WO2019024819A1

WO2019024819A1 - Control method for air conditioner

Info

Publication number: WO2019024819A1
Application number: PCT/CN2018/097620
Authority: WO
Inventors: 董志钢; 樊明敬; 刘伟彤; 吕福俊; 郝红波; 郭志闯; 李朋; 唐波; 赵丹; 李进涛; 刘翔; 张青花; 曹壬艳; 魏菡; 臧金玲; 周宝娟
Original assignee: 青岛海尔空调器有限总公司
Priority date: 2017-08-01
Filing date: 2018-07-27
Publication date: 2019-02-07
Also published as: CN107328029A

Abstract

A control method for an air conditioner, the air conditioner comprising at least one indoor heat exchanger (61) arranged in an indoor unit (10), a human body temperature sensing device (70) used for sensing human body temperature and a plurality of sets of independent air guide mechanisms arranged in an air supply outlet of the indoor unit (10). Throttling devices (62) are in serial connection on a refrigerant flow path where each indoor heat exchanger (61) is located. The control method comprises: (S10) partitioning an indoor environment where the indoor unit (10) is located into a plurality of independent areas, and obtaining the temperature of each human body in each area by means of the human body temperature sensing device (70); (S20) calculating the average human body temperature in each area; (S30) and when the average human body temperature in any area exceeds a preset human body temperature range, regulating the opening degree of a throttling device (62) which is in serial connection to one indoor heat exchanger (61) of the at least one indoor heat exchanger (61) and/or the state of a set of air guide mechanisms corresponding to the area.

Description

Air conditioner control method

Technical field

The present invention relates to energy saving technologies, and in particular to a method of controlling an air conditioning device.

Background technique

With the development trend of intelligent control and comfort control of air conditioners, existing air conditioners can intelligently control air conditioners according to the temperature of indoor human bodies. However, in the intelligent control of the air conditioner, only the average temperature change in the room is considered, and other environmental conditions, such as the body temperature values of different individuals, are not considered. Therefore, the control of the existing air conditioner based on the activity amount is not comprehensive, accurate, and the degree of intelligence is low, and the balance control of energy saving and comfort cannot be achieved.

Moreover, in the existing household air conditioner, at the same time, during cooling or heating, the temperature of the wind blown by the indoor unit is a temperature, and various air outlet temperatures cannot be realized to meet the somatosensory demands of different users. .

Summary of the invention

An object of the present invention is to overcome at least one of the deficiencies in the prior art and to provide a control method for an air conditioning apparatus capable of realizing different air supply temperatures in different areas to meet the differentiated needs of users.

Another object of the invention is the accuracy of the supply air temperature control in different regions.

Yet another object of the present invention is to improve the user's comfort experience.

In order to achieve the above object, the present invention provides a control method of an air conditioning apparatus including at least one indoor heat exchanger disposed in an indoor unit thereof for exchanging heat with indoor air, and for sensing a body temperature of a human body. a human body temperature sensing device and a plurality of sets of mutually independent air guiding mechanisms disposed at the air blowing opening of the indoor unit, wherein the refrigerant flow path of each of the indoor heat exchangers is connected in series with a throttle device; and the control Methods include:

Dividing the indoor environment in which the indoor unit is located into a plurality of mutually independent regions, and acquiring the temperature of each human body in each region by the human body temperature sensing device;

Calculate the average temperature of the human body in each area;

Adjusting the opening and/or the throttling device in series with an indoor heat exchanger of the at least one indoor heat exchanger when the average temperature of the human body in any of the regions exceeds the preset human body temperature range The state of the corresponding set of air guiding mechanisms in the area to adjust the supply air temperature and/or the amount of air supply in the area.

Optionally, the preset body temperature range has an upper limit temperature value and a lower limit temperature value, and the lower limit temperature value is less than the upper limit temperature value;

The number of the indoor heat exchanger, the throttling device and the area are both two, and the air guiding mechanism at the air supply opening is divided into two groups, each of the areas being associated with a corresponding one of the indoors A heat exchanger, a corresponding said throttling device, and a corresponding set of air guiding mechanisms.

Optionally, adjusting an opening of a throttling device connected in series with an indoor heat exchanger of the at least one indoor heat exchanger when an average temperature of the human body in any region exceeds a preset body temperature range And/or the step of the state of the group of air guiding mechanisms corresponding to the area specifically includes:

In the cooling state, when the average temperature of the human body in any of the regions is greater than the upper limit temperature value, the opening degree of a throttling device corresponding to the region is increased, and then a group of wind guides corresponding to the region is added. The state of the mechanism is adjusted to minimize the angle formed by the vertical bisector of the region.

Optionally, adjusting an opening of a throttling device connected in series with an indoor heat exchanger of the at least one indoor heat exchanger when an average temperature of the human body in any region exceeds a preset body temperature range And the step of the state of the group of air guiding mechanisms corresponding to the area further includes:

In the cooling state, when the average temperature of the human body in any of the regions is less than the lower limit temperature value, the opening degree of a throttling device corresponding to the region is reduced, and then a group of wind guides corresponding to the region is The state of the mechanism is adjusted such that it forms an initial angle with the vertical bisector of the region.

When the average temperature of the human body in any region is less than the lower limit temperature value in the heating state, the opening degree of a throttle device corresponding to the region is increased, and then a group of wind guides corresponding to the region is added The state of the mechanism is adjusted to minimize the angle formed by the vertical bisector of the region.

When the average temperature of the human body in any region is greater than the upper limit temperature value in the heating state, the opening degree of a throttle device corresponding to the region is reduced, and then a group of wind guides corresponding to the region is selected The state of the mechanism is adjusted such that it forms an initial angle with the vertical bisector of the region.

The number of the indoor heat exchangers is two, which are respectively a left side heat exchanger and a right side heat exchanger arranged in a lateral direction; the number of the throttling devices is two, respectively, and the heat exchange with the left side a left-hand throttling device and a right-hand throttling device connected in series with the right heat exchanger; the number of the regions is three, respectively a left region, a right region, and the left a middle portion between the side region and the right side region; the air guiding mechanism at the air blowing port is divided into three groups, respectively being a left side air guiding mechanism corresponding to the left side area, and the middle area Corresponding central air guiding mechanism and right side air guiding mechanism corresponding to the right side region.

Adjusting the opening degree of the left side throttle device and the state of the left side air guiding mechanism when the average human body temperature in the left side region is outside the preset body temperature range; when the human body in the right side region Adjusting an opening degree of the right throttle device and a state of the right air guiding mechanism when an average temperature is outside the preset human body temperature range;

Adjusting the middle portion when the average temperature of the human body in the middle region exceeds the preset human body temperature range on the basis of determining the opening degree of the left side throttle device and the right throttle device The state of the air guiding mechanism.

Optionally, on the basis of determining the opening degree of the left side throttle device and the right side throttle device, when the average temperature of the human body in the middle region exceeds the preset human body temperature range, The operation of adjusting the state of the central air guiding mechanism specifically includes:

Based on the determination of the opening degree of the left side throttling device and the right side throttling device, when the air conditioning device is in a heating state, and when the average temperature of the human body in the central region is greater than the upper limit temperature And when the value is adjusted, the state of the central air guiding mechanism is adjusted such that it forms an initial angle with the vertical bisector of the central portion; when the air conditioning device is in a heating state, and when the middle portion When the average human body temperature in the region is less than the lower limit temperature value, the state of the central air guiding mechanism is adjusted to minimize the angle formed by the vertical bisector of the central region.

Based on the determination of the opening degree of the left side throttling device and the right side throttling device, when the air conditioning device is in a cooling state, and when the average temperature of the human body in the middle region is greater than the upper limit temperature value Adjusting the state of the central air guiding mechanism such that it forms the smallest angle with the vertical bisector of the central portion; when the air conditioning device is in a cooling state, and when the human body in the central region When the average temperature is less than the lower limit temperature value, the state of the central air guiding mechanism is adjusted to form an angle with a predetermined size of the central portion.

The control method of the air conditioner of the present invention divides the indoor environment into a plurality of mutually independent regions, and acquires the human body temperature in each region by human sensing technology, and then calculates the average human body temperature in each region, and finally according to each region. The relationship between the average human body temperature and the preset human body temperature range adjusts the opening degree of the throttle device and/or the swing state of the corresponding air guiding mechanism, thereby adjusting the air supply temperature and/or the air supply amount of each region, thereby realizing At the same time, according to the temperature requirements of different users in different areas, the purpose of adjusting the different outlet temperatures of each area is adopted, and the wind guide mechanism is used to send different amounts of wind to the users in different areas through the wind guiding mechanism. User's differentiated needs.

Further, when the indoor environment is divided into two regions, the outlet air temperature and the air outlet amount in each region can be jointly adjusted by the opening degree of one throttling device and the swing state of a group of air guiding mechanisms, and the adjustment precision is high. , more effectively meet the user's differentiated needs. When the indoor environment is divided into three regions, the outlet air temperature and the air outlet volume in the left and right regions can be adjusted together by the opening degree of one throttle device and the swing state of a group of air guiding mechanisms, and the outflow in the middle region The air volume is adjusted by the swing state of a group of air guiding mechanisms after the opening of the two throttling devices is determined. Thereby, the adjustment accuracy of the amount of airflow in each area is relatively high.

Further, the present invention can also enable users of different body temperatures to experience different usage sensations by adjusting the opening of the throttle device and the state of the air guiding mechanism so that the air conditioner is in a cooling state or a heating state. For example, some users can have a strong sense of wind, so as to achieve better cooling effect and heating effect, and at the same time, some users have a cool, cold or warm and soft feeling, thereby achieving a better comfort experience. effect.

The above as well as other objects, advantages and features of the present invention will become apparent to those skilled in the <

DRAWINGS

Some specific embodiments of the present invention will be described in detail, by way of example, and not limitation, The same reference numbers in the drawings identify the same or similar parts. Those skilled in the art should understand that the drawings are not necessarily drawn to scale. In the figure:

1 is a schematic flow chart of a control method of an air conditioning apparatus according to an embodiment of the present invention;

2 is a schematic schematic diagram of an air conditioning apparatus according to an embodiment of the present invention;

3 is a flow chart showing a control method when the air conditioning apparatus is in a cooling state according to an embodiment of the present invention;

4 is a flow chart of a control method when an air conditioning apparatus is in a heating state according to an embodiment of the present invention;

5 to FIG. 8 are schematic structural views respectively showing air supply to the air supply regions at different air blowing angles according to an embodiment of the present invention;

Figure 9 is a schematic structural view of an air conditioning apparatus according to another embodiment of the present invention;

10 is a flow chart of a control method when an air conditioning apparatus is in a heating state according to another embodiment of the present invention;

11 is a flow chart showing a control method of an air conditioning apparatus in a cooling state according to another embodiment of the present invention;

12 and 13 are schematic structural views respectively showing air supply to the air supply regions at different air blowing angles according to another embodiment of the present invention.

Detailed ways

Embodiments of the present invention provide a method for controlling an air conditioner. The air conditioner 1 includes at least one indoor heat exchanger disposed in the indoor unit 10 for exchanging heat with indoor air, a human body temperature sensing device 70 for sensing body temperature, and a air supply port provided at the indoor unit. A plurality of independent air guiding mechanisms are arranged, and a flow device is connected in series on the refrigerant flow path where each indoor heat exchanger is located. Specifically, the number of air blowing ports may be one, two or more than two. The number of indoor heat exchangers and throttling devices can be one, two or more than two. The indoor heat exchanger is preferably a plate evaporator. In other embodiments, the indoor heat exchanger may also be a multi-fold evaporator or other suitably shaped evaporator. The human body temperature sensing device can be disposed outside the casing of the indoor unit to sense the body temperature in the indoor environment. The human body temperature sensing device can be a human body infrared sensor or a plurality of human body infrared sensors. The air guiding mechanism is preferably a pendulum blade, and each group of air guiding mechanisms may include a plurality of pendulum leaves.

1 is a schematic flow chart of a control method of an air conditioning apparatus according to an embodiment of the present invention. The control method of the present invention includes:

Step S10, dividing the indoor environment in which the indoor unit is located into a plurality of mutually independent regions, and acquiring the temperature of each human body in each region by the human body temperature sensing device;

Step S20, calculating an average temperature of the human body in each area;

Step S30, when the average temperature of the human body in any region is outside the preset human body temperature range, adjusting the opening degree of the throttling device connected in series with one of the indoor heat exchangers of the at least one indoor heat exchanger and/or Or a swing state of a group of air guiding mechanisms corresponding to the area to adjust the supply air temperature and/or the air supply amount in the area.

It should be noted that the "preset body temperature range" as used in the present invention means a human body temperature range which is set in advance in the controller of the air conditioner.

That is, the control method of the present invention divides the indoor environment into a plurality of mutually independent regions, and acquires the human body temperature in each region by human sensing technology, and then calculates the average human body temperature in each region, and finally according to each The relationship between the average human body temperature in the region and the preset human body temperature range adjusts the opening degree of the throttle device and/or the swing state of the corresponding air guiding mechanism, thereby adjusting the air supply temperature and/or the air supply amount of each region, thereby realizing At the same time, according to the temperature requirements of different users in different regions, the purpose of adjusting the different outlet temperatures of each region is adopted, and the wind guiding device is used to send different amounts of wind to the users in different regions through the wind guiding mechanism. The differentiated needs of users.

In some embodiments of the invention, the preset body temperature range has an upper limit temperature value and a lower limit temperature value, and the lower limit temperature value is less than the upper limit temperature value. Specifically, in one embodiment, the preset body temperature range may be 36.2 ° C to 36.8 ° C. The upper limit temperature value is 36.8 ° C, and the lower limit temperature value is 36.2 ° C. In other embodiments, the upper limit temperature value of the preset body temperature range may also be any temperature value between 36.6 ° C and 37.0 ° C, such as 36.6 ° C, 36.7 ° C, 36.9 ° C or 37.0 ° C. The lower limit temperature value of the preset body temperature range may also be any temperature value between 36.0 ° C and 36.4 ° C, such as 36.0 ° C, 36.1 ° C, 36.3 ° C or 36.4 ° C. In some alternative embodiments, the upper limit temperature value and the lower limit temperature value of the preset body temperature range may also be other suitable temperature values as long as the lower limit temperature value is less than the upper limit temperature value. That is to say, the production personnel or users of the air conditioner before leaving the factory can set or adjust the specific value and range of the preset human body temperature range according to the actual situation.

2 is a schematic schematic diagram of an air conditioning apparatus in accordance with one embodiment of the present invention. Further, referring to FIG. 2, the air conditioner 1 includes a compressor 64, a four-way switching valve 65, an outdoor heat exchanger 66, and an outdoor fan 67 disposed in the outdoor unit thereof. In the embodiment shown in Fig. 2, the number of indoor heat exchangers 61, throttling devices 62 and zones is two, that is, the indoor environment is divided into two mutually independent regions. The air guiding mechanism at the indoor air supply duct is divided into two groups, each of which corresponds to a corresponding indoor heat exchanger 61, a corresponding throttle device 62, and a corresponding set of air guiding mechanisms. Further, the air conditioner 1 may further include an indoor fan 63 for driving indoor air supply, and the number of indoor fans 63 may be the same as the number of indoor heat exchangers 61. At this time, referring to the flowchart of the control method when the air conditioner shown in FIG. 3 is in the cooling state, the above step S30 specifically includes:

In the cooling state, when the average temperature of the human body in any region is greater than the upper limit temperature value of the preset human body temperature range, the opening degree of a throttle device corresponding to the region is increased, and then the corresponding region is corresponding to the region. The state of the set of air guiding mechanisms is adjusted to minimize the angle formed by the vertical bisector of the area. In the cooling state, if the average temperature of the human body in a certain area is too high, it is necessary to lower the air supply temperature in the area and increase the air supply volume in the area, so that the user has a strong wind feeling, thereby achieving a comparison. Good cooling effect. The present invention can quickly reduce the supply air temperature of the region by increasing the opening of the throttle device corresponding to the region. At the same time, the invention also adjusts the state of the air guiding mechanism corresponding to the region such that it forms the smallest angle with the vertical bisector of the region, so as to reduce the friction between the airflow and the air guiding mechanism as much as possible, and reduce Loss of airflow rate to maximize airflow.

In some embodiments of the present invention, referring to FIG. 3, the foregoing step S30 specifically includes: when the average temperature of the human body in any area is less than the lower limit temperature value of the preset human body temperature range, in the cooling state, The opening of a throttle device corresponding to the region is then adjusted to a state of a group of air guiding mechanisms corresponding to the region such that it forms an initial angle with the vertical bisector of the region. In the cooling state, if the average temperature of the human body in a certain area is too low, it is necessary to increase the air supply temperature in the area and reduce the air supply amount in the area, so that the user has a cool and cold feeling, thereby Achieve better comfort experience. The present invention can quickly reduce the supply air temperature of the region by reducing the opening of the throttle device corresponding to the region. At the same time, the present invention also adjusts the state of the air guiding mechanism corresponding to the area such that it forms an angle with a vertical bisector of the area to a predetermined size to change the air supply amount and the air supply direction of the area, thereby avoiding The cold airflow blows the user, increasing the user's comfort experience in the area.

Further, when the average temperature of the human body in any area is neither greater than the upper limit temperature value nor less than the lower limit temperature value (ie, within the preset body temperature range), the opening of a throttle device corresponding to the region is maintained. The degree and state of a group of air guiding mechanisms are unchanged.

4 is a flow chart of a control method when the air conditioning apparatus is in a heating state according to an embodiment of the present invention. In some embodiments of the present invention, referring to FIG. 4, the above step S30 may specifically include: when the average temperature of the human body in any region is less than the lower limit temperature value of the preset human body temperature range in the heating state, the increase and the The opening of a corresponding throttling device in the region is then adjusted to a state of a set of air guiding mechanisms corresponding to the region such that it forms the smallest angle with the vertical bisector of the region. In the heating state, if the average temperature of the human body in a certain area is too low, it is necessary to increase the air supply temperature and the air supply amount in the area, so that the user has a strong wind feeling, thereby achieving better heating. effect. According to the present invention, by increasing the opening degree of the throttle device corresponding to the region, the air supply temperature of the region can be quickly increased. At the same time, the invention also adjusts the state of the air guiding mechanism corresponding to the region such that it forms the smallest angle with the vertical bisector of the region, so as to reduce the friction between the airflow and the air guiding mechanism as much as possible, and reduce Loss of airflow rate to maximize airflow.

In some embodiments of the present invention, referring to FIG. 4, the foregoing step S30 may further include: when the average temperature of the human body in any area is greater than the upper limit temperature value of the preset human body temperature range in the heating state, The opening of a corresponding throttling device in the region is then adjusted to a state of a set of air guiding mechanisms corresponding to the region such that it forms an initial angle with the vertical bisector of the region. In the heating state, if the average temperature of the human body in a certain area is too high, it is necessary to reduce the supply air temperature and the air supply amount in the area, so that the user has a warm and not warm soft feeling, thereby achieving better. Comfortable experience. The present invention can quickly reduce the supply air temperature of the region by reducing the opening of the throttle device corresponding to the region. At the same time, the present invention also adjusts the state of the air guiding mechanism corresponding to the area such that it forms an angle with a vertical bisector of the area to a predetermined size to change the air supply amount and the air supply direction of the area, thereby avoiding Hot and cold airflow blows the user, increasing the user's comfort experience in the area.

It can be seen that when the indoor environment is divided into two regions, the outlet air temperature and the air outlet amount in each region can be jointly adjusted by the opening degree of one throttling device and the swing state of a group of air guiding mechanisms, and the adjustment precision is high. More effectively meet the differentiated needs of users.

5 to 8 are schematic structural views respectively showing air supply to the air supply regions at different air blowing angles according to an embodiment of the present invention. In FIGS. 5 to 8, the dotted line is the boundary line between the adjacent two regions, the broken line is the vertical bisector of the corresponding area, and the straight line arrow indicates the airflow direction. Specifically, referring to FIG. 5 to FIG. 8 , the two air supply areas of the air conditioner (that is, the two areas in which the indoor environment is divided) are spaces in the range of 0 to 90 degrees in front of the air conditioner. The area of the area and the horizontal angle in the range of 90 ° ~ 180 °. For ease of description and understanding, the two regions may be Region A and Region B, respectively. At this time, the vertical bisectors M and N of the region A and the region B respectively extend 45° toward the front surface of the air conditioner to extend laterally forward.

In the embodiment shown in FIG. 5, both the air guiding mechanism 91 corresponding to the area A and the air guiding mechanism 92 corresponding to the area B extend in the front-rear direction so as to be perpendicular to the vertical plane M of the area A and the area B, respectively. N forms an angle of 45° (the angle is an angle of a predetermined size). In the embodiment shown in FIG. 6, the air guiding mechanism 91 corresponding to the area A extends in the front-rear direction so as to form an angle of 45° with the vertical bisector M of the area A (the angle is an angle of a predetermined size) ). The air guiding mechanism 92 corresponding to the region B extends toward the front side of the B region so as to form a minimum angle with the vertical bisector plane N of the region B, and the minimum angle may be between 0° and 10°. In the embodiment shown in Fig. 7, the air guiding mechanism 91 and the air guiding mechanism 92 corresponding to the area A and the area B extend toward the front side of the A area side and the front side of the B area, respectively, so as to be respectively vertical with the area A and the area B. The straight facets M and N form the smallest angle. Similarly, the minimum angle can be between 0° and 10°. In the embodiment shown in FIG. 8, the air guiding mechanism 92 corresponding to the region B extends in the front-rear direction so as to form an angle of 45° with the vertical bisector plane N of the region B (the angle is an angle of a predetermined size) ). The air guiding mechanism 91 corresponding to the area A extends toward the front side of the A area side to form a minimum angle with the vertical bisector M of the area A, and the minimum angle can be set between 0 and 10 degrees.

Fig. 9 is a schematic structural view of an air conditioning apparatus according to another embodiment of the present invention. In some embodiments of the invention, the number of indoor heat exchangers is two, respectively a left side heat exchanger 81 and a right side heat exchanger 82 arranged in a lateral direction. The number of the throttling devices is two, which are a left throttling device connected in series with the left side heat exchanger 81 and a right throttling device connected in series with the right side heat exchanger 82. Accordingly, the number of indoor fans 63 is also two. The number of the regions is three, which are the left region C, the right region E, and the middle region D between the left region C and the right region E. The air guiding mechanisms at the air outlet are divided into three groups, respectively A left air guiding mechanism 93 corresponding to the left side area C, a middle air guiding mechanism 94 corresponding to the middle area D, and a right side air guiding mechanism 95 corresponding to the right side area E.

At this time, the above step S30 may specifically include: adjusting the opening degree of the left throttle device and the state of the left air guiding mechanism 93 when the average temperature of the human body in the left region C is outside the preset human body temperature range; When the average temperature of the human body in the right area E exceeds the preset body temperature range, adjust the opening degree of the right throttle device and the state of the right air guiding mechanism 95; and the throttle device on the left side and the right side throttle Based on the determination of the opening degree of the device, the state of the central air guiding mechanism 94 is adjusted when the average temperature of the human body in the middle portion D exceeds the preset human body temperature range.

That is to say, when the indoor environment is divided into three regions, and the air conditioner has only two indoor heat exchangers and two throttling devices, the average human body temperature and the preset human body temperature may be firstly determined according to the end regions of the two sides. The relationship between the ranges determines the opening of the two throttling devices and the state of the corresponding two sets of air guiding mechanisms, and then determines the central air guiding mechanism according to the relationship between the average human body temperature in the central region and the preset human body temperature range. status. In other words, when the indoor environment is divided into three regions, the outlet air temperature and the air outlet volume in the left and right regions can be adjusted together by the opening degree of one throttle device and the swing state of a group of air guiding mechanisms, and the middle portion The amount of air in the area is adjusted by the swing state of a group of air guiding mechanisms after the opening of the two throttle devices is determined. Thereby, the adjustment accuracy of the amount of airflow in each area is relatively high.

Figure 10 is a flow chart showing a control method of an air conditioning apparatus in a heating state according to another embodiment of the present invention. Referring to FIG. 10, based on the determination of the opening degree of the left side throttling device and the right side throttling device, when the average temperature of the human body in the middle portion D exceeds the preset human body temperature range, the adjustment of the central air guiding mechanism 94 is performed. The operation of the state specifically includes:

Based on the determination of the opening degree of the left throttle device and the right throttle device, when the air conditioner is in a heating state, and the average temperature of the human body in the middle portion D is greater than the upper limit temperature value, the middle air guiding mechanism is The state of 94 is adjusted such that it forms an angle with a vertical bisector of the central region D by a predetermined size; when the air conditioner is in a heating state, and the average temperature of the human body in the middle region D is less than the lower limit temperature value, The state of the central air guiding mechanism 94 is adjusted such that it forms the smallest angle with the vertical bisector of the central portion D. When the average temperature of the human body in the central region D is neither greater than the upper limit temperature nor less than the lower limit temperature value, the state of the central air guiding mechanism is maintained.

11 is a flow chart showing a control method of an air conditioning apparatus in a cooling state according to another embodiment of the present invention. Referring to FIG. 11, on the basis of the determination of the opening degree of the left throttle device and the right throttle device, when the average temperature of the human body in the middle portion D exceeds the preset human body temperature range, the adjustment of the central air guiding mechanism 94 is performed. The operation of the state specifically includes:

Based on the determination of the opening degree of the left throttle device and the right throttle device, when the air conditioner is in a cooling state, and the average temperature of the human body in the middle portion D is greater than the upper limit temperature value, the central air guiding mechanism 94 is The state is adjusted such that it forms the smallest angle with the vertical bisector of the central region D; when the air conditioning device is in a cooling state, and the average human body temperature in the middle region D is less than the lower limit temperature value, the central air guiding mechanism is The state of 94 is adjusted such that it forms an angle of a predetermined size with the vertical bisector of the central region D. When the average temperature of the human body in the central region D is neither greater than the upper limit temperature nor less than the lower limit temperature value, the state of the central air guiding mechanism is maintained.

It should be noted that the opening degree of the left throttle device and the state adjustment of the left side air guiding mechanism 93 and the opening degree of the right side throttle device and the state adjustment of the right side air guiding mechanism 95 are not limited in order. That is, the opening degree of the left side throttle device and the state of the left side air guiding mechanism 93 may be adjusted first, and then the opening degree of the right side throttle device and the state of the right side air guiding mechanism 95 may be adjusted; The opening degree of the flow device and the state of the right side air guiding mechanism 95 adjust the opening degree of the left side throttle device and the state of the left side air guiding mechanism 93. Further, the opening degree of the left throttle device and the state adjustment of the left side air guiding mechanism 93, and the opening degree of the right side throttle device and the state adjusting process of the right side air guiding mechanism 95 are implemented as shown in FIGS. 3 and 4. The examples are similar and will not be described here.

12 and 13 are schematic structural views respectively showing air supply to the air supply regions at different air blowing angles according to another embodiment of the present invention. In FIGS. 12 to 13, the dotted line is the boundary line between two adjacent regions, the broken line is the vertical bisector of the corresponding area, and the straight line arrow indicates the direction of the air flow. Specifically, referring to FIG. 12 to FIG. 13 , the three air supply areas of the air conditioner (that is, the three areas in which the indoor environment is divided) are respectively left in the horizontal angle of 0 to 60° in front of the air conditioner. The side region C, the central region D having a horizontal angle in the range of 60° to 120°, and the right region E having a horizontal angle in the range of 120° to 180°. The vertical bisector plane X of the left side region C forms a 30° angle with the forward surface of the air conditioner to extend to the left front side, and the vertical bisector plane Y of the middle region D extends perpendicularly to the front surface of the air conditioner, and the right side The vertical bisector plane Z of the region E forms a 30° angle with the forward surface of the air conditioner to extend to the right front side.

In the embodiment of Fig. 12, the left side air guiding mechanism 93 extends in the front-rear direction so as to form an angle of 60° with the vertical bisector plane X of the left side area C (the angle is an angle of a predetermined size). The central air guiding mechanism 94 extends in the front-rear direction so as to form a minimum angle of 0° with the vertical bisector surface Y of the central portion D. The right wind guiding mechanism 95 is inclined toward the right front side so as to form an angle with the smallest angle of the vertical bisector Z of the right side region E, and the minimum angle can be set between 0° and 10°. In the embodiment of FIG. 13, the left air guiding mechanism 93 is inclined to the left front so as to form an angle with the smallest angle X with the vertical bisector X of the left side region C, and the minimum angle may be between 0° and 10°. The value between them. The middle air guiding mechanism 94 is inclined toward the right front side so as to form an angle of 45° with the vertical bisector surface Y of the middle portion D (the included angle is an angle of a predetermined size). The right wind guiding mechanism 95 is inclined toward the right front side so as to form an angle with the smallest angle of the vertical bisector Z of the right side region E, and the minimum angle can be set between 0° and 10°.

Those skilled in the art will appreciate that in some alternative embodiments of the invention, the indoor environment may also be divided into four or more regions.

In other alternative embodiments, when the indoor environment is divided into two or three regions, the angular range of each region is not limited to the range of angles described in the above embodiments, and other options may be selected according to actual conditions. The way of division. At the same time, the "pre-set angle" formed by the air guiding mechanism corresponding to each area and the vertical bisector of the area is not limited to the angle described in the above embodiment, and may be other pre- Set the angle value.

In this regard, it will be appreciated by those skilled in the <RTIgt;the</RTI> <RTIgt; </ RTI> <RTIgt; </ RTI> <RTIgt; </ RTI> <RTIgt; The content directly determines or derives many other variations or modifications consistent with the principles of the invention. Therefore, the scope of the invention should be understood and construed as covering all such other modifications or modifications.

Claims

A method of controlling an air conditioner, comprising: at least one indoor heat exchanger disposed in an indoor unit thereof for exchanging heat with indoor air, a human body temperature sensing device for sensing body temperature of the human body, and a plurality of sets of mutually independent air guiding mechanisms at the air supply opening of the indoor unit, wherein each of the indoor heat exchangers is connected to the refrigerant flow path in series with a throttle device; and the control method comprises:

Dividing the indoor environment in which the indoor unit is located into a plurality of mutually independent regions, and acquiring temperature of each human body in each region by the human body temperature sensing device; calculating an average human body temperature in each region;

Adjusting the opening and/or the throttling device in series with an indoor heat exchanger of the at least one indoor heat exchanger when the average temperature of the human body in any of the regions exceeds the preset human body temperature range The state of the corresponding set of air guiding mechanisms in the area to adjust the supply air temperature and/or the amount of air supply in the area.
The control method according to claim 1, wherein

The preset body temperature range has an upper limit temperature value and a lower limit temperature value, the lower limit temperature value being less than the upper limit temperature value;

The number of the indoor heat exchanger, the throttling device and the area are both two, and the air guiding mechanism at the air supply opening is divided into two groups, each of the areas being associated with a corresponding one of the indoors A heat exchanger, a corresponding said throttling device, and a corresponding set of air guiding mechanisms.
The control method according to claim 2, wherein

Adjusting the opening and/or the throttling device in series with an indoor heat exchanger of the at least one indoor heat exchanger when the average temperature of the human body in any of the regions exceeds the preset human body temperature range The steps of the state of the corresponding group of air guiding mechanisms in the region specifically include:

In the cooling state, when the average temperature of the human body in any of the regions is greater than the upper limit temperature value, the opening degree of a throttling device corresponding to the region is increased, and then a group of wind guides corresponding to the region is added. The state of the mechanism is adjusted to minimize the angle formed by the vertical bisector of the region.
The control method according to claim 3, wherein

Adjusting the opening and/or the throttling device in series with an indoor heat exchanger of the at least one indoor heat exchanger when the average temperature of the human body in any of the regions exceeds the preset human body temperature range The step of the state of the corresponding group of air guiding mechanisms in the region specifically includes:

In the cooling state, when the average temperature of the human body in any of the regions is less than the lower limit temperature value, the opening degree of a throttling device corresponding to the region is reduced, and then a group of wind guides corresponding to the region is The state of the mechanism is adjusted such that it forms an initial angle with the vertical bisector of the region.
The control method according to claim 2, wherein

Adjusting the opening and/or the throttling device in series with an indoor heat exchanger of the at least one indoor heat exchanger when the average temperature of the human body in any of the regions exceeds the preset human body temperature range The steps of the state of the corresponding group of air guiding mechanisms in the region specifically include:

When the average temperature of the human body in any region is less than the lower limit temperature value in the heating state, the opening degree of a throttle device corresponding to the region is increased, and then a group of wind guides corresponding to the region is added The state of the mechanism is adjusted to minimize the angle formed by the vertical bisector of the region.
The control method according to claim 5, wherein

Adjusting the opening and/or the throttling device in series with an indoor heat exchanger of the at least one indoor heat exchanger when the average temperature of the human body in any of the regions exceeds the preset human body temperature range The step of the state of the corresponding group of air guiding mechanisms in the region specifically includes:

When the average temperature of the human body in any region is greater than the upper limit temperature value in the heating state, the opening degree of a throttle device corresponding to the region is reduced, and then a group of wind guides corresponding to the region is selected The state of the mechanism is adjusted such that it forms an initial angle with the vertical bisector of the region.
The control method according to claim 1, wherein

The preset body temperature range has an upper limit temperature value and a lower limit temperature value, the lower limit temperature value being less than the upper limit temperature value;

The number of the indoor heat exchangers is two, which are respectively a left side heat exchanger and a right side heat exchanger arranged in a lateral direction; the number of the throttling devices is two, respectively, and the heat exchange with the left side a left-hand throttling device and a right-hand throttling device connected in series with the right heat exchanger; the number of the regions is three, respectively a left region, a right region, and the left a middle portion between the side region and the right side region; the air guiding mechanism at the air blowing port is divided into three groups, respectively being a left side air guiding mechanism corresponding to the left side area, and the middle area Corresponding central air guiding mechanism and right side air guiding mechanism corresponding to the right side region.
The control method according to claim 7, wherein

Adjusting the opening and/or the throttling device in series with an indoor heat exchanger of the at least one indoor heat exchanger when the average temperature of the human body in any of the regions exceeds the preset human body temperature range The steps of the state of the corresponding group of air guiding mechanisms in the region specifically include:

Adjusting the opening degree of the left side throttle device and the state of the left side air guiding mechanism when the average human body temperature in the left side region is outside the preset body temperature range; when the human body in the right side region Adjusting an opening degree of the right throttle device and a state of the right air guiding mechanism when an average temperature is outside the preset human body temperature range;

Adjusting the middle portion when the average temperature of the human body in the middle region exceeds the preset human body temperature range on the basis of determining the opening degree of the left side throttle device and the right throttle device The state of the air guiding mechanism.
The control method according to claim 8, wherein

Adjusting the middle portion when the average temperature of the human body in the middle region exceeds the preset human body temperature range on the basis of determining the opening degree of the left side throttle device and the right throttle device The operation of the state of the air guiding mechanism specifically includes:

Based on the determination of the opening degree of the left side throttling device and the right side throttling device, when the air conditioning device is in a heating state, and when the average temperature of the human body in the central region is greater than the upper limit temperature a value, the state of the central air guiding mechanism is adjusted such that it forms an initial angle with the vertical bisector of the central region; when the air conditioning device is in a heating state, and when the central region When the average human body temperature is less than the lower limit temperature value, the state of the middle air guiding mechanism is adjusted to minimize the angle formed by the vertical bisector of the middle portion.
The control method according to claim 8, wherein

Adjusting the middle portion when the average temperature of the human body in the middle region exceeds the preset human body temperature range on the basis of determining the opening degree of the left side throttle device and the right throttle device The operation of the state of the air guiding mechanism specifically includes: when the left throttle device and the right throttle device are determined to be open, when the air conditioner is in a cooling state, and when in the middle region When the average human body temperature is greater than the upper limit temperature value, the state of the central air guiding mechanism is adjusted to be the smallest angle formed by the vertical bisector of the central region; when the air conditioning device is in a cooling state And when the average temperature of the human body in the central region is less than the lower limit temperature value, adjusting the state of the central air guiding mechanism to form an angle with a predetermined size of the central region.