CN112432337B - Air port position regulating method and device, air conditioner and storage medium - Google Patents

Abstract

The application relates to a method and a device for regulating and controlling the position of an air port, an air conditioner and a storage medium, wherein the method comprises the following steps: acquiring a first characteristic parameter of air-conditioning air emitted from a first air outlet of an air conditioner to be controlled; acquiring a second characteristic parameter of the fresh air to be fused, which is emitted from a second air outlet of the air conditioner to be controlled; and acquiring a target relative position of the second air outlet and the first air outlet according to the first characteristic parameter, or acquiring a target relative position of the second air outlet and the first air outlet according to the second characteristic parameter, or acquiring a target relative position of the second air outlet and the first air outlet according to the first characteristic parameter and the second characteristic parameter. According to the method and the device, the position of the fresh air outlet relative to the air conditioner air outlet is dynamically regulated and controlled according to the characteristic parameters of the air conditioner air and the fresh air and the influence of the relative position of the air conditioner air outlet and the fresh air outlet on the fusion quantity of the air conditioner air and the fresh air, and the air conditioner air and the fresh air are fully fused in a room on the premise of not influencing the refrigeration and heating functions of the air conditioner.

Description

Air port position regulating method and device, air conditioner and storage medium

Technical Field

The application relates to the technical field of air conditioners, in particular to an air port position regulating method and device, an air conditioner and a storage medium.

Background

With the increasing living standard, people increasingly pay more attention to the influence of the environment on health and the influence of epidemic situations, and it becomes an important requirement for people to introduce fresh air into the room while using an air conditioner to eliminate indoor pollution. The fresh air cabinet air conditioner sends fresh air to an air-conditioning air jet area in a room for mixing and fusion by introducing the outdoor fresh air which is not processed by an air conditioner, and then sends the fresh air to the area of human activity in the room. At the moment, the position design of the air conditioner air inlet and the fresh air inlet has important influence on the performance of the air conditioner, the requirement of the air conditioner for supplying air to a fresh air demand area is met, and the fresh air and the air conditioner air are mixed, so that the air conditioner has a good cross jet air supply effect.

In actual use, the fusion amount is expected to be improved as much as possible, but the temperature of outdoor environment is brought by fresh air, the cold load is large, the refrigeration effect is poor due to excessive fresh air, and therefore the fusion amount of the fresh air is at the upper limit value, and the fusion effect is not ideal.

Disclosure of Invention

In order to solve the technical problem that the introduced fresh air and air conditioning air are not ideal in fusion effect, the embodiment of the application provides an air port position regulating method and device, an air conditioner and a storage medium.

In a first aspect, an embodiment of the present application provides a method for regulating and controlling a position of a tuyere, the method including:

acquiring a first characteristic parameter of air-conditioning air emitted from a first air outlet of an air conditioner to be controlled;

acquiring a second characteristic parameter of the fresh air to be fused, which is emitted from a second air outlet of the air conditioner to be controlled;

acquiring the target relative position of the second air outlet and the first air outlet according to the first characteristic parameter,

or the like, or, alternatively,

acquiring the target relative position of the second air outlet and the first air outlet according to the second characteristic parameter,

or the like, or, alternatively,

and acquiring the target relative position of the second air outlet and the first air outlet according to the first characteristic parameter and the second characteristic parameter.

Optionally, obtaining a target relative position of the second air outlet and the first air outlet according to the first characteristic parameter includes:

acquiring a first fusion quantity change curve corresponding to a first characteristic parameter of air-conditioning air;

the first fusion change curve is characterized: under the condition that the corresponding first characteristic parameter is not changed, along with the change of the relative position of the second air outlet and the first air outlet, the change curve of the fusion amount of the air conditioning air and the fresh air to be fused emitted from the second air outlet is obtained;

and determining a first target relative position of the second air outlet and the first air outlet from the first fusion volume change curve according to the first target fusion volume and the first characteristic parameter.

Optionally, obtaining a target relative position of the second air outlet and the first air outlet according to the second characteristic parameter includes:

acquiring a second fusion quantity change curve corresponding to a second characteristic parameter of the fresh air to be fused;

second fusion change curve characterization: under the condition that the corresponding second characteristic parameter is not changed, along with the change of the relative position of the second air outlet and the first air outlet, the change curve of the fusion amount of the air conditioning air and the fresh air to be fused emitted from the second air outlet is obtained;

and determining a second target relative position of the second air outlet and the first air outlet from the second fusion volume change curve according to the second target fusion volume and the second characteristic parameter.

Optionally, obtaining a target relative position of the second air outlet and the first air outlet according to the first characteristic parameter and the second characteristic parameter includes:

acquiring a first fusion quantity change curve corresponding to a first characteristic parameter of air-conditioning air;

the first fusion change curve is characterized: under the condition that the corresponding first characteristic parameter is not changed, along with the change of the relative position of the second air outlet and the first air outlet, the change curve of the fusion amount of the air conditioning air and the fresh air to be fused emitted from the second air outlet is obtained;

determining a first target relative position of the second air outlet and the first air outlet from the first fusion volume change curve according to the first target fusion volume and the first characteristic parameter;

acquiring a second fusion quantity change curve corresponding to a second characteristic parameter of the fresh air to be fused;

second fusion change curve characterization: under the condition that the corresponding second characteristic parameter is not changed, along with the change of the relative position of the second air outlet and the first air outlet, the change curve of the fusion amount of the air conditioning air and the fresh air to be fused emitted from the second air outlet is obtained;

determining a second target relative position of the second air outlet and the first air outlet from a second fusion volume change curve according to a second target fusion volume and a second characteristic parameter;

and acquiring a final target relative position according to the first target relative position and the second target relative position based on a first preset rule.

Optionally, the first characteristic parameter comprises at least one first sub-characteristic parameter;

the method for acquiring the first fusion volume change curve corresponding to the first characteristic parameter of the air conditioner air comprises the following steps:

acquiring a first sub-fusion quantity change curve corresponding to each first sub-characteristic parameter in the first characteristic parameters;

confirm the first target relative position of second air outlet and first air outlet from first fusion volume change curve according to first target fusion volume and first characteristic parameter, include:

respectively acquiring a first candidate relative position corresponding to a first target fusion amount under each first sub-characteristic parameter based on each first sub-characteristic parameter and a corresponding first sub-fusion amount change curve;

wherein, the first sub-fusion variation curve is characterized: under the condition that the corresponding first sub-characteristic parameter is not changed, along with the change of the relative position of the second air outlet relative to the first air outlet, the change curve of the fusion amount of the air-conditioning air and the fresh air to be fused emitted from the second air outlet is obtained;

the first candidate relative position is the relative position of the second air outlet relative to the first air outlet when the first target fusion amount is reached in the first sub-fusion amount change curve;

and determining a first target relative position of the second air outlet and the first air outlet according to all the first candidate relative positions based on a second preset rule.

Optionally, the at least one first sub-feature parameter comprises: temperature and/or first wind speed;

the second characteristic parameters include: a second wind speed.

Optionally, the method further comprises:

generating a regulation instruction according to the relative position of the target;

controlling the movement of a movable mechanism of the air conditioner to be controlled through a transmission module of the air conditioner to be controlled according to the regulation and control instruction, so that the relative position of the second air outlet and the first air outlet is a target relative position;

the movable mechanism is used for controlling the position of the second air outlet on the air conditioner to be controlled.

In a second aspect, an embodiment of the present application provides a tuyere position regulating device, which includes:

the first acquisition module is used for acquiring a first characteristic parameter of air-conditioning air emitted from a first air outlet of the air conditioner to be controlled;

the second acquisition module is used for acquiring a second characteristic parameter of the fresh air to be fused, which is emitted from a second air outlet of the air conditioner to be controlled;

and the positioning module is used for acquiring the target relative position of the second air outlet and the first air outlet according to the first characteristic parameter, or acquiring the target relative position of the second air outlet and the first air outlet according to the second characteristic parameter, or acquiring the target relative position of the second air outlet and the first air outlet according to the first characteristic parameter and the second characteristic parameter.

In a third aspect, an embodiment of the present application provides an air conditioner, where the air conditioner includes a first air outlet and a second air outlet, and a position of the second air outlet relative to the first air outlet is regulated and controlled by a moving mechanism in a method for regulating and controlling an air outlet position of any one of the air conditioners.

In a fourth aspect, embodiments of the present application provide a computer-readable storage medium having stored thereon a computer program, which, when executed by a processor, causes the processor to perform the steps of the method according to any one of the preceding claims.

In a fifth aspect, the present application provides a computer device comprising a memory, a processor and a computer program stored on the memory and executable on the processor, the processor performing the steps of the method according to any one of the preceding claims when executing the program.

Compared with the prior art, the technical scheme provided by the embodiment of the application has the following advantages:

the method includes the steps that a first characteristic parameter of air conditioner air emitted from a first air outlet of an air conditioner to be controlled is obtained; acquiring a second characteristic parameter of the fresh air to be fused, which is emitted from a second air outlet of the air conditioner to be controlled; and acquiring a target relative position of the second air outlet and the first air outlet according to the first characteristic parameter, or acquiring a target relative position of the second air outlet and the first air outlet according to the second characteristic parameter, or acquiring a target relative position of the second air outlet and the first air outlet according to the first characteristic parameter and the second characteristic parameter. Through the application, according to the characteristic parameters of the air conditioner air, the characteristic parameters of the fresh air and the influence of the relative position of the outlet of the air conditioner air and the outlet of the fresh air on the fusion quantity of the air conditioner air and the fresh air, the position of the fresh air outlet relative to the air conditioner air outlet is dynamically regulated and controlled, and the air conditioner air and the fresh air are fully fused in a room under the condition that the influence on the self refrigerating and heating functions of the air conditioner is not large.

Drawings

The accompanying drawings, which are incorporated in and constitute a part of this specification, illustrate embodiments consistent with the invention and together with the description, serve to explain the principles of the invention.

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below, and it is obvious for those skilled in the art that other drawings can be obtained according to the drawings without inventive exercise.

Fig. 1 is a schematic position diagram of a fresh air outlet and an air-conditioning outlet according to an embodiment of the present application;

fig. 2 is a schematic flow chart of a tuyere position control method according to an embodiment of the present disclosure;

FIG. 3 is a graph illustrating the variation of the fusion volume due to the effect of temperature and relative position on the fusion volume according to an embodiment of the present disclosure;

FIG. 4 is a graph illustrating a variation of a fusion volume due to the influence of wind speed and relative position on the fusion volume according to an embodiment of the present disclosure;

fig. 5 is a block diagram of a tuyere position regulating device according to an embodiment of the present disclosure.

Detailed Description

In order to make the objects, technical solutions and advantages of the embodiments of the present application clearer, the technical solutions in the embodiments of the present application will be clearly and completely described below with reference to the drawings in the embodiments of the present application, and it is obvious that the described embodiments are some embodiments of the present application, but not all embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present application.

Fig. 1 is a schematic position diagram of a fresh air outlet and an air-conditioning outlet provided in an embodiment of the present application. Referring to fig. 1, the air-conditioning air inlet is an air inlet or outlet for emitting air-conditioning air in the air conditioner to be controlled, and the fresh air inlet is an air inlet or outlet for emitting fresh air to be mixed in the air conditioner to be controlled. The air-conditioning air is mixed with the fresh air to be mixed after being emitted from the air-conditioning air outlet. The relative position of the air conditioner air inlet and the fresh air inlet determines the fusion effect of the air conditioner air and the fresh air.

The air-conditioned air is air subjected to temperature treatment by an air conditioner, for example, air subjected to cooling treatment or heating treatment by an evaporator of the air conditioner. The air-conditioned air is derived from air circulating indoors.

The fresh air is fresh air introduced from the outside.

Take the example that the relative height of the air-conditioning air inlet and the fresh air inlet represents the relative position of the air-conditioning air inlet and the fresh air inlet. In one embodiment, the air conditioning air inlet is square and the fresh air inlet is circular. Of course, not limited thereto. The shapes of the air conditioner air opening and the fresh air opening are specifically set according to actual conditions.

The lower end of the air-conditioning air inlet is taken as a zero boundary line, and the relative height delta h of the two air inlets is the vertical distance between the zero boundary line of the air-conditioning air inlet and the diameter of the fresh air inlet parallel to the zero boundary line.

When the diameter of the fresh air inlet parallel to the zero boundary line is above the zero boundary line, delta h is positive; when the diameter of the fresh air port parallel to the zero boundary line is below the zero boundary line, Δ h is negative.

The relative position of the air-conditioning air inlet and the fresh air inlet determines the fusion amount or fusion effect of the air-conditioning air and the fresh air. To achieve a predetermined target effect of the fusion amount or fusion effect, the relative positions of the two tuyeres may be adjusted.

Fig. 2 is a schematic flow chart of a tuyere position control method according to an embodiment of the present disclosure. Referring to fig. 2, the method includes the steps of:

s100: the method comprises the steps of obtaining a first characteristic parameter of air-conditioning air emitted from a first air outlet of an air conditioner to be controlled.

S200: and acquiring a second characteristic parameter of the fresh air to be fused, which is emitted from a second air outlet of the air conditioner to be controlled.

S300: and acquiring a target relative position of the second air outlet and the first air outlet according to the first characteristic parameter, or acquiring a target relative position of the second air outlet and the first air outlet according to the second characteristic parameter, or acquiring a target relative position of the second air outlet and the first air outlet according to the first characteristic parameter and the second characteristic parameter.

Specifically, the first air outlet is the air conditioner air outlet described above, and the second air outlet is the fresh air outlet described above. The relative position of the second air outlet and the first air outlet can be the relative vertical height of the second air outlet and the first air outlet; or the distance between the second air outlet and the central point of the first air outlet.

For example: the first air outlet is rectangular, the second air outlet is circular, and the relative position can be the vertical height between the boundary line of the lower end of the first air outlet and the diameter of the second air outlet parallel to the boundary line of the lower end of the first air outlet. The relative position may also be, but is not limited to, the distance between the center of the rectangle and the center of the circle.

The relative position of the second air outlet and the first air outlet can be achieved by adjusting the position of the second air outlet on the air conditioner by keeping the position of the first air outlet on the air conditioner unchanged; the position of the first air outlet on the air conditioner can be adjusted by keeping the position of the second air outlet on the air conditioner unchanged; the air conditioner can be achieved by adjusting the positions of the first air outlet and the second air outlet on the air conditioner at the same time.

In a specific embodiment, only the air-conditioning air parameters and the influence of the relative positions of the second air outlet and the first air outlet on the fusion amount are considered. The method comprises the steps of obtaining a first characteristic parameter of air-conditioning air emitted from a first air outlet of an air conditioner to be controlled and a first fusion volume change curve corresponding to the first characteristic parameter, and determining the relative position of a second air outlet relative to the first air outlet when the first characteristic parameter is determined to reach a first target fusion volume according to the first characteristic parameter and the first fusion volume change curve corresponding to the first characteristic parameter.

The first fusion change curve is characterized: under the condition that the corresponding first characteristic parameter is not changed, along with the change of the relative position of the second air outlet and the first air outlet, the change curve of the fusion amount of the air conditioning air and the fresh air to be fused emitted from the second air outlet is obtained.

That is, the first fusion change curve characterizes: and the comparison relation between the fusion amount of the fresh air to be fused and the air-conditioning air emitted from the first air outlet, the first characteristic parameter and the relative positions of the second air outlet and the first air outlet.

For example, if the first characteristic parameter is the temperature of the air-conditioned air, the first fusion volume change curve is a change curve of the fusion volume of the air-conditioned air and the fresh air along with the change of the relative position of the second air outlet and the first air outlet when the temperature of the air-conditioned air is determined.

For another example, if the first characteristic parameter is the air speed of the air-conditioned air, the first fusion volume change curve is a change curve of the fusion volume of the air-conditioned air and the fresh air with a change in the relative position of the second outlet and the first outlet when the air speed of the air-conditioned air is determined.

The wind speed of the air conditioner is different, and the corresponding first fusion volume change curves are different. The temperature of the air conditioning air is different, and the corresponding first fusion volume change curves are different. The wind speed and temperature of the air conditioning wind have an influence on the fusion amount or the fusion effect.

In a specific embodiment, only the fresh air parameters and the influence of the relative positions of the second air outlet and the first air outlet on the fusion amount are considered. And acquiring a second characteristic parameter of the fresh air to be fused and a second fusion volume change curve corresponding to the second characteristic parameter, which is emitted from a second air outlet of the air conditioner to be controlled, and determining a target relative position of the second air outlet relative to the first air outlet when the second characteristic parameter is determined to reach a second target fusion volume according to the second characteristic parameter and the second fusion volume change curve corresponding to the second characteristic parameter.

Second fusion change curve characterization: and under the condition that the corresponding second characteristic parameter is not changed, along with the change of the relative position of the second air outlet and the first air outlet, the change curve of the fusion amount of the air conditioning air and the fresh air to be fused emitted from the second air outlet is obtained.

That is, the second fusion change curve characterizes: and the comparison relation between the fusion amount of the fresh air to be fused and the air-conditioning air emitted from the first air outlet, the second characteristic parameter and the relative position of the second air outlet and the first air outlet.

For example, if the second characteristic parameter is the wind speed of the fresh air, the second fusion volume change curve is a change curve of the fusion volume of the air-conditioning wind and the fresh air along with the change of the relative position of the second air outlet and the first air outlet under the condition that the wind speed of the fresh air is determined.

In a specific embodiment, the air conditioning air parameter, the fresh air parameter and the influence of the relative position of the second air outlet and the first air outlet on the fusion amount are considered simultaneously.

The method comprises the steps of obtaining a first characteristic parameter of air-conditioning air emitted from a first air outlet of an air conditioner to be controlled and a first fusion volume change curve corresponding to the first characteristic parameter, and determining a first target relative position of a second air outlet relative to the first air outlet when the first characteristic parameter is determined according to the first characteristic parameter and the first fusion volume change curve corresponding to the first characteristic parameter. And acquiring a second characteristic parameter of the fresh air to be fused and a second fusion volume change curve corresponding to the second characteristic parameter, which is emitted from a second air outlet of the air conditioner to be controlled, and determining a second target relative position of the second air outlet relative to the first air outlet when the second characteristic parameter is determined according to the second characteristic parameter and the second fusion volume change curve corresponding to the second characteristic parameter. And determining the final target relative position of the second air outlet and the first air outlet according to the first target relative position and the second target relative position based on a first preset rule.

The first fusion change curve is characterized: under the condition that the corresponding first characteristic parameter is not changed, along with the change of the relative position of the second air outlet and the first air outlet, the change curve of the fusion amount of the air conditioning air and the fresh air to be fused emitted from the second air outlet is obtained.

Second fusion change curve characterization: and under the condition that the corresponding second characteristic parameter is not changed, along with the change of the relative position of the second air outlet and the first air outlet, the change curve of the fusion amount of the air conditioning air and the fresh air to be fused emitted from the second air outlet is obtained.

Since the temperature and the wind speed have different degrees of influence on the fusion volume, the first target fusion volume and the second target fusion volume may be the same or different.

In one embodiment, the first preset rule is: and carrying out weighted summation on the first target relative position and the second target relative position to obtain the target relative position of the second air outlet and the first air outlet.

In one embodiment, the first preset rule is: and taking the maximum value of the first target relative position and the second target relative position as the final target relative position of the second air outlet and the first air outlet.

In a specific embodiment, the first and second fusion volume change curves may be further replaced with a first fusion volume mapping table and a second fusion volume mapping table.

For example: the first fusion quantity mapping table with the first characteristic parameter corresponding to the temperature is as follows: and fusing amounts of a plurality of groups of different relative positions corresponding to the temperatures of the plurality of groups respectively.

The temperature interval or step length between the temperatures can be set according to actual conditions, and the position interval or step length between the relative positions can also be set according to actual conditions.

For example: the temperature is as follows: 5 ℃, 15 ℃, 25 ℃, 35 ℃, 45 ℃ and 55 ℃.

The relative positions are relative heights: -500mm, -400mm, -300mm, -200mm, -100mm, 0mm, 100mm, 200mm, 300mm, 400mm, 500 mm.

The first fusion quantity mapping table includes: a fusion quantity mapping table corresponding to each relative height above 5 ℃, a fusion quantity mapping table corresponding to each relative height above 15 ℃, a fusion quantity mapping table corresponding to each relative height above 25 ℃, a fusion quantity mapping table corresponding to each relative height above 35 ℃, a fusion quantity mapping table corresponding to each relative height above 45 ℃, and a fusion quantity mapping table corresponding to each relative height above 55 ℃.

In a particular embodiment, the first characteristic parameter comprises at least one first sub-characteristic parameter. The at least one first sub-feature parameter comprises: temperature and/or first wind speed. The temperature is the temperature of the air conditioning air, and the first air speed is the air speed of the air conditioning air.

The method for obtaining the first fusion volume change curve corresponding to the first characteristic parameter of the air conditioner air specifically comprises the following steps: and acquiring a first sub-fusion change curve corresponding to each first sub-characteristic parameter in the first characteristic parameters.

Specifically, a first sub-fusion variation curve corresponding to the temperature is obtained, and/or a first sub-fusion variation curve corresponding to the first wind speed is obtained.

Confirm the first target relative position of second air outlet and first air outlet from first fusion volume change curve according to first target fusion volume and first characteristic parameter, include:

and acquiring a corresponding first candidate relative position when the first target fusion volume is reached under each first sub-feature parameter respectively based on each first sub-feature parameter and the corresponding first sub-fusion volume change curve.

Specifically, a first candidate relative position of the second air outlet and the first air outlet corresponding to the temperature is obtained based on a first sub-fusion volume change curve corresponding to the air-conditioning air temperature when the first target fusion volume is reached at the temperature.

And/or the presence of a gas in the gas,

and acquiring a first candidate relative position of a second air outlet and a first air outlet corresponding to the air-conditioning air speed when the first target fusion volume is reached under the air-conditioning air speed based on a first sub-fusion volume change curve corresponding to the air-conditioning air speed.

Wherein, the first sub-fusion variation curve is characterized: under the condition that the corresponding first sub-characteristic parameter is not changed, along with the change of the relative position of the second air outlet relative to the first air outlet, the change curve of the fusion amount of the air-conditioning air and the fresh air to be fused emitted from the second air outlet is obtained; the first candidate relative position is the relative position of the second air outlet relative to the first air outlet when the first target fusion amount is reached in the first sub-fusion amount change curve.

Specifically, a first sub-fusion volume change curve corresponding to the air-conditioning air temperature is characterized: under the condition that the temperature of the air conditioner air is not changed, along with the change of the relative position of the second air outlet relative to the first air outlet, the change curve of the fusion amount of the air conditioner air and the new air to be fused emitted from the second air outlet is obtained.

The first candidate relative position corresponding to the wind adjusting temperature is as follows: and the relative position of the second air outlet relative to the first air outlet when the first target fusion volume is reached in the first sub-fusion volume change curve corresponding to the air conditioning air temperature.

The first sub-fusion volume change curve representation corresponding to the air speed of the air conditioner is as follows: under the condition that the air speed of the air conditioner is not changed, along with the change of the relative position of the second air outlet relative to the first air outlet, the change curve of the fusion amount of the air conditioner and the new air to be fused emitted from the second air outlet is obtained.

The first candidate relative position corresponding to the air speed of the air conditioner is as follows: and the relative position of the second air outlet relative to the first air outlet when the first target fusion volume is reached in a first sub-fusion volume change curve corresponding to the air speed of the air conditioner.

Of course, the first target fusion volume corresponding to the air-conditioning air temperature and the air-conditioning air speed may be set to be the same, or may be set to be different first sub-target fusion volume and second sub-target fusion volume.

And determining a first target relative position of the second air outlet and the first air outlet according to all the first candidate relative positions based on a second preset rule.

Specifically, the second preset rule is: and performing weighted summation on all the first candidate relative positions to obtain a first target relative position of the second air outlet and the first air outlet.

The second preset rule may also be: and taking the maximum value of all the first candidate relative positions as the final first target relative position of the second air outlet and the first air outlet.

If the first characteristic parameter comprises the air-conditioning air temperature and the air-conditioning air speed. And obtaining a final first target relative position of the second air outlet and the first air outlet according to a second preset rule according to the first candidate relative position corresponding to the air-conditioning air temperature and the first candidate relative position corresponding to the air-conditioning air speed.

In a particular embodiment, the method further comprises:

s400: and generating a regulation and control instruction according to the relative position of the target.

S500: and controlling the movement of the movable mechanism of the air conditioner to be controlled through a transmission module of the air conditioner to be controlled according to the regulation and control instruction, so that the relative position of the second air outlet and the first air outlet is a target relative position.

Specifically, for example, the position of the first outlet on the air conditioner to be controlled is fixed, and the relative position of the second outlet with respect to the first outlet is adjusted by changing the position of the second outlet.

The movable mechanism is used for controlling the position of the second air outlet on the air conditioner to be controlled, the transmission module is driven by the main control module of the air conditioner to be controlled, and after the main control module obtains the relative position, the main control module sends an instruction to the transmission module to enable the transmission module to control the movable mechanism to move up and down and left and right, so that the position of the second air outlet relative to the first air outlet is the relative position obtained by the method.

Different factors influence the fusion amount, and the more factors are considered, the closer the obtained final target relative position is to the actual air conditioner parameters, and the more the fusion of the actual air conditioner air and the fresh air is facilitated.

However, the actual air conditioner operation condition is very complex, and it may not be possible to consider a plurality of influencing factors at the same time, so that, according to the actual situation, only the influence of one of the factors (for example, only the temperature or only the wind speed) may be considered in terms of the fusion amount, or a plurality of factors (for example, the temperature and the wind speed) may be considered at the same time.

FIG. 3 is a graph illustrating the variation of the fusion volume due to the effect of temperature and relative position on the fusion volume according to an embodiment of the present disclosure; fig. 4 is a graph illustrating a variation of the fusion volume due to the influence of the wind speed and the relative position on the fusion volume according to an embodiment of the present disclosure.

Referring to fig. 3, the air-conditioning air temperature is: 5 ℃, 15 ℃, 25 ℃, 35 ℃, 45 ℃ and 55 ℃. Of course, fig. 3 is only an example, and the first fusion variation graph for specifically setting which temperatures correspond to may be set according to actual conditions.

The air conditioning temperature is 5 ℃, 15 ℃, 25 ℃, 35 ℃, 45 ℃ and 55 ℃, and the air conditioning temperature respectively has a corresponding first sub-fusion quantity change curve chart.

Each first sub-fusion volume change curve chart is a continuous curve chart, so that the fusion volume corresponding to the relative position of each second air outlet and the first air outlet can be obtained under the condition that the temperature of the air conditioning air is determined.

The relative position in fig. 3 is relative height, and the interval is: -500mm to +500 mm. Of course, this is merely an example, and the specific setting of the fusion amount corresponding to which relative height is set may be set according to actual situations.

Referring to fig. 4, fig. 4 is a graph showing the variation of the fusion volume due to the influence of the air-conditioning air speed or the fresh air speed and the relative position on the fusion volume. Namely, the first sub-fusion volume change curve corresponding to the air conditioning air speed is the same as the second fusion volume change curve corresponding to the fresh air speed.

Of course, the first sub-fusion variation curve corresponding to the air-conditioning wind speed and the second fusion variation curve corresponding to the fresh air wind speed can be set to be different.

The air speed of the air conditioner or the air speed of the fresh air is as follows: 2m/s, 4m/s, 6m/s, 8m/s, 10 m/s. The first sub-fusion variation graph or the second sub-fusion variation graph corresponding to which wind speeds are specifically set can be set according to actual conditions.

The air speed of the air conditioner or the air speed of the fresh air is as follows: the two sub-fusion quantity change graphs are respectively corresponding to 2m/s, 4m/s, 6m/s, 8m/s and 10 m/s.

Each first sub-fusion volume change curve graph or each second fusion volume change curve graph is a continuous curve graph, so that the fusion volume corresponding to the relative position of each second air outlet and the first air outlet can be obtained under the condition that the air conditioning air speed or the fresh air speed is determined.

The relative position in fig. 4 is relative height, and the interval is: -500mm to +500 mm. Of course, this is merely an example, and the specific setting of the fusion amount corresponding to which relative height is set may be set according to actual situations.

Under different air conditioner air-out temperatures, the relative height of the air conditioner air inlet and the fresh air inlet has certain influence on the fusion amount of the fresh air and the air conditioner air: the smaller the Delta h is, the larger the air quantity naturally escaping to the room environment around the cabinet body in the rising process of the fresh air is along with the downward movement of the fresh air inlet, the poorer the mixing effect with the air conditioning air is, the fusion amount of the Delta h below-200 mm is reduced to below 80 percent, and the fusion amount of the Delta h below-300 mm is reduced to below 40 percent. When delta h is increased, namely the fresh air inlet continuously moves upwards, the air supplied by the fresh air inlet rises along with the fresh air inlet, the fresh air inlet easily penetrates through the air supply area of the air-conditioning air, and the air is difficult to smoothly merge in the air supply area. During refrigeration, cold air with high density flows downwards and is easier to penetrate, and the degree of reduction of the fusion amount along with the reduction of delta h is higher. When the delta h is between-100 mm and 100, the fusion amount can stably reach more than 80 percent.

The air-out temperature is an important determinant, and compared with refrigeration, the air-out temperature of the air conditioner is high when the air conditioner is used for heating, and the fusion effect of the air-conditioning air and the fresh air is also poor at the moment, because the air-conditioning air is influenced by thermal buoyancy and continuously flows upwards along with the rise of the air-out temperature, the distance between the air-conditioning air and the fresh air is increased, and a good fusion effect is difficult to obtain.

Considering the influence of the relative height of the air conditioner air inlet and the fresh air inlet on the fusion amount under different fresh air speeds, the relative height of the air conditioner air inlet and the fresh air inlet has certain influence on the fusion amount of the fresh air and the air conditioner air under different fresh air speeds: when the delta h is lower than minus 180mm, the fusion amount is reduced to be below 80% under the condition of small wind speed; when the delta h is lower than-300 mm, the fusion amount is also reduced to be lower than 80% under the condition of high wind speed. When delta h is higher than 200mm, the fusion amount of the small wind speed is reduced to be below 80%, the fresh air easily penetrates through the air conditioning wind along with the increase of the wind speed, and the fusion amount is smaller and even reduced to be below 50%. Under the condition of wind speed of fresh air of both sizes, the fusion amount can reach more than 95% when delta h is between minus 100mm and 100, and the air conditioner is in a high-efficiency and energy-saving state.

At this time, it can be known from fig. 3 and 4 that theoretically Δ h is between-100 mm and 100mm, the fusion amount can achieve the most excellent effect, but actually, due to the structure of the air duct inside the air conditioner of different models and the positions of the motor and the electric control component, it is difficult to arrange the Δ h value between-100 mm and 100mm at the air inlet position. Therefore, in practical control, the ideal fusion effect that can be achieved can only be achieved as far as possible within the range that can be achieved by the relative position.

Specifically, the present application further includes: and if the movement of the movable mechanism of the air conditioner to be controlled is controlled through the transmission module of the air conditioner to be controlled according to the regulation and control instruction, and the relative position of the second air outlet and the first air outlet cannot be made to be the target relative position, selecting the relative position closest to the target relative position from the relative positions which can be reached by the air conditioner to be controlled as the undetermined relative position.

And acquiring the fusion quantity corresponding to the first fusion quantity change curve under the condition of the relative position to be determined according to the first fusion quantity change curve. If the fusion amount is not lower than the lowest fusion threshold value, the movable mechanism of the air conditioner to be controlled is controlled to move through the transmission module of the air conditioner to be controlled, so that the relative position of the second air outlet and the first air outlet is the undetermined relative position.

Or the like, or, alternatively,

and acquiring the fusion quantity corresponding to the second fusion quantity change curve under the condition of the relative position to be determined according to the second fusion quantity change curve. If the fusion amount is not lower than the lowest fusion threshold value, the movable mechanism of the air conditioner to be controlled is controlled to move through the transmission module of the air conditioner to be controlled, so that the relative position of the second air outlet and the first air outlet is the undetermined relative position.

Or the like, or, alternatively,

and acquiring the fusion quantity corresponding to the first fusion quantity change curve and the fusion quantity corresponding to the second fusion quantity change curve under the condition of the relative position to be fixed according to the first fusion quantity change curve and the second fusion quantity change curve. If any one of the two previous fusion amounts is not lower than the lowest fusion threshold, the movable mechanism of the air conditioner to be controlled is controlled to move through the transmission module of the air conditioner to be controlled, so that the relative position of the second air outlet and the first air outlet is the relative position to be determined.

The application designs a movable mechanism, and the transmission structure controls the movable mechanism according to the logic, so that the position of an air port is controlled, and air conditioning air and fresh air are fully fused in a room.

Based on the above analysis and a large amount of experience and data, the fusion change profiles of fig. 3 and 4 were obtained by fitting.

According to the influence of different air outlet temperatures and fresh air speeds on the air conditioning air and fresh air fusion quantity, the position of the fresh air port is controlled, and the air conditioning air and the fresh air are fully fused in a room under the condition that the influence on the refrigeration and heating functions of the air conditioner is small.

The fresh air inlet position control method reduces the influence of adverse factors such as thermal buoyancy and penetration phenomenon, and greatly improves the fusion amount. The working conditions of different air conditioner air outlet temperatures are comprehensively considered, the refrigerating and heating are suitable for the air conditioner, the air supply accessibility of a fresh air demand area is improved by 61.1%, the CO2 concentration reduction rate is increased by 29.2%, the air age of the far end of the fresh air demand area is smaller by 53.7%, and the air is fresh. Meanwhile, in the aspect of energy conservation, the cold load of a room is not increased under the condition of increasing the fresh air fusion amount as much as possible; this application makes the abundant integration that realizes air conditioner wind and new trend in the room through adjusting the new trend position, fuses volume greatly increased, has played fine blowdown and air purification effect.

Fig. 5 is a block diagram of a tuyere position regulating device according to an embodiment of the present disclosure. Referring to fig. 5, the apparatus includes:

the first obtaining module 100 is configured to obtain a first characteristic parameter of air-conditioning air emitted from a first air outlet of an air conditioner to be controlled;

a second obtaining module 200, configured to obtain a second characteristic parameter of the fresh air to be merged emitted from a second air outlet of the air conditioner to be controlled;

the positioning module 300 is configured to obtain a target relative position between the second air outlet and the first air outlet according to the first characteristic parameter, or obtain a target relative position between the second air outlet and the first air outlet according to the second characteristic parameter, or obtain a target relative position between the second air outlet and the first air outlet according to the first characteristic parameter and the second characteristic parameter.

In an embodiment, the positioning module 300 specifically includes:

the first curve acquisition module is used for acquiring a first fusion volume change curve corresponding to a first characteristic parameter of the air-conditioning air;

the first fusion change curve is characterized: under the condition that the corresponding first characteristic parameter is not changed, along with the change of the relative position of the second air outlet and the first air outlet, the change curve of the fusion amount of the air conditioning air and the fresh air to be fused emitted from the second air outlet is obtained;

and the first matching module is used for determining a first target relative position of the second air outlet and the first air outlet from the first fusion volume change curve according to the first target fusion volume and the first characteristic parameter.

In an embodiment, the positioning module 300 specifically includes:

the second curve acquisition module is used for acquiring a second fusion quantity change curve corresponding to a second characteristic parameter of the fresh air to be fused;

second fusion change curve characterization: under the condition that the corresponding second characteristic parameter is not changed, along with the change of the relative position of the second air outlet and the first air outlet, the change curve of the fusion amount of the air conditioning air and the fresh air to be fused emitted from the second air outlet is obtained;

and the second matching module is used for determining a second target relative position of the second air outlet and the first air outlet from the second fusion volume change curve according to the second target fusion volume and the second characteristic parameter.

In an embodiment, the positioning module 300 specifically includes:

the first curve acquisition module is used for acquiring a first fusion volume change curve corresponding to a first characteristic parameter of the air-conditioning air;

the first fusion change curve is characterized: under the condition that the corresponding first characteristic parameter is not changed, along with the change of the relative position of the second air outlet and the first air outlet, the change curve of the fusion amount of the air conditioning air and the fresh air to be fused emitted from the second air outlet is obtained;

the first matching module is used for determining a first target relative position of the second air outlet and the first air outlet from the first fusion volume change curve according to the first target fusion volume and the first characteristic parameter;

the second curve acquisition module is used for acquiring a second fusion quantity change curve corresponding to a second characteristic parameter of the fresh air to be fused;

second fusion change curve characterization: under the condition that the corresponding second characteristic parameter is not changed, along with the change of the relative position of the second air outlet and the first air outlet, the change curve of the fusion amount of the air conditioning air and the fresh air to be fused emitted from the second air outlet is obtained;

the second matching module is used for determining a second target relative position of the second air outlet and the first air outlet from a second fusion volume change curve according to a second target fusion volume and a second characteristic parameter;

and the calculating module is used for acquiring a final target relative position according to the first target relative position and the second target relative position based on a first preset rule.

In a specific embodiment, the first characteristic parameter comprises at least one first sub-characteristic parameter;

the first curve acquisition module is specifically configured to: acquiring a first sub-fusion quantity change curve corresponding to each first sub-characteristic parameter in the first characteristic parameters;

the first matching module specifically comprises:

the sub-matching module is used for acquiring a corresponding first candidate relative position when the first target fusion volume is reached under each first sub-characteristic parameter respectively based on each first sub-characteristic parameter and the corresponding first sub-fusion volume change curve;

wherein, the first sub-fusion variation curve is characterized: under the condition that the corresponding first sub-characteristic parameter is not changed, along with the change of the relative position of the second air outlet relative to the first air outlet, the change curve of the fusion amount of the air-conditioning air and the fresh air to be fused emitted from the second air outlet is obtained;

the first candidate relative position is the relative position of the second air outlet relative to the first air outlet when the first target fusion amount is reached in the first sub-fusion amount change curve;

and the sub-calculation module is used for determining the first target relative position of the second air outlet and the first air outlet according to all the first candidate relative positions based on a second preset rule.

In a specific embodiment, the at least one first sub-feature parameter comprises: temperature and/or first wind speed; the second characteristic parameters include: a second wind speed.

In a specific embodiment, the apparatus further comprises:

the instruction generating module is used for generating a regulation and control instruction according to the relative position of the target;

and controlling the movement of the movable mechanism of the air conditioner to be controlled through a transmission module of the air conditioner to be controlled according to the regulation and control instruction, so that the relative position of the second air outlet and the first air outlet is a target relative position.

The movable mechanism is used for controlling the position of the second air outlet on the air conditioner to be controlled.

In one embodiment, the present application provides an air conditioner, which includes a first air outlet and a second air outlet, and the air conditioner obtains a relative position between the second air outlet and the first air outlet according to the air outlet position regulating method described in any one of the preceding claims, and regulates a position of the second air outlet relative to the first air outlet on the air conditioner to be controlled through a moving mechanism according to the relative position between the second air outlet and the first air outlet.

In one embodiment, a computer device is provided, comprising a memory, a processor, and a computer program stored on the memory and executable on the processor, the processor implementing the following steps when executing the computer program: acquiring a second characteristic parameter of the fresh air to be fused, which is emitted from a second air outlet of the air conditioner to be controlled; and acquiring a target relative position of the second air outlet and the first air outlet according to the first characteristic parameter, or acquiring a target relative position of the second air outlet and the first air outlet according to the second characteristic parameter, or acquiring a target relative position of the second air outlet and the first air outlet according to the first characteristic parameter and the second characteristic parameter.

In one embodiment, the processor executes the computer program to further implement the steps of any one of the methods for regulating and controlling the position of the tuyere.

In one embodiment, a computer-readable storage medium is provided, having a computer program stored thereon, which when executed by a processor, performs the steps of: acquiring a first characteristic parameter of air-conditioning air emitted from a first air outlet of an air conditioner to be controlled; acquiring a second characteristic parameter of the fresh air to be fused, which is emitted from a second air outlet of the air conditioner to be controlled; and acquiring a target relative position of the second air outlet and the first air outlet according to the first characteristic parameter, or acquiring a target relative position of the second air outlet and the first air outlet according to the second characteristic parameter, or acquiring a target relative position of the second air outlet and the first air outlet according to the first characteristic parameter and the second characteristic parameter.

In one embodiment, the computer program when executed by the processor further implements the steps of any one of the methods for tuyere position regulation and control described above.

It is noted that, in this document, relational terms such as "first" and "second," and the like, may be used solely to distinguish one entity or action from another entity or action without necessarily requiring or implying any actual such relationship or order between such entities or actions. Also, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus. Without further limitation, an element defined by the phrase "comprising an … …" does not exclude the presence of other identical elements in a process, method, article, or apparatus that comprises the element.

The foregoing are merely exemplary embodiments of the present invention, which enable those skilled in the art to understand or practice the present invention. Various modifications to these embodiments will be readily apparent to those skilled in the art, and the generic principles defined herein may be applied to other embodiments without departing from the spirit or scope of the invention. Thus, the present invention is not intended to be limited to the embodiments shown herein but is to be accorded the widest scope consistent with the principles and novel features disclosed herein.

Claims (9)

1. A tuyere position regulation and control method is characterized by comprising the following steps:

acquiring a first characteristic parameter of air-conditioning air emitted from a first air outlet of an air conditioner to be controlled;

acquiring a second characteristic parameter of the fresh air to be fused, which is emitted from a second air outlet of the air conditioner to be controlled;

acquiring the target relative position of the second air outlet and the first air outlet according to the first characteristic parameter,

or the like, or, alternatively,

acquiring the target relative position of the second air outlet and the first air outlet according to the second characteristic parameter,

or the like, or, alternatively,

acquiring a target relative position of the second air outlet and the first air outlet according to the first characteristic parameter and the second characteristic parameter;

wherein the method further comprises:

generating a regulation and control instruction according to the obtained relative position of the target;

controlling a movable mechanism of the air conditioner to be controlled to move through a transmission module of the air conditioner to be controlled according to the regulation and control instruction, so that the relative position of the second air outlet and the first air outlet is the target relative position;

the movable mechanism is used for controlling the position of the second air outlet on the air conditioner to be controlled.

2. The method of claim 1, wherein the obtaining the target relative position of the second outlet and the first outlet according to the first characteristic parameter comprises:

acquiring a first fusion quantity change curve corresponding to a first characteristic parameter of the air-conditioning air;

the first fusion change curve is characterized by: under the condition that the corresponding first characteristic parameter is not changed, along with the change of the relative position of the second air outlet and the first air outlet, the change curve of the fusion amount of the air-conditioning air and the fresh air to be fused emitted from the second air outlet is obtained;

and determining a first target relative position of the second air outlet and the first air outlet from the first fusion volume change curve according to a first target fusion volume and the first characteristic parameter.

3. The method of claim 1, wherein the obtaining the target relative position of the second air outlet and the first air outlet according to the second characteristic parameter comprises:

acquiring a second fusion quantity change curve corresponding to a second characteristic parameter of the fresh air to be fused;

the second fusion change curve is characterized by: under the condition that the corresponding second characteristic parameter is not changed, along with the change of the relative position of the second air outlet and the first air outlet, the change curve of the fusion amount of the air-conditioning air and the fresh air to be fused emitted from the second air outlet is obtained;

and determining a second target relative position of the second air outlet and the first air outlet from the second fusion volume change curve according to a second target fusion volume and the second characteristic parameter.

4. The method of claim 1, wherein obtaining the target relative position of the second outlet with respect to the first outlet according to the first characteristic parameter and the second characteristic parameter comprises:

acquiring a first fusion quantity change curve corresponding to a first characteristic parameter of the air-conditioning air;

the first fusion change curve is characterized by: under the condition that the corresponding first characteristic parameter is not changed, along with the change of the relative position of the second air outlet and the first air outlet, the change curve of the fusion amount of the air-conditioning air and the fresh air to be fused emitted from the second air outlet is obtained;

determining a first target relative position of the second air outlet and the first air outlet from the first fusion volume change curve according to a first target fusion volume and the first characteristic parameter;

acquiring a second fusion quantity change curve corresponding to a second characteristic parameter of the fresh air to be fused;

the second fusion change curve is characterized by: under the condition that the corresponding second characteristic parameter is not changed, along with the change of the relative position of the second air outlet and the first air outlet, the change curve of the fusion amount of the air-conditioning air and the fresh air to be fused emitted from the second air outlet is obtained;

determining a second target relative position of the second air outlet and the first air outlet from the second fusion volume change curve according to a second target fusion volume and the second characteristic parameter;

and acquiring a final target relative position according to the first target relative position and the second target relative position based on a first preset rule.

5. The method according to claim 2 or 4, wherein the first feature parameter comprises at least one first sub-feature parameter;

the acquiring of the first fusion volume change curve corresponding to the first characteristic parameter of the air-conditioning air comprises the following steps:

acquiring a first sub-fusion volume change curve corresponding to each first sub-characteristic parameter in the first characteristic parameters;

the determining a first target relative position of the second air outlet and the first air outlet from the first fusion volume change curve according to the first target fusion volume and the first characteristic parameter includes:

respectively acquiring a first candidate relative position corresponding to a first target fusion amount under each first sub-characteristic parameter based on each first sub-characteristic parameter and a corresponding first sub-fusion amount change curve;

wherein the first sub-fusion variation curve is characterized by: under the condition that the corresponding first sub-characteristic parameter is not changed, along with the change of the relative position of the second air outlet relative to the first air outlet, the change curve of the fusion amount of the air-conditioning air and the fresh air to be fused emitted from the second air outlet is obtained;

the first candidate relative position is the relative position of the second air outlet relative to the first air outlet when the first target fusion amount is reached in the first sub-fusion amount change curve;

and determining a first target relative position of the second air outlet and the first air outlet according to all the first candidate relative positions based on a second preset rule.

6. The method according to claim 5, wherein the at least one first sub-feature parameter comprises: temperature and/or first wind speed;

the second characteristic parameter includes: a second wind speed.

7. A tuyere position regulating device characterized in that the device comprises:

the first acquisition module is used for acquiring a first characteristic parameter of air-conditioning air emitted from a first air outlet of the air conditioner to be controlled;

the second acquisition module is used for acquiring a second characteristic parameter of the fresh air to be fused, which is emitted from a second air outlet of the air conditioner to be controlled;

a positioning module for obtaining a target relative position of the second air outlet and the first air outlet according to the first characteristic parameter,

or the like, or, alternatively,

acquiring the target relative position of the second air outlet and the first air outlet according to the second characteristic parameter,

or the like, or, alternatively,

acquiring a target relative position of the second air outlet and the first air outlet according to the first characteristic parameter and the second characteristic parameter;

wherein, the device still includes:

the instruction generating module is used for generating a regulation and control instruction according to the relative position of the target;

controlling the movement of the movable mechanism of the air conditioner to be controlled through a transmission module of the air conditioner to be controlled according to the regulation and control instruction to enable the relative position of the second air outlet and the first air outlet to be a target relative position,

the movable mechanism is used for controlling the position of the second air outlet on the air conditioner to be controlled.

8. An air conditioner, characterized by comprising a first air outlet and a second air outlet, wherein the air conditioner regulates the position of the second air outlet relative to the first air outlet through a movable mechanism according to the air outlet position regulating method of any one of claims 1 to 6.

9. A computer-readable storage medium, on which a computer program is stored which, when executed by a processor, causes the processor to carry out the steps of the method according to any one of claims 1 to 6.

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