CN104279726A - Air conditioner and operation control method and system thereof - Google Patents

Abstract

The invention belongs to the technical field of air conditioner control, and provides an air conditioner and an operation control method and system thereof. The method includes: performing object type recognition on moving objects in an indoor space and judging whether pneumatic type objects exist in the moving objects or not; if yes, continuously judging whether motion of the pneumatic type objects is caused by wind power; when the motion of the pneumatic type objects is caused by the wind power, performing corresponding adjustment on operation parameters according to the motion state of the pneumatic type objects. Therefore, cold wind/hot wind outputted by the air conditioner can be driven through the air conditioner by the aid of air motion caused by the wind power existing indoor, refrigerating/heating speed of the indoor space and heat exchanging efficiency of the indoor space can be increased, and power consumption of the air conditioner can be lowered.

Description

A kind of air-conditioner and progress control method thereof and system

Technical field

The invention belongs to air conditioner controlling technology field, particularly relate to a kind of air-conditioner and progress control method thereof and system.

Background technology

At present, the operational mode of existing air-conditioner correspondingly determines the operational factors such as air-out direction, wind speed and leaving air temp according to the setting of user, and carry out work according to these operational factors.And in the actual application environment of air-conditioner, if there is air flowing (as electric fan work air-out or outdoor are blown into natural wind) in indoor environment, object in indoor environment is (as the curtain in the interior space, plant leaf, windbell, ornament etc.) corresponding activity (as swung with the wind) can be there is, therefore, when there is air flowing in indoor environment, if can drive by the air cold wind/hot blast that air-conditioner is exported that flows, then can contribute to accelerating air-conditioner to the refrigerating/heating speed of indoor, accelerate the heat exchange efficiency of the interior space, and the power consumption of air-conditioner can also be reduced thus further.And existing air-conditioner is owing to cannot drive by the air cold wind/hot blast exported by air-conditioner that flows, so the refrigerating/heating speed accelerated indoor, the heat exchange efficiency accelerating the interior space also just cannot be reached and reduce the object of power consumption.

Summary of the invention

The object of the present invention is to provide a kind of air-conditioner progress control method, be intended to solve existing air-conditioner because driving by the air cold wind/hot blast exported by air-conditioner that flows, and cause accelerating refrigerating/heating speed to the interior space, accelerate the heat exchange efficiency of the interior space and reduce the problem of air-conditioner power consumption.

The present invention is achieved in that a kind of air-conditioner progress control method, and it comprises the following steps:

Object type identification is carried out to each mobiles in the interior space, and judges whether there is pneumatic type object in each mobiles described;

If there is pneumatic type object in each mobiles described, then judge whether the activity of described pneumatic type object is caused by wind-force;

When the activity of described pneumatic type object be caused by wind-force time, the operational factor of active state to air-conditioner according to described pneumatic type object adjusts accordingly.

Present invention also offers a kind of air-conditioner operation control system, it comprises:

Object identification and judge module, for carrying out object type identification to each mobiles in the interior space, and judge whether there is pneumatic type object in each mobiles described;

Activity factor judge module, if for there is pneumatic type object in each mobiles described, then judges whether the activity of described pneumatic type object is caused by wind-force;

Air conditioner operation parameters adjusting module, for when the activity of described pneumatic type object be caused by wind-force time, the operational factor of active state to air-conditioner according to described pneumatic type object adjusts accordingly.

Another object of the present invention is also to provide a kind of air-conditioner comprising above-mentioned air-conditioner operation control system.

The present invention is by carrying out object type identification to each mobiles in the interior space, and judge in each mobiles, whether to there is pneumatic type object, if there is pneumatic type object in each mobiles, then continue to judge whether the activity of pneumatic type object is caused by wind-force, when judge the activity of pneumatic type object be caused by wind-force time, the operational factor of active state to air-conditioner according to this pneumatic type object adjusts accordingly, and then enable air-conditioner have air that wind-force the causes cold wind/hot blast exported by air-conditioner that flows by indoor to drive, thus the refrigerating/heating speed can accelerated the interior space, accelerate the heat exchange efficiency of the interior space and reduce the power consumption of air-conditioner.

Accompanying drawing explanation

Fig. 1 is the realization flow figure of the air-conditioner progress control method that the embodiment of the present invention provides;

Fig. 2 is the specific implementation flow chart of the step S3 in the air-conditioner progress control method shown in Fig. 1;

Fig. 3 is the specific implementation flow chart of the step S3 in the air-conditioner progress control method shown in Fig. 1;

Fig. 4 is the specific implementation flow chart of the step S3 in the air-conditioner progress control method shown in Fig. 1;

Fig. 5 is another realization flow figure of the air-conditioner progress control method that the embodiment of the present invention provides;

Fig. 6 is the structural representation of the air-conditioner operation control system that the embodiment of the present invention provides;

Fig. 7 is the internal structure schematic diagram of the air conditioner operation parameters adjusting module in the air-conditioner operation control system shown in Fig. 6;

Fig. 8 is the internal structure schematic diagram of the air conditioner operation parameters adjusting module in the air-conditioner operation control system shown in Fig. 6;

Fig. 9 is the internal structure schematic diagram of the air conditioner operation parameters adjusting module in the air-conditioner operation control system shown in Fig. 6;

Figure 10 is another structural representation of the air conditioner air-out direction control system that the embodiment of the present invention provides.

Detailed description of the invention

In order to make object of the present invention, technical scheme and advantage clearly understand, below in conjunction with drawings and Examples, the present invention is further elaborated.Should be appreciated that specific embodiment described herein only in order to explain the present invention, be not intended to limit the present invention.

Fig. 1 shows the realization flow of the air-conditioner progress control method that the embodiment of the present invention provides, and for convenience of explanation, illustrate only the part relevant to the embodiment of the present invention, details are as follows:

In step sl, object type identification is carried out to each mobiles in the interior space, and judge in each mobiles, whether to there is pneumatic type object.

Wherein, the step of object type identification is carried out specifically to each mobiles in the interior space: identify based on the type of existing image recognition technology by the mobiles in the interior space; Existing image recognition technology first can carry out image detection to the interior space, and according to the type (comprising animal, human body and mobilizable indoor decorative or object) of each mobiles in the indoor space of detected graphical analysis.For above-mentioned pneumatic type object, its refer to can because of wind-force effect the object of activity; It can thus be appreciated that animal and human's body is not obviously the object of activity because of wind-force effect, in the mobiles in the interior space, wind-force effect can be followed and the object of activity is generally curtain, plant leaf and ornament (as windbell) etc.

In step s 2, if there is pneumatic type object in each mobiles, then judge whether the activity of this pneumatic type object is caused by wind-force.

Wherein, judge that step that whether activity of this pneumatic type object caused by wind-force specifically: judge whether the activity of pneumatic type object exists based on existing image recognition technology and tangible execute main body, tangible execute main body if existed, then show that the activity of pneumatic type object causes by executing main body institute externally applied forces; If there is no tangiblely execute main body, then show that the activity of pneumatic type object is caused by wind-force.Such as: it is cause because the hand of child stirs branches and leaves that the branches and leaves of the potted flower in the interior space rock, image recognition technology can detect that the adjacent domain of branches and leaves exists mobiles (i.e. the hand of child), then now be judged to be that rocking of branches and leaves is that main body of executing by tangible causes, if and image recognition technology does not detect the adjacent domain mobiles of branches and leaves, be then judged to be that rocking of branches and leaves is caused by wind-force.

In step s3, when the activity of pneumatic type object be caused by wind-force time, the operational factor of active state to air-conditioner according to pneumatic type object adjusts accordingly.

Concrete, the active state of above-mentioned pneumatic type object mainly refers to activity direction and/or the movable amplitude of pneumatic type object; The operational factor of above-mentioned air-conditioner can be one or more in the air-out direction of air-conditioner, leaving air temp and wind speed.

For the step of according to the active state of pneumatic type object, the operational factor of air-conditioner being carried out to corresponding adjustment in step S3, as shown in Figure 2, it specifically can comprise the following steps:

S31. the moving ends position that pneumatic type object arrives because of wind-force effect is obtained;

S32. according to the resting position of pneumatic type object obtained in advance and the activity direction of the pneumatic type object of above-mentioned moving ends position acquisition;

S33. the windward orientation of this resting position is determined according to the resting position of pneumatic type object and activity direction, and using the source orientation of this windward orientation as wind-force;

S34. the air-out direction adjusting air-conditioner is blown to the orientation, source of wind-force to make air-conditioner.

Wherein, step S31 carries out image detection based on existing image recognition technology to pneumatic type object, and determines according to detected image the position that pneumatic type object arrives under wind-force effect, and this position is above-mentioned moving ends position.For resting position involved in step S32 and step S33, also be before control air-conditioner runs, continue to carry out image detection to the pneumatic type object in the interior space based on existing image recognition technology, and when pneumatic type object is remained static the position at place as above-mentioned resting position; Because the pneumatic type object in the interior space always at a time remains static, so resting position depends on to carry out long image to pneumatic type object and detect determined.And, for step S32, it specifically determines the activity direction of pneumatic type object according to the position relationship between the resting position of pneumatic type object and the moving ends position obtained, such as: resting position is in the right side of moving ends position, then can determine that the activity direction of pneumatic type object is for from right to left.Because step S32 has determined the activity direction of pneumatic type object, then step S33 just can according to the windward orientation of the resting position of pneumatic type object and activity direction determination resting position, then this windward orientation is the orientation, source of wind-force.

Such as: pneumatic type object is plant leaf, its resting position is A point, moving ends position is B point, if B point is in the left side of A point, then can determine that the activity direction of plant leaf is from right to left, then according to the right side that the windward orientation of the position of A point and the known A point of the activity direction (from right to left) of plant leaf is at A, and using the source orientation of the windward orientation (i.e. the right side of A point) of A point as wind-force.

Therefore, control air-conditioner by above-mentioned steps S34 to blow to the orientation, source of wind-force, the refrigerating/heating speed to the interior space can be accelerated, and then accelerate the heat exchange efficiency of the interior space, and due to the quickening of refrigerating/heating speed, the power consumption that air-conditioner is used for refrigerating/heating can be reduced significantly.

For the step of according to the active state of pneumatic type object, the operational factor of air-conditioner being carried out to corresponding adjustment in step S3, as shown in Figure 3, it specifically can comprise the following steps:

S311. the moving ends position that pneumatic type object arrives because of wind-force effect is obtained;

S312. according to the resting position of pneumatic type object obtained in advance and the movable amplitude of the pneumatic type object of above-mentioned moving ends position acquisition;

S313. according to leaving air temp and/or the wind speed of the movable amplitude adjustment air-conditioner of pneumatic type object.

Wherein, the step S31 shown in step S311 and Fig. 2 is identical, and the resting position of pneumatic type object is also mentioned in foregoing teachings, therefore repeats no more.For step S312, it specifically obtains the displacement of pneumatic type object according to the resting position of pneumatic type object and moving ends position, this displacement is the movable amplitude of pneumatic type object, movable amplitude is relevant with wind-force size, and wind-force is larger, then movable amplitude is larger, otherwise then movable amplitude is less.Therefore, the movable amplitude that step S313 just can obtain according to step S312 adjusts the leaving air temp of air-conditioner and/or wind speed, further, step S313 can be specifically: when the movable amplitude of pneumatic type object increases, and reduces the leaving air temp of air-conditioner and/or reduces the wind speed of air-conditioner; When the movable amplitude of pneumatic type object reduces, improve the leaving air temp of air-conditioner and/or increase the wind speed of air-conditioner.

Such as: pneumatic type object is curtain, its resting position is a place, curtain because of the moving ends position that wind-force effect arrives be b place, suppose that the displacement that curtain is located from a to b is 2 centimetres, and curtain is 3 centimetres in the displacement of previous moment, then show that the movable amplitude of curtain reduces, so can by improving the leaving air temp of air-conditioner and/or increasing the wind speed of air-conditioner, have air flow faster that wind-force causes to the object of the refrigerating/heating speed of the interior space to reach by indoor.

For the step of according to the active state of pneumatic type object, the operational factor of air-conditioner being carried out to corresponding adjustment in step S3, as shown in Figure 4, it specifically can comprise the following steps:

S321. the moving ends position that pneumatic type object arrives because of wind-force effect is obtained;

S322. according to the resting position of pneumatic type object that obtains in advance and the activity direction of the pneumatic type object of above-mentioned moving ends position acquisition and movable amplitude;

S323. according to pneumatic type object resting position and activity direction determine the windward orientation of this resting position, and using the source orientation of this windward orientation as wind-force;

S324. the air-out direction adjusting air-conditioner is blown to the orientation, source of wind-force to make air-conditioner, and according to pneumatic type object the movable amplitude adjustment leaving air temp of air-conditioner and/or wind speed.

Because step S321 is identical with above-mentioned step S31 and step S311, step S322 is then above-mentioned step S32 and the combination of step S312, step S323 is identical with above-mentioned step S33, step 324 item is above-mentioned step S34 and the combination of step S313, so its step S321 obtains detailed description all to step S324 in foregoing, therefore repeat no more.In addition, for above-mentioned step S324, its air flowing mainly utilizing existing wind-force in the interior space to cause, both controlled air-conditioner to blow to the orientation, source of wind-force, and the simultaneously leaving air temp of adjustable air-conditioner and/or wind speed, thus the refrigerating/heating speed to the interior space can be accelerated further.

In addition, as shown in Figure 5, further comprising the steps of before step S1:

S11. active state analysis is carried out to the object in the interior space, and identify mobiles and stationary object.

Wherein, step S11 is actually and carries out dynamic monitoring based on existing image recognition technology to the object in the interior space, is mobiles by the object identification being subjected to displacement change, is stationary object by the object identification not being subjected to displacement change.

In embodiments of the present invention, if step S1 judges there is not pneumatic type object in each mobiles, then do not perform step S2 to step S3, namely do not adjust the running status of air-conditioner, air-conditioner maintains original duty to be continued to run.

In sum, the embodiment of the present invention is by carrying out object type identification to each mobiles in the interior space, and judge in each mobiles, whether to there is pneumatic type object, if there is pneumatic type object in each mobiles, then continue to judge whether the activity of pneumatic type object is caused by wind-force, when judge the activity of pneumatic type object be caused by wind-force time, the operational factor of active state to air-conditioner according to this pneumatic type object adjusts accordingly, and then enable air-conditioner have air that wind-force the causes cold wind/hot blast exported by air-conditioner that flows by indoor to drive, thus the refrigerating/heating speed can accelerated the interior space, accelerate the heat exchange efficiency of the interior space and reduce the power consumption of air-conditioner.

Based on above-mentioned air-conditioner progress control method, the embodiment of the present invention additionally provides a kind of air-conditioner operation control system, and as shown in Figure 6, it comprises:

Object identification and judge module 100, for carrying out object type identification to each mobiles in the interior space, and judge whether there is pneumatic type object in each mobiles;

Activity factor judge module 200, if for there is pneumatic type object in each mobiles, then judges whether the activity of this pneumatic type object is caused by wind-force;

Air conditioner operation parameters adjusting module 300, adjusts accordingly for the operational factor of active state to air-conditioner when pneumatic type object.

Wherein, each mobiles in object identification and judge module 100 pairs of interior spaces carries out the process of object type identification specifically: identify based on the type of existing image recognition technology by the mobiles in the interior space; Existing image recognition technology first can carry out image detection to the interior space, and according to the type (comprising animal, human body and mobilizable indoor decorative or object) of each mobiles in the indoor space of detected graphical analysis.Therefore, object identification and judge module 100 can be specifically conventional pattern recognition devices, and it is equipped with camera or camera to analyze to carry out image pickup to the interior space and to detect.For above-mentioned pneumatic type object, its refer to can because of wind-force effect the object of activity; It can thus be appreciated that animal and human's body is not obviously the object of activity because of wind-force effect, for the mobiles in the interior space, wind-force effect can be followed and the object of activity is generally curtain, plant leaf and ornament (as windbell) etc.

Activity factor judge module 200 judges that process that whether activity of this pneumatic type object caused by wind-force specifically: judge whether the activity of pneumatic type object exists based on existing image recognition technology and tangible execute main body, tangible execute main body if existed, then show that the activity of pneumatic type object causes by executing main body institute externally applied forces; If there is no tangiblely execute main body, then show that the activity of pneumatic type object is caused by wind-force.Therefore, activity factor judge module 200 also can be specifically conventional pattern recognition device, it is equipped with camera or camera to carry out image pickup and detection to the interior space, thus after pickup to the image of the interior space, can judge whether the activity of pneumatic type object is caused by wind-force according to image.

Further, as shown in Figure 7, air conditioner operation parameters adjusting module 300 can comprise:

Moving position acquiring unit 301, for obtaining the moving ends position that pneumatic type object arrives because of wind-force effect;

Activity direction acquiring unit 302, for the activity direction of the pneumatic type object of moving ends position acquisition obtained according to the resting position of pneumatic type object obtained in advance and moving position acquiring unit 301;

Wind-force source determining unit 303, for determining the windward orientation of this resting position, and using the source orientation of this windward orientation as wind-force according to the resting position of pneumatic type object obtained in advance and the activity direction of pneumatic type object;

Air-conditioning wind direction adjustment unit 304, blows to the orientation, source of wind-force to make air-conditioner for the air-out direction adjusting air-conditioner.

It should be noted that, moving position acquiring unit 301, activity direction acquiring unit 302 and wind-force source determining unit 303 is in fact all realize corresponding function based on existing image recognition technology herein.Wherein, moving position acquiring unit 301 can be specifically conventional pattern recognition device, and it is equipped with camera or camera to carry out image pickup to the interior space, and obtains the moving ends position of pneumatic type object according to picked up image; Activity direction acquiring unit 302 and wind-force source determining unit 303 are then that analysiss acquisition is carried out in windward orientation when being in static to the activity direction of pneumatic type object and pneumatic type object respectively based on existing image recognition algorithm.

Further, as shown in Figure 8, air conditioner operation parameters adjusting module 300 also can comprise:

Moving position acquiring unit 311, for obtaining the moving ends position that pneumatic type object arrives because of wind-force effect;

Movable amplitude acquiring unit 312, for the movable amplitude of the pneumatic type object of moving ends position acquisition obtained according to the resting position of pneumatic type object obtained in advance and moving position acquiring unit 311;

Air conditioning exhausting parameter adjustment unit 313, for leaving air temp and/or the wind speed of the movable amplitude adjustment air-conditioner according to pneumatic type object.

Wherein, moving position acquiring unit 311 is identical with the moving position acquiring unit 301 shown in Fig. 7, therefore repeats no more; And for movable amplitude acquiring unit 312, it is based on existing image recognition algorithm, calculate the displacement size that pneumatic type object produces because of wind-force effect according to the resting position of pneumatic type object and movable emphasis position, then the displacement of pneumatic type object is exactly its movable amplitude.

Further, as shown in Figure 9, air conditioner operation parameters adjusting module 300 also can comprise:

Moving position acquiring unit 321, for obtaining the moving ends position that pneumatic type object arrives because of wind-force effect;

Movement parameter acquiring unit 322, for activity direction and the movable amplitude of pneumatic type object described in the moving ends position acquisition that obtains according to the resting position of pneumatic type object obtained in advance and moving position acquiring unit 321;

Wind-force source determining unit 323, for determining the windward orientation of this resting position, and using the source orientation of this windward orientation as wind-force according to the resting position of pneumatic type object obtained in advance and the activity direction of pneumatic type object;

Air conditioner operation parameters adjustment unit 324, blows to the orientation, source of wind-force to make air-conditioner for the air-out direction adjusting air-conditioner, and adjusts leaving air temp and/or the wind speed of air-conditioner according to the movable amplitude of pneumatic type object.

Wherein, moving position acquiring unit 311 shown in moving position acquiring unit 321 with the moving position acquiring unit 301 shown in Fig. 7 and Fig. 8 is identical, movement parameter acquiring unit 322 is the combination of movable amplitude acquiring unit 312 shown in the activity direction acquiring unit 302 shown in Fig. 7 and Fig. 8, wind-force source determining unit 323 is identical with the determining unit 303 of originating of the wind-force shown in Fig. 7, air conditioner operation parameters adjustment unit 324 is the combination of the air-conditioning wind direction adjustment unit 304 shown in Fig. 7 and the air conditioning exhausting parameter adjustment unit 313 shown in Fig. 8, so moving position acquiring unit 321, movement parameter acquiring unit 322, wind-force source determining unit 323 and air conditioner operation parameters adjustment unit 324 obtain detailed description all in foregoing, therefore repeat no more.In addition, for air conditioner operation parameters adjustment unit 324, it mainly utilizes existing air flowing in the interior space, both controlled air-conditioner to blow to the orientation, source of wind-force, and the simultaneously leaving air temp of adjustable air-conditioner and/or wind speed, thus the refrigerating/heating speed to the interior space can be accelerated further.

In addition, as shown in Figure 10, air-conditioner operation control system also comprises mobiles identification module 400, and it for carrying out active state analysis to the object in the interior space, and identifies mobiles and stationary object.

Wherein, mobiles identification module 500 is actually and carries out dynamic monitoring based on existing image recognition technology to the object in the interior space, is mobiles by the object identification being subjected to displacement change, is stationary object by the object identification not being subjected to displacement change.Therefore, mobiles identification module 500 can be conventional pattern recognition device, and it is equipped with camera or camera to carry out image pickup to the interior space, and carries out discriminance analysis according to picked up image to the mobiles in the interior space and stationary object.

In sum, in above-mentioned air-conditioner operation control system, object type identification is carried out by each mobiles in object identification and judge module 100 pairs of interior spaces, and judge in each mobiles, whether to there is pneumatic type object, if there is pneumatic type object in each mobiles, then continued to judge whether the activity of pneumatic type object is caused by wind-force by activity factor judge module 200, when judge the activity of pneumatic type object be caused by wind-force time, adjusted accordingly by the operational factor of active state to air-conditioner of air conditioner operation parameters adjusting module 300 according to this pneumatic type object, and then make air-conditioner have air that wind-force the causes cold wind/hot blast exported by air-conditioner that flows by indoor to drive, thus the refrigerating/heating speed can accelerated the interior space, accelerate the heat exchange efficiency of the interior space and reduce the power consumption of air-conditioner.

In view of the control that the running status of above-mentioned air-conditioner operation control system to air-conditioner realizes, the embodiment of the present invention additionally provides a kind of air-conditioner comprising above-mentioned air-conditioner operation control system.

The foregoing is only preferred embodiment of the present invention, not in order to limit the present invention, all any amendments done within the spirit and principles in the present invention, equivalent replacement and improvement etc., all should be included within protection scope of the present invention.

Claims (11)

1. an air-conditioner progress control method, is characterized in that, described air-conditioner progress control method comprises the following steps:

Object type identification is carried out to each mobiles in the interior space, and judges whether there is pneumatic type object in each mobiles described;

If there is pneumatic type object in each mobiles described, then judge whether the activity of described pneumatic type object is caused by wind-force; When the activity of described pneumatic type object be caused by wind-force time, the operational factor of active state to air-conditioner according to described pneumatic type object adjusts accordingly.

2. air-conditioner progress control method as claimed in claim 1, it is characterized in that, described, object type identification is carried out to each mobiles in the interior space, and comprises the following steps before judging whether there is the step of pneumatic type object in each mobiles described:

Active state analysis is carried out to the object in the interior space, and identifies mobiles and stationary object.

3. air-conditioner progress control method as claimed in claim 1, it is characterized in that, the described step adjusted according to the operational factor of active state to air-conditioner of described pneumatic type object comprises the following steps:

Obtain the moving ends position that pneumatic type object arrives because of wind-force effect; The activity direction of pneumatic type object according to the resting position of the described pneumatic type object obtained in advance and described moving ends position acquisition;

The windward orientation of described resting position is determined according to described resting position and described activity direction, and using the source orientation of described windward orientation as wind-force;

The air-out direction of adjustment air-conditioner is blown to orientation, described source to make described air-conditioner.

4. air-conditioner progress control method as claimed in claim 1, it is characterized in that, the described step adjusted according to the operational factor of active state to air-conditioner of described pneumatic type object comprises the following steps:

Obtain the moving ends position that pneumatic type object arrives because of wind-force effect;

The movable amplitude of pneumatic type object according to the resting position of the described pneumatic type object obtained in advance and described moving ends position acquisition;

According to leaving air temp and/or the wind speed of described movable amplitude adjustment air-conditioner.

5. air-conditioner progress control method as claimed in claim 1, it is characterized in that, the described step adjusted according to the operational factor of active state to air-conditioner of described pneumatic type object comprises the following steps:

Obtain the moving ends position that pneumatic type object arrives because of wind-force effect;

The activity direction of pneumatic type object and movable amplitude according to the resting position of the described pneumatic type object obtained in advance and described moving ends position acquisition;

The windward orientation of described resting position is determined according to described resting position and described activity direction, and using the source orientation of described windward orientation as wind-force;

The air-out direction of adjustment air-conditioner is blown to orientation, described source to make described air-conditioner, and adjusts leaving air temp and/or the wind speed of air-conditioner according to described movable amplitude.

6. an air-conditioner operation control system, is characterized in that, described air-conditioner operation control system comprises:

Object identification and judge module, for carrying out object type identification to each mobiles in the interior space, and judge whether there is pneumatic type object in each mobiles described;

Activity factor judge module, if for there is pneumatic type object in each mobiles described, then judges whether the activity of described pneumatic type object is caused by wind-force;

Air conditioner operation parameters adjusting module, for when the activity of described pneumatic type object be caused by wind-force time, the operational factor of active state to air-conditioner according to described pneumatic type object adjusts accordingly.

7. air-conditioner operation control system as claimed in claim 6, it is characterized in that, described air conditioner air-out direction control system also comprises mobiles identification module, described mobiles identification module is used for carrying out active state analysis to the object in the interior space, and identifies mobiles and stationary object.

8. air-conditioner operation control system as claimed in claim 6, it is characterized in that, described air conditioner operation parameters adjusting module comprises:

Moving position acquiring unit, for obtaining the moving ends position that pneumatic type object arrives because of wind-force effect;

Activity direction acquiring unit, for the activity direction of pneumatic type object according to the resting position of described pneumatic type object obtained in advance and described moving ends position acquisition;

Wind-force source determining unit, for determining the windward orientation of described resting position, and using the source orientation of described windward orientation as wind-force according to described resting position and described activity direction;

Air-conditioning wind direction adjustment unit, blows to orientation, described source to make described air-conditioner for the air-out direction adjusting air-conditioner.

9. air-conditioner operation control system as claimed in claim 6, it is characterized in that, described air conditioner operation parameters adjusting module comprises:

Moving position acquiring unit, for obtaining the moving ends position that pneumatic type object arrives because of wind-force effect;

Movable amplitude acquiring unit, for the movable amplitude of pneumatic type object according to the resting position of described pneumatic type object obtained in advance and described moving ends position acquisition;

Air conditioning exhausting parameter adjustment unit, for adjusting leaving air temp and/or the wind speed of air-conditioner according to described movable amplitude.

10. air-conditioner operation control system as claimed in claim 6, it is characterized in that, described air conditioner operation parameters adjusting module comprises:

Moving position acquiring unit, for obtaining the moving ends position that pneumatic type object arrives because of wind-force effect;

Movement parameter acquiring unit, for activity direction and the movable amplitude of pneumatic type object according to the resting position of described pneumatic type object obtained in advance and described moving ends position acquisition;

Wind-force source determining unit, for determining the windward orientation of described resting position, and using the source orientation of described windward orientation as wind-force according to described resting position and described activity direction;

Air conditioner operation parameters adjustment unit, blows to orientation, described source to make described air-conditioner for the air-out direction adjusting air-conditioner, and adjusts leaving air temp and/or the wind speed of air-conditioner according to described movable amplitude.

11. 1 kinds of air-conditioners, is characterized in that, described air-conditioner comprises the air-conditioner operation control system as described in any one of claim 6 to 10.