is in the range of 5 to 20 at a distance of 2.5m and below from the air outlet.

Example two

As shown in fig. 1,2, 3, 4 and 5, in one embodiment of the present invention, the plurality of modes includes a first mode and a second mode, the controller obtains an operation mode of the air conditioner, determines the operation mode to be a cooling mode, and controls the air outlet assembly 200 to operate in the first mode; the operational mode is determined to be a heating mode and the air outlet assembly 200 is controlled to operate in a second mode.

The plurality of modes further includes a third mode, and the controller controls the air outlet assembly 200 to switch modes according to the ambient temperature, specifically including: acquiring a preset temperature, and calculating a difference value between the environment temperature and the preset temperature; determining that the difference value is within a first difference value range, and controlling the air outlet assembly 200 to be switched from the first mode to the third mode; the difference is determined to be within the second difference range, and the air outlet assembly 200 is controlled to maintain the first configuration.

The plurality of modes further includes a fourth mode, and the controller controls the air outlet assembly 200 to switch modes according to the ambient temperature, and further includes: the difference is determined to be within the third difference range and the air outlet assembly 200 is controlled to operate in a fourth configuration.

The plurality of modes further includes a fifth mode, the working mode is determined to be a heating mode, and the controller controls the air outlet assembly 200 to switch modes according to the ambient temperature, and the method further includes: the difference is determined to be within the third difference range and the air outlet assembly 200 is controlled to operate in a fifth configuration.

The first difference range is greater than 2.5; the second difference range is greater than 1.5 and less than or equal to 2.5; the third difference range is greater than or equal to 0 and less than or equal to 1.5.

In this embodiment, the third mode is a normal cooling mode in which the air conditioner supplies air evenly into the room. In the refrigeration mode, a difference value between the ambient temperature and a preset temperature is calculated in real time, wherein the preset temperature is a comfortable temperature. When the difference value is within the first difference value range, the temperature difference between the current room temperature and the comfortable temperature is smaller, and the air outlet assembly 200 is switched to the third mode, so that the air supply quantity and the air supply area are reduced, on one hand, noise is reduced, and on the other hand, the influence of cold air on a human body is reduced. If the difference is within the second difference range, it indicates that the temperature difference between the room temperature and the comfort temperature is large, and the air-out assembly 200 is maintained in the first form at this time, so as to ensure the rapid cooling effect.

The first range is specifically a distance range closer to the air conditioner, and the second range is specifically a distance range farther from the air conditioner. When the first ambient temperature is less than the second ambient temperature, the room remote temperature is higher, and the air outlet assembly 200 is controlled to operate in the first mode to realize "remote air supply" so as to reduce the remote temperature. If the first ambient temperature is greater than the second ambient temperature, the air outlet assembly 200 is controlled to operate in a third configuration to provide an average supply of air into the room. When the air is sent averagely, the cooling capacity loss is smaller in the first range, namely in the range which is closer to the air conditioner, so that the cooling capacity in the first range is higher than that in the second range, and the room temperature balance is further realized.

The fourth mode is a "no-sense-of-wind" mode, and in the fourth mode, the full house "no-sense of wind" can be realized. When the difference value is in the third difference value range, the current room temperature is in accordance with the comfortable temperature, and the air outlet assembly 200 is switched to the fourth form, so that cold air is prevented from directly blowing the human body, the influence of the air conditioner on the human body is reduced on the premise that the room temperature is comfortable, and the product use experience is improved.

The fifth mode is specifically a "warm foot" air-blowing mode. When the air conditioner is operated in the heating mode, if the ambient temperature meets the comfort temperature, the air outlet assembly 200 of the air conditioner is switched to the fifth mode, and hot air is sent to the floor of the room, so that the heating requirement of the user in winter is met.

When the difference between the ambient temperature and the comfort temperature is greater than 2.5, the room temperature and the comfort temperature are considered to be greatly different. When the difference between the ambient temperature and the comfort temperature is between 1.5 and 2.5, the room temperature and the comfort temperature are considered to be less apart. When the difference between the ambient temperature and the comfort temperature is between 0 and 1.5, the room temperature is considered to correspond to the comfort temperature.

It will be appreciated that the comfort temperature and difference ranges may be freely adjusted according to the actual situation and are not limited to the numerical ranges provided above.

Example III

As shown in fig. 1, 2, 3, 4 and 5, in one embodiment of the present invention, the air outlet assembly 200 includes: the first air deflector 202 is disposed in the air outlet 102, and the first air deflector 202 is adapted to rotate relative to the direction of the air outlet 102 to change the air supply direction of the air outlet 102; the second air deflector 204 is connected to the air conditioning body 100 and adapted to move in a first direction relative to the air conditioning body 100 to block or open the air outlet 102 in a second direction, and the air dispersing assembly 206 is connected to the air conditioning body 100 and adapted to move in a second direction relative to the air conditioning body 100 to block or open the air outlet 102 in the first direction, and the air dispersing assembly 206 has an air dispersing structure formed thereon, and the air dispersing structure is adapted to allow air flow to pass therethrough and to disperse and flow the air flow passing therethrough.

In the first configuration, as shown in fig. 3, the second air deflector 204 shields the air outlet 102 in the second direction, the air dispersing assembly 206 opens the air outlet 102 in the first direction, and the first air deflector 202 guides the air blown out from the air outlet 102 in the first direction.

In the second state, as shown in fig. 4, the second air deflector 204 opens the air outlet 102 in the second direction, the air dispersing component 206 opens the air outlet 102 in the first direction, and the first air deflector 202 guides the air blown out from the air outlet 102 to the direction of the included angle between the plane of the second air deflector 204 and the plane of the air dispersing component 206.

In the third configuration, as shown in fig. 2, the second air deflector 204 opens the air outlet 102 in the second direction, the air dispersing assembly 206 opens the air outlet 102 in the first direction, and the first air deflector 202 directs the air blown out from the air outlet 102 in the first direction.

In the fourth configuration, as shown in fig. 1, the second air deflector 204 shields the air outlet 102 in the second direction, the air dispersion member 206 shields the air outlet 102 in the first direction, and the first air deflector 202 guides the air blown out from the air outlet 102 in the first direction.

In the fifth configuration, as shown in fig. 5, the second air deflector 204 opens the air outlet 102 in the second direction, the air dispersing assembly 206 shields the air outlet 102 in the first direction, and the first air deflector 202 guides the air blown out from the air outlet 102 in the second direction.

In this embodiment, for a standard installed wall-mounted air conditioner, the first direction is generally horizontal and the second direction is generally vertical. The air outlet assembly 200 includes a first air deflection 202, a second air deflection 204, and a wind dispersion assembly 206.

The first air deflector 202 is disposed in the air outlet 102, and can rotate along an axis parallel to the air outlet 102, so as to change the air supply direction of the air outlet 102, thereby realizing "far" air supply or "near" air supply. The second air deflector 204 is used to open or close the air outlet 102 or to shield the air outlet 102 in a horizontal direction. Specifically, when the second air deflector 204 is retracted, the air outlet 102 is completely opened, and the air outlet 102 can discharge air to the whole house. When the second air deflector 204 extends, the lower side of the air outlet 102 is blocked, and the air outlet 102 is directed toward the front to supply air to the room.

The air dispersing unit 206 is movable relative to the air conditioning body 100, and when the no-air-feeling mode is not activated, the air dispersing unit 206 is housed in the air conditioning body 100. When the no-wind-sensation mode is started, the wind dispersing component 206 extends out to lean against one end of the second wind deflector 204 and shade the air outlet 102. The air dispersing component 206 is further provided with an air dispersing structure, and air flow passing through the air dispersing component 206 can be dispersed and enabled to flow in a dispersing mode through the air dispersing structure, so that no wind sense and direct blowing prevention are achieved.

The air conditioner body 102 comprises a shell, wherein the shell is provided with a front side wall and a lower side wall, and an air outlet 100 is formed at the transition position of the front side wall of the shell and the lower side wall of the shell; the first direction faces the direction corresponding to the lower side wall, and the second direction faces the direction corresponding to the front side wall.

Specifically, the air outlet 102 is specifically directed toward the "front lower" side of the air conditioner, where the first direction is directed toward the direction corresponding to the lower sidewall, i.e., toward the lower side of the air conditioner, and the second direction is directed toward the direction corresponding to the front sidewall, i.e., toward the front side of the air conditioner. By adjusting the air output in the first direction and the second direction, the whole air output of the air conditioner can be increased on the premise of ensuring that the air output does not directly blow the human body and realizing no wind sensation, and the refrigerating or heating efficiency of the air conditioner is improved.

When the air supply assembly is in the first configuration, i.e., the cooling far air supply, the second air deflector 204 extends out and shields the lower portion of the air outlet 102, the air dispersion assembly 206 is retracted, and the first air deflector 202 guides the air outlet 102 in a direction far from the room.

When the air supply assembly is in the second form, i.e. conventional heating, the second air deflector 204 and the air dispersing assembly 206 are retracted, the air outlet 102 is completely opened, and the first air deflector 202 guides the air outlet 102 to the direction of "obliquely downward", and at this time, hot air is delivered to the whole house.

When the air outlet assembly 200 is in the third mode, i.e. conventional refrigeration, the second air deflector 204 and the air dispersing assembly 206 are both retracted, the air outlet 102 is completely opened, the first air deflector 202 guides the air outlet of the air outlet 102 to the direction far away from the room, and at this time, the air conditioner delivers cold air to the whole house because of no shielding of the second air deflector 204.

When the air outlet assembly 200 is in the fourth mode, i.e. in the no-wind-sensation mode, the second air deflector 204 and the air dispersing assembly 206 extend to shield the air outlet 102, the first air deflector 202 guides the air blown from the air outlet 102 to the direction of the air dispersing assembly 206, and at this time, the cold air blown from the air conditioner air outlet 102 is dispersed by the air dispersing assembly 206 and forms disordered small air flow, so that the high-flow cold air is prevented from directly blowing the human body, and no wind sensation is realized in the whole house.

When the air outlet assembly 200 is in the fifth configuration, i.e., the foot warming mode, the second air deflection 204 is retracted, the air dispersion assembly 206 extends to block the air outlet 102 in a horizontal direction, and the first air deflection 202 directs the air outlet in a "downward" direction. At this time, the hot air blown out from the air outlet 102 of the air conditioner will blow down to the floor, thereby achieving the effect of "warming feet".

Example IV

As shown in fig. 1, in one embodiment of the present invention, the second air deflector 204 and the air dispersing component 206 are combined to define a cavity that is located outside the air-conditioning air outlet 102 and is communicated with the air-conditioning air outlet 102, and two ends of the cavity along the length direction of the combining line of the second air deflector 204 and the air dispersing component 206 are respectively formed with side openings, and the side openings are communicated with the cavity.

In this embodiment, after the second air deflector 204 is spliced with the air dispersing component 206, a cavity is formed outside the air outlet 102, and side openings are formed on two sides of the cavity, so as to realize two-side air supply. In some embodiments, a side fan can be arranged at the side opening to ensure the air output of the side air outlet.

Example five

In one embodiment of the present invention, control logic of an air conditioner will be described from a cooling mode and a heating mode, respectively.

1. When the user starts to refrigerate, the air outlet assembly is positioned at a far air supply refrigerating angle within the refrigerating preset time of the operation of the air conditioner, and the air conditioner supplies air far at the moment, so that the whole room can be cooled down quickly, and the requirement of quick cooling of the user is met.

When the running time of the air conditioner is longer than the preset time, judging the difference value between the room temperature and the set temperature or the comfortable temperature, if the difference value is in the first difference value range, the air conditioner is still in a far air supply refrigerating angle, if the difference value is in the second difference value range, the air outlet assembly swings from the previous state to the conventional refrigerating angle, and if the difference value is in the third preset range, the air outlet assembly swings from the previous state to the no-wind-sense refrigerating angle. If the non-uniformity of the far and near temperatures in the room is detected in the far air supply refrigerating angle and the conventional refrigerating angle, the far air supply angle and the conventional refrigerating angle are controlled to be mutually switched, so that the overall uniformity of the room temperature is met.

2. When a user starts heating, the air outlet component is positioned at a conventional heating angle within heating preset time of the air conditioner, and at the moment, the air conditioner sends out the maximum heating amount to quickly heat a room, so that the quick heating requirement of the user is met.

When the running time of the air conditioner is longer than the heating preset time, judging whether the room temperature reaches the comfortable temperature, if so, controlling the air outlet assembly to swing from the normal heating angle to the foot warming heating angle, and sending hot air to the floor of the room at the moment, so as to meet the heating requirement of a user in winter. If the comfortable temperature is not reached, the air outlet component maintains the normal heating angle.

In some embodiments, because the heat exchange capacity of the system is reduced as a whole in the no-wind-sensation mode, the guiding cooling capacity is concentrated on the indoor heat exchanger and cannot be fully discharged, the air conditioner can be controlled to increase the downward (the direction facing the ground) air outlet capacity, the downward flow trend of the cooling capacity is utilized to improve the cooling capacity discharge efficiency, and the system performance is improved.

In some cases, the no-wind-sensation mode may cause circulation around the air conditioner due to positive air outlet pressure and negative air return inlet pressure, resulting in reduction of overall air volume, deterioration of overall circulation of the room, and "stuffy feeling" of the user.

In order to solve the problems, differential air supply can be adopted, specifically, one part of air supply adopts large air quantity, and the other part of air supply adopts small air quantity mode, so that air flow exchange at the far and near positions of the room is promoted.

Example six

As shown in fig. 6, in one embodiment of the present invention, there is provided a control method of an air conditioner, including:

step S602, obtaining the ambient temperature;

step S604, controlling the switching mode of the air outlet component of the air conditioner according to the ambient temperature.

In this embodiment, the air outlet assembly of the air conditioner has a plurality of modes, and the air supply mode can be changed by switching the modes. Specifically, the air conditioner is provided with a detection device capable of detecting the ambient temperature of the current room. According to the corresponding switching form of ambient temperature control air supply subassembly, and then realize multiple air supply mode through air supply subassembly, realize "long-range air supply" or "warm sufficient" air supply, and then can satisfy user's multiple demand through this air conditioner, improve user's use experience.

Example seven

In one embodiment of the present invention, the air outlet assembly has a first configuration and a second configuration, and the control method further includes, prior to the step of obtaining the ambient temperature, as shown in fig. 7:

Step S702, obtaining an operation mode of an air conditioner;

step S704, determining that the operation mode is a refrigeration mode, and controlling the air outlet assembly to work in a first mode;

step S706, determining that the operation mode is a heating mode, and controlling the air outlet assembly to work in a second mode.

The air outlet assembly further has a third mode, and determines that the operation mode is a refrigeration mode, as shown in fig. 8, and the step of controlling the switching mode of the air outlet assembly according to the ambient temperature specifically includes:

Step S802, obtaining a preset temperature, and calculating a difference value between the ambient temperature and the preset temperature;

Step S804, determining that the difference value is within a first difference value range, and controlling the air outlet assembly to be switched from a first form to a third form;

Step S806, determining that the difference is within the second difference range, and controlling the air outlet assembly to maintain the first shape.

Acquiring the ambient temperature specifically comprises acquiring a first ambient temperature in a first range and acquiring a second ambient temperature in a second range; as shown in fig. 9, the step of controlling the switching mode of the air outlet assembly according to the ambient temperature further includes:

Step S902, determining that the first ambient temperature is less than the second ambient temperature, and controlling the air outlet assembly to work in a first mode;

step S904, determining that the first ambient temperature is greater than the second ambient temperature, and controlling the air outlet assembly to work in a third mode.

The air-out subassembly still has the fourth form, and the controller is according to ambient temperature control air-out subassembly switching mode, still includes: and determining that the difference value is in a third difference value range, and controlling the air outlet assembly to work in a fourth mode.

The air outlet assembly further has a fifth mode, the working mode is determined to be a heating mode, and the step of controlling the switching mode of the air outlet assembly according to the ambient temperature further comprises the following steps: and determining that the difference value is in a third difference value range, and controlling the air outlet assembly to work in a fifth mode.

And after the air outlet assembly works in the first mode or the second mode for a preset time, executing the step of acquiring the ambient temperature.

Wherein the first difference range is greater than 2.5; the second difference range is greater than 1.5 and less than or equal to 2.5; the third difference range is greater than or equal to 0 and less than or equal to 1.5.

In this embodiment, the plurality of modes includes a first mode and a second mode, which correspond to a default air supply mode of the cooling mode and a default air supply mode of the heating mode, respectively. The first mode is a "far air supply" mode, in which rapid cooling can be achieved. The second form is a conventional heating form. When the air conditioner is operated in the cooling mode, the air outlet assembly defaults to operate in the first mode. When the air conditioner is operated in the heating mode, the air outlet component defaults to work in the second mode.

The third mode is a normal cooling mode in which the air conditioner supplies air into the room evenly. In the refrigeration mode, a difference value between the ambient temperature and a preset temperature is calculated in real time, wherein the preset temperature is a comfortable temperature. When the difference value is in the first difference value range, the fact that the temperature difference between the current room temperature and the comfortable temperature is smaller is indicated, the air outlet assembly is switched to the third mode, the air supply quantity and the air supply area are reduced, noise is reduced, and the influence of cold air on a human body is reduced. If the difference is in the second difference range, the temperature difference between the room temperature and the comfortable temperature is larger, and the air outlet component is maintained in the first form at the moment, so that the rapid refrigeration effect is ensured.

The first range is specifically a distance range closer to the air conditioner, and the second range is specifically a distance range farther from the air conditioner. When the first ambient temperature is smaller than the second ambient temperature, the remote temperature of the room is higher, and the air outlet assembly is controlled to work in a first mode so as to realize 'remote air supply', and further lower the remote temperature. And if the first ambient temperature is higher than the second ambient temperature, controlling the air outlet assembly to work in a third mode, and supplying air to the room evenly. When the air is sent averagely, the cooling capacity loss is smaller in the first range, namely in the range which is closer to the air conditioner, so that the cooling capacity in the first range is higher than that in the second range, and the room temperature balance is further realized.

The fourth mode is a "no-sense-of-wind" mode, and in the fourth mode, the full house "no-sense of wind" can be realized. When the difference value is in the third difference value range, the current room temperature is in accordance with the comfortable temperature, the air outlet assembly is switched to the fourth form, the cold air is prevented from directly blowing the human body, the influence of the air conditioner on the human body is reduced on the premise that the room temperature is comfortable, and the product use experience is improved.

The fifth mode is specifically a "warm foot" air-blowing mode. When the air conditioner is operated in the heating mode, if the ambient temperature accords with the comfortable temperature, the air outlet component of the air conditioner is switched to a fifth mode, hot air is sent to the floor of a room, and the heating requirement of a user in winter is met.

After the air conditioner is started and starts to operate in a refrigerating or heating mode, the air outlet assembly is controlled to maintain the initial form to work for a preset time length so as to ensure that the refrigerating and heating effects are reflected, and then the air outlet assembly is controlled to switch the form according to the ambient temperature so as to ensure the operation effect of the air conditioner.

When the difference between the ambient temperature and the comfort temperature is greater than 2.5, the room temperature and the comfort temperature are considered to be greatly different. When the difference between the ambient temperature and the comfort temperature is between 1.5 and 2.5, the room temperature and the comfort temperature are considered to be less apart. When the difference between the ambient temperature and the comfort temperature is between 0 and 1.5, the room temperature is considered to correspond to the comfort temperature.

It will be appreciated that the comfort temperature and difference ranges may be freely adjusted according to the actual situation and are not limited to the numerical ranges provided above.

Example eight

In one embodiment of the present invention, the complete control logic of the air outlet assembly is shown in FIG. 10:

After the startup operation, step S1002 is executed first, and an operation mode is determined; if the cooling mode is the heating mode, the step S1026 is performed;

step S1004, entering a far air supply angle;

Step S1006, judging whether the refrigerating preset time is longer than the refrigerating preset time, if yes, entering step S1008, otherwise returning to step S1004;

Step S1008, detecting room temperature;

Step S1010, judging the difference between the room temperature and the comfort temperature; if the difference is the first preset range, go to step S1012, if the difference is the second preset range, go to step S1014, if the difference is the third preset range, go to step S1024;

Step S1012, entering a far air supply angle;

step S1014, entering a normal refrigeration angle;

Step S1016, judging the temperature difference between far and near; step S1018 is entered when the distance is high, and step S1020 is entered when the distance is low;

step S1018, entering a far air supply angle;

step S1020, entering a normal refrigeration angle;

step S1022, determining that the difference value is in a third preset range;

Step S1024, entering a windless angle;

Step S1026, entering a normal heating angle;

step 1028, judging whether the heating preset time is longer than the heating preset time, if yes, entering step 1030, otherwise returning to step 1026;

Step S1030, detecting a room temperature;

step S1032, judging whether the comfort temperature is reached; if yes, go to step S1034, otherwise return to step S1026;

step S1034, entering a warm foot heating angle.

Example nine

In one embodiment of the present invention, a computer readable storage medium is provided, on which a computer program is stored, which when executed by a processor, implements the control method of an air conditioner as provided in any one of the above embodiments, and therefore, the computer readable storage medium includes all the advantages of the control method of an air conditioner as provided in any one of the above embodiments, which are not described herein again.

In the description of the present invention, the term "plurality" means two or more, unless explicitly defined otherwise, the orientation or positional relationship indicated by the terms "upper", "lower", etc. are orientation or positional relationship based on the drawings, merely for convenience of description of the present invention and to simplify the description, and do not indicate or imply that the apparatus or elements referred to must have a specific orientation, be constructed and operated in a specific orientation, and thus should not be construed as limiting the present invention; the terms "coupled," "mounted," "secured," and the like are to be construed broadly, and may be fixedly coupled, detachably coupled, or integrally connected, for example; can be directly connected or indirectly connected through an intermediate medium. The specific meaning of the above terms in the present invention can be understood by those of ordinary skill in the art according to the specific circumstances.

In the description of the present invention, the terms "one embodiment," "some embodiments," "particular embodiments," and the like, mean that a particular feature, structure, material, or characteristic described in connection with the embodiment or example is included in at least one embodiment or example of the present invention. In the present invention, the schematic representations of the above terms do not necessarily refer to the same embodiment or example. Furthermore, the particular features, structures, materials, or characteristics described may be combined in any suitable manner in any one or more embodiments or examples.

The above description is only of the preferred embodiments of the present invention and is not intended to limit the present invention, but various modifications and variations can be made to the present invention by those skilled in the art. Any modification, equivalent replacement, improvement, etc. made within the spirit and principle of the present invention should be included in the protection scope of the present invention.

Claims (13)

1. An air conditioner, comprising:

The air conditioner comprises an air conditioner body, wherein an air outlet is formed in the air conditioner body;

the air outlet assembly is configured to adjust the air outlet of the air outlet and is provided with a plurality of forms;

a detection device configured to be adapted to obtain an ambient temperature;

The controller is electrically connected with the air outlet component and controls the switching mode of the air outlet component according to the ambient temperature;

The plurality of modes comprise a first mode and a second mode, the controller obtains the running mode of the air conditioner, determines the running mode to be a refrigerating mode, and controls the air outlet assembly to work in the first mode; determining the operation mode as a heating mode, and controlling the air outlet assembly to work in the second mode;

the plurality of modes further includes a third mode, the operation mode is determined to be a refrigeration mode, and the controller controls the air outlet assembly to switch modes according to the ambient temperature, specifically including:

acquiring a preset temperature, and calculating a difference value between the ambient temperature and the preset temperature;

Determining that the difference value is in a first difference value range, and controlling the air outlet assembly to be switched from the first mode to the third mode;

determining that the difference value is in a second difference value range, and controlling the air outlet assembly to maintain the first form;

The plurality of modes further includes a fourth mode, and the controller controls the air outlet assembly to switch modes according to the ambient temperature, and further includes:

determining that the difference value is in a third difference value range, and controlling the air outlet assembly to work in the fourth mode;

The plurality of modes further includes a fifth mode, the operation mode is determined to be a heating mode, the controller controls the air outlet assembly to switch modes according to the ambient temperature, and the method further includes:

Determining that the difference value is in the third difference value range, and controlling the air outlet assembly to work in the fifth mode;

The air-out subassembly includes:

The first air deflector is arranged in the air outlet and is suitable for rotating relative to the direction of the air outlet so as to change the air supply direction of the air outlet;

the second air deflector is connected with the air conditioner body and is suitable for moving relative to the air conditioner body along the first direction so as to shade or open the air outlet in the second direction;

The air dispersing component is connected with the air conditioner body and is suitable for moving relative to the air conditioner body along the second direction so as to shade or open the air outlet in the first direction, and an air dispersing structure is formed on the air dispersing component and is suitable for allowing air flow to pass through and for allowing the passing air flow to diffuse and flow;

The air conditioner body comprises a shell, wherein the shell is provided with a front side wall and a lower side wall, and the air outlet is formed at the transition position of the front side wall of the shell and the lower side wall of the shell;

Wherein the first direction faces the direction corresponding to the lower side wall, and the second direction faces the direction corresponding to the front side wall;

The air outlet assembly is in the first state, the second air deflector shields the air outlet in the second direction, the air dispersing assembly opens the air outlet in the first direction, and the first air deflector guides air blown out from the air outlet to the first direction;

The air outlet assembly is in the second state, the second air deflector opens the air outlet in the second direction, the air dispersing assembly opens the air outlet in the first direction, and the first air deflector guides the air blown out from the air outlet to the direction of an included angle between the plane where the second air deflector is located and the plane where the air dispersing assembly is located;

The air outlet assembly is in the third state, the second air deflector opens the air outlet in the second direction, the air dispersing assembly opens the air outlet in the first direction, and the first air deflector guides the air blown out by the air outlet to the first direction;

the air outlet assembly is in the fourth mode, the second air deflector shields the air outlet in the second direction, the air dispersing assembly shields the air outlet in the first direction, and the first air deflector guides air blown out by the air outlet to the first direction;

The air outlet assembly is in the fifth mode, the second air deflector opens the air outlet in the second direction, the air dispersing assembly shields the air outlet in the first direction, and the first air deflector guides air blown out by the air outlet to the second direction.

2. The air conditioner according to claim 1, wherein the detecting means is adapted to acquire a first ambient temperature in a first range and acquire a second ambient temperature in a second range;

the controller controls the switching mode of the air outlet assembly according to the ambient temperature, and the controller further comprises:

Determining that the first ambient temperature is less than the second ambient temperature, and controlling the air outlet assembly to work in the first mode;

and determining that the first ambient temperature is greater than the second ambient temperature, and controlling the air outlet assembly to work in the third mode.

3. The air conditioner according to claim 1 or 2, wherein the second air guide plate and the air dispersing component are spliced to define a cavity which is positioned outside the air outlet and communicated with the air outlet, and side openings are respectively formed at two ends of the cavity along the length direction of the splicing line of the second air guide plate and the air dispersing component, and the side openings are communicated with the cavity.

4. The air conditioner according to claim 1 or 2, wherein the first difference range is greater than 2.5;

the second difference range is greater than 1.5 and less than or equal to 2.5;

the third difference range is greater than or equal to 0 and less than or equal to 1.5.

5. A control method of an air conditioner for controlling the air conditioner according to any one of claims 1 to 4, characterized by comprising:

acquiring an ambient temperature;

And controlling the switching mode of the air outlet component of the air conditioner according to the ambient temperature.

6. The method of controlling an air conditioner according to claim 5, wherein the air outlet assembly has a first configuration and a second configuration, and the method further comprises, prior to the step of obtaining the ambient temperature:

acquiring an operation mode of the air conditioner;

determining the operation mode as a refrigeration mode, and controlling the air outlet assembly to work in the first mode;

and determining the operation mode as a heating mode, and controlling the air outlet assembly to work in the second mode.

7. The method according to claim 6, wherein the air outlet assembly further has a third configuration, the operation mode is determined to be a cooling mode, and the step of controlling the switching configuration of the air outlet assembly according to the ambient temperature specifically includes:

acquiring a preset temperature, and calculating a difference value between the ambient temperature and the preset temperature;

Determining that the difference value is in a first difference value range, and controlling the air outlet assembly to be switched from the first mode to the third mode;

And determining that the difference value is in a second difference value range, and controlling the air outlet assembly to maintain the first form.

8. The method according to claim 7, wherein the step of obtaining the ambient temperature comprises:

Acquiring a first ambient temperature in a first range and acquiring a second ambient temperature in a second range;

The step of controlling the switching mode of the air outlet assembly according to the ambient temperature further comprises the following steps:

Determining that the first ambient temperature is less than the second ambient temperature, and controlling the air outlet assembly to work in the first mode;

and determining that the first ambient temperature is greater than the second ambient temperature, and controlling the air outlet assembly to work in the third mode.

9. The method of controlling an air conditioner according to claim 8, wherein the air outlet assembly further has a fourth mode, and the controller controls the air outlet assembly to switch modes according to the ambient temperature, further comprising:

And determining that the difference value is in a third difference value range, and controlling the air outlet assembly to work in the fourth mode.

10. The method of claim 9, wherein the air outlet module further has a fifth configuration, the operation mode is determined to be a heating mode, and the step of controlling the switching configuration of the air outlet module according to the ambient temperature further comprises:

And determining that the difference value is in a third difference value range, and controlling the air outlet assembly to work in the fifth mode.

11. The control method of an air conditioner according to any one of claims 6 to 10, wherein the step of obtaining the ambient temperature is performed after the air outlet assembly is operated in the first or second state for a preset period of time.

12. The control method of an air conditioner according to claim 9 or 10, wherein the first difference range is greater than 2.5;

the second difference range is greater than 1.5 and less than or equal to 2.5;

the third difference range is greater than or equal to 0 and less than or equal to 1.5.

13. A computer-readable storage medium, on which a computer program is stored, characterized in that the computer program, when executed by a processor, implements the control method of an air conditioner according to any one of claims 5 to 12.