JP2020510182A - Control method of air deflector of air conditioner and air conditioner - Google Patents

Abstract

A method for controlling an air deflector of an air conditioner and an air conditioner. The control method of the air deflector of the air conditioner is that each air deflector (1) is deployed after the start command is received and before each air deflector (1) of the air conditioner moves from the air conditioner outlet (2) to the preset position. The preset position is the final position in which each air deflector (1) moves outwards and downwards with respect to the outlet (2). The rotational expansion of the air deflector (1) during the start-up phase is performed before each air deflector (1) moves to the preset position, instead of being performed after the air deflector (1) moves to the preset position. It is not necessary to take additional time for the rotary expansion of the deflector (1). Therefore, the starting time is greatly reduced.

Description

  This application is based on and claims priority from Chinese Patent Application Publication No. 201710156104.5 filed on Mar. 16, 2017, and the disclosure of this Chinese patent application is as follows. The entirety of which is incorporated herein by reference.

  The present disclosure relates to the technical field of air conditioners, and more particularly, to a method for controlling an air deflector of an air conditioner and an air conditioner.

  An air outlet structure of an air conditioner generally includes an air outlet and a plurality of air deflectors arranged at the air outlet. In the prior art, during the start-up phase of an air conditioner, the air deflector is generally controlled to move outward and downward relative to the outlet to a preset position, and then the air deflector is adapted to deploy the air deflector. Rotating, this preset position is the final position where the air deflector moves outward and downward relative to the outlet.

  Since the rotation and deployment of the air deflector at the start-up stage are performed after the air deflector has moved to the preset position, the start-up time is relatively long, and the user experience deteriorates.

  According to one aspect of the present disclosure, there is provided a method of controlling an air deflector of an air conditioner and an air conditioner in order to ameliorate the problems related to the relatively long start-up time of the air conditioner in the prior art.

  In order to solve the above technical problem, a first aspect of the present disclosure is a method of controlling an air deflector of an air conditioner, wherein the air deflector of the air conditioner is preset from an air outlet of the air conditioner after a start command is received. A control method in which the air deflector rotates for deployment before moving to the position, the preset position is the final position where the air deflector moves outward and downward relative to the outlet, and the air deflector is moved outward. And the process when moving downwards partially overlaps in time with the process when the air deflector rotates for deployment.

  Alternatively, after the start command is received, the air deflector starts moving from the outlet to the preset position and the air deflector starts rotating for deployment.

  Alternatively, after the start command is received, when the air deflector (1) moves from the outlet to a non-interfering position located above the preset position, the air deflector rotates for deployment and the non-interfering The position is a position configured to prevent the top of the air deflector from interfering with the outlet during the process as the air deflector rotates for deployment.

Alternatively, after the shutdown command is received,
The air deflector starts moving from the preset position to the outlet (2) and the air deflector starts rotating for folding;
After the air deflector rotates for folding, the air deflector moves from the preset position to the outlet,
After the air deflector moves from the preset position to the outlet, the air deflector rotates for folding,
The air deflector moves in one of them.

  According to a second aspect of the present disclosure, there is provided an air conditioner including an air outlet, a plurality of air deflectors, a first power unit, and a second power unit, wherein the first power unit includes an air deflector that blows air. The second power means is configured to control to move between an outlet and a preset position outside and below the outlet, and the second power means is configured to control the air deflector to rotate for deployment or folding. An air conditioner, after the start command is received, and before the first power means starts controlling the air deflector to move from the outlet to the preset position, the second power means operates when the air deflector is deployed. The process when the air deflector moves outward and downward is the same as the process and time when the air deflector rotates for deployment. Partially overlaps, to provide air conditioning.

  Alternatively, after the start command is received, the first power means initiates movement of the air deflector from the outlet to the preset position and the second power means activates the air deflector to deploy. It is configured to start rotation.

  Alternatively, when the first power means controls the air deflector to move from the outlet to a non-interfering position located above the preset position after the start command is received, the second power means Is configured to initiate control of the air deflector to rotate for deployment, and the non-interfering position is such that the top of the air deflector interferes with the outlet in the process when the air deflector rotates for deployment. This is a position that is configured to prevent

  Alternatively, the first power means comprises a first stepper motor, the second power means comprises a second stepper motor, and after the start command is received, the first power means comprises an X step operation. After the second power means is configured to control the air deflector to rotate for deployment, and when the first power means performs the X step operation, the air deflector moves from the outlet to the non-interference position. It is configured to move.

  Alternatively, after the shutdown command has been received, the first power means and the second power means may be used to start moving the air deflector from the preset position to the outlet and to start rotating the air deflector to fold. Are configured to start operating simultaneously.

  Alternatively, after the shutdown command is received, after the second power means controls the air deflector to rotate for folding, the first power means causes the air deflector to move from the preset position to the outlet. The first power means is configured to control to move, or after the shutdown command is received, the second power means is controlled to move the air deflector from the preset position to the outlet. , Is configured to control the air deflector to rotate for folding.

  According to the control method of the air deflector of the air conditioner provided by the present disclosure, before the air deflector moves from the outlet to the preset position, the air deflector starts rotating for deployment, and the air deflector is started at the starting stage. Rotational folding does not need to be performed after the air deflector has moved to the preset position, thus significantly reducing start-up time and promoting an improved user experience.

  Other features and advantages of the present disclosure will become apparent from the following detailed description of exemplary embodiments of the present disclosure, with reference to the drawings.

  In order to more clearly illustrate the technical solutions in the embodiments of the present disclosure or the prior art, a brief description of the drawings necessary for the description of the embodiments or the prior art is given below. It is evident that the drawings in the following description are only some examples of the present disclosure, based on which other drawings can be obtained without any creative effort by those skilled in the art.

FIG. 4 is a schematic diagram of a state of an air deflector during a start-up phase according to an embodiment of the present disclosure; FIG. 5 is a schematic diagram of a state of an air deflector after a shutdown is completed according to an embodiment of the present disclosure; FIG. 4 is a control flow diagram of an air deflector during a start-up phase according to one embodiment of the present disclosure;

  A clear and complete description of the technical solutions in the embodiments of the present disclosure will be given below in combination with the drawings of the embodiments of the present disclosure. Apparently, the embodiments described below are only some but not all of the embodiments of the present disclosure. The following description of at least one example embodiment is illustrative only and is not used in any way as a limitation on the present disclosure or its application or use. All other embodiments obtained by a person of ordinary skill in the art based on the embodiments of the present disclosure without creative efforts fall within the protection scope of the present disclosure.

  Techniques, methods, and devices known to those of ordinary skill in the art may not be discussed in detail, but, where appropriate, such techniques, methods, and devices should be considered part of the authorized specification.

  In the description of this disclosure, terms such as "first" and "second" are used to define parts and components, and are only for the purpose of facilitating distinction between corresponding parts and components. It should be understood that it is used. Unless stated otherwise, the terms have no specific meaning and therefore cannot be construed as limiting the scope of protection of the present disclosure.

  In the description of the present disclosure, the directions indicated by terms indicating directions such as `` front, rear, top, bottom, left, right, '' `` horizontal, vertical, vertical, horizontal, '' and `` top, bottom '' or The positional relationship is generally based on the orientation or positional relationship when the air conditioner is normally used, and the term "inside and outside" refers to the inside and outside of each component's own outline. I want to be understood.

  1 and 2 show schematic diagrams of the state of an air deflector at a start-up phase and a shutdown phase, respectively, according to one embodiment of the present disclosure, and FIG. 3 shows a start-up phase according to one embodiment of the present disclosure. FIG. 3 shows a control flow chart of the air deflector in FIG. Referring to FIGS. 1 to 3, the method of controlling an air deflector of an air conditioner provided by the present disclosure is such that after a start command is received, the air deflector 1 of the air conditioner starts moving from the air outlet 2 of the air conditioner to a preset position. Before the air deflector 1 starts to be controlled to rotate for deployment.

  As in the prior art, in the present disclosure, the preset position also refers to the final position where the air deflector 1 moves outward and downward with respect to the outlet 2, i.e. during the start-up phase, the air deflector 1 After moving to, do not continue moving downward and outward.

  According to the present disclosure, the rotation and deployment of the air deflector 1 at the start stage need not be performed after the air deflector 1 has moved to the preset position, and is performed before the air deflector 1 moves to the preset position. The rolling deployment of the deflector 1 does not need to take any extra time, thus greatly reducing the start-up time and promoting an improved user experience.

  In the embodiment of the present disclosure, after the start command is received, control is started so that the air deflector 1 moves from the outlet 2 to the preset position, and the air deflector 1 starts rotating for deployment. In this way, the rotation and deployment of the air deflector 1 during the start-up phase is performed simultaneously with the movement of the air deflector 1, and the rotation and deployment of the air deflector 1 does not require any additional time, so that the startup time is reduced. Be shortened.

  In another embodiment of the present disclosure, after the start command is received, when the air deflector 1 starts moving from the outlet 2 to a non-interfering position located above the preset position, the air deflector 1 will To start spinning. Of course, in this case, when the air deflector 1 rotates for deployment, the air deflector will move from the non-interfering position downward and outward until it has moved to the preset position and the movement process in the starting phase is completed. To continue.

  In the present disclosure, the non-interference position is a position configured to prevent the upper portion of the air deflector 1 from interfering with the air outlet 2 in a process when the air deflector 1 rotates for deployment.

  In the above-described alternative embodiment, in the starting phase, the rotation and deployment of the air deflector 1 is started when the air deflector 1 moves to the non-interference position. On the other hand, since the rotation and deployment of the air deflector 1 is started before the air deflector 1 moves to the preset position, the movement process of the air deflector 1 partially overlaps with the rotation and deployment process of the air deflector 1 and the air deflector 1 1 does not need to take any additional time, so that the start-up time can be greatly reduced, while the rolling of the air deflector 1 is not performed simultaneously with the movement of the air deflector 1, Since the rotation is started when the air deflector 1 moves to the non-interference position, the rotation and deployment of the air deflector 1 are slightly delayed from the movement of the air deflector 1. Therefore, interference between the upper portion of the air deflector 1 and the outlet 2 in the rotation and deployment process is effectively avoided, and the rotation and deployment process of the air deflector 1 is smoothed.

Since the time taken for the air deflector 1 to rotate or to be folded is shorter than the time required for the air deflector 1 to move between the air outlet and the preset position, generally, the time between the air deflector 1 and the air outlet 2 is slightly smaller. In the shutdown phase, even if the rotation of the air deflector 1 and the movement of the air deflector 1 are performed simultaneously, the air deflector 1 is folded before interfering with the outlet 2. Therefore, no interference occurs. Therefore, in the present disclosure, in the shutdown stage, the rotational folding of the air deflector 1 and the movement of the air deflector 1 are performed simultaneously or sequentially, and the rotational folding of the air deflector 1 and the movement of the air deflector 1 are sequentially performed. In this case, the rotation folding of the air deflector 1 is executed before the movement of the air deflector 1, or the rotation folding of the air deflector 1 is executed after the movement of the air deflector 1. Based on this, in the control method provided by the present disclosure, after the shutdown command is received,
Start the control so that the air deflector 1 moves from the preset position to the air outlet 2, and start the control so that the air deflector 1 rotates for folding.
After the air deflector 1 is rotated for folding, control is started so that the air deflector 1 moves from the preset position to the air outlet 2.
After the air deflector 1 has moved from the preset position to the outlet 2, the air deflector 1 starts control to rotate for folding.
The air deflector 1 can be controlled to move in any of them.

  Alternatively, in order to reduce the shutdown time, the rotational folding of the air deflector 1 and the movement of the air deflector 1 are performed simultaneously.

  The present disclosure relates to an air conditioner including an air outlet 2, a plurality of air deflectors 1, a first power unit, and a second power unit, wherein the first power unit includes the air deflector 1 And a second power means for rotating the air deflector 1 for deployment or for folding the air deflector 1. An air conditioner configured to control the air deflector 1 to move from the air outlet 2 to the preset position after the start command has been received. A power supply further provides an air conditioner that initiates control of the air deflector 1 to rotate for deployment.

  Unlike the air conditioner of the prior art, in the air conditioner of the present disclosure, in the starting phase, the second power means for controlling the rotation of the air deflector 1 is the first power means for controlling the movement of the air deflector 1 The air deflector 1 rotates for deployment before moving to the preset position, since the operation is started before the first power means completes the operation, instead of starting the operation after the operation is completed. Start, resulting in a relatively short start-up time, relatively high start-up efficiency, and an improved user experience.

  In order to cause the second power means to start operating before the first power means completes the operation, in the air conditioner of the present disclosure, after the start command is received, the first power means causes the air deflector 1 to operate. The control starts to move from the outlet 2 to the preset position, and the second power means starts the control so that the air deflector 1 rotates for deployment, and thus the second power means and The first power means starts operating at the same time and the operation of the second power means does not need to take any extra time, so that the starting time is reduced.

  In another embodiment, when the first power means controls the air deflector 1 to move from the outlet 2 to a non-interfering position located above the preset position, the second power means also controls the air deflector 1 Starts to rotate for deployment, and the second power means operates slightly later than the first power means, so that not only the start-up time can be shortened, but also the air deflector 1 Can also be prevented from interfering with the air outlet 2, and the starting process becomes smooth. Needless to say, even after the first power unit controls the air deflector 1 to move from the outlet 2 to the non-interference position, the first power unit controls the air deflector 1 to move to the preset position, and the first power unit controls the air deflector 1 to move to the preset position. Until the operation of the first power unit is completed, the first power unit continues to control the air deflector 1 to move from the non-interference position to the preset position.

  In the above embodiment, the first power means includes a first stepper motor, and the second power means includes a second stepper motor. Further, after the start command is received, after the first power means has operated X steps (X = 1, 2, 3,...), The second power means rotates the air deflector 1 for deployment. The air deflector 1 moves from the air outlet 2 to the non-interference position when the first power unit performs the X step operation. Based on this, the second stepping motor is delayed by X steps from the first stepping motor, and the air deflector 1 is controlled to start rotating for deployment when it moves to the non-interference position in the starting phase. Is done. Therefore, the starting time is shortened and the smoothness of the starting is improved.

In addition, in the air conditioner of the present disclosure, after the shutdown command is received,
The first power means and the second power means start operating simultaneously;
After the second power means controls the air deflector 1 to rotate for folding, the first power means starts controlling the air deflector 1 to move from the preset position to the outlet 2.
After the first power unit controls the air deflector 1 to move from the preset position to the outlet 2, the second power unit starts control so that the air deflector 1 rotates for folding.
The first power means and the second power means operate according to any one of them.

  If the first power means and the second power means start operating at the same time, it starts to control the air deflector 1 to move from the preset position to the air outlet 2, and the air deflector 1 is moved for folding. Rotating folding of the air deflector 1 does not need to take any additional time, meaning that the rotation folding in the shutdown phase and the movement of the air deflector 1 are performed at the same time, meaning that it starts to be controlled to rotate. Shutdown time is significantly reduced.

  Therefore, based on the control method and the air conditioner provided by the present disclosure, the start-up time is reduced, and in experiments, the present disclosure has reduced the start-up time by 50% compared to the prior art, greatly improving the efficiency and improving the user experience. Has been shown to improve significantly.

  The above description is merely exemplary embodiments of the present disclosure, and is not intended to limit the present disclosure, and any modifications, equivalents, improvements, etc. made within the spirit and principles of the present disclosure are not intended to protect the present disclosure. Should be included in the range.

1 air deflector 2 outlet

Claims (10)

  A method of controlling an air deflector of an air conditioner, the method comprising: receiving a start command before moving the air deflector (1) from an air outlet (2) of the air conditioner to a preset position; ) Is a control method of rotating for deployment, wherein the preset position is a final position where the air deflector (1) moves outward and downward with respect to the air outlet, and the air deflector (1) is A control method, wherein the process when moving outward and downward partially overlaps the process when the air deflector (1) rotates for deployment.   After the start command is received, the air deflector (1) starts moving from the outlet (2) to the preset position and the air deflector (1) starts rotating for deployment. Item 2. The control method according to Item 1.   After the start command is received, when the air deflector (1) moves from the outlet (2) to a non-interference position located above the preset position, the air deflector (1) is deployed. And the non-interfering position prevents the upper portion of the air deflector (1) from interfering with the outlet (2) in the process when the air deflector (1) rotates for deployment. The control method according to claim 1, wherein the position is a position configured to perform the control. After the shutdown command is received,
The air deflector (1) starts moving from the preset position to the outlet (2), and the air deflector (1) starts rotating for folding;
After the air deflector (1) rotates for folding, the air deflector (1) moves from the preset position to the outlet (2);
After the air deflector (1) moves from the preset position to the outlet (2), the air deflector (1) rotates for folding;
The control method according to claim 1, wherein the air deflector (1) moves at any one of them.   An air conditioner including an air outlet (2), a plurality of air deflectors (1), a first power unit, and a second power unit, wherein the first power unit is the air deflector (1). Is controlled to move between the outlet (2) and a preset position outside and below the outlet (2), and the second power unit is configured such that the air deflector (1) is deployed. Or an air conditioner configured to be controlled to rotate for folding, wherein after a start command is received, the first power means causes the air deflector (1) to move from the outlet (2). Prior to initiating control to move to the preset position, the second power means is configured to control the air deflector (1) to rotate for deployment, wherein the air deflector (1) Outward and Process as it moves in the direction overlaps the process temporally partially when said air deflector (1) is rotated for deployment, air conditioning.   After the start command is received, the first power means starts moving the air deflector (1) from the outlet (2) to the preset position, and the second power means The air conditioner according to claim 5, wherein the air conditioner is configured to start rotation of the air deflector (1) to deploy.   After the start command is received, when the first power means controls the air deflector (1) to move from the air outlet (2) to a non-interfering position located above the preset position. , The second power means is configured to start controlling the air deflector (1) to rotate for deployment, and wherein the non-interfering position is such that the air deflector (1) rotates for deployment. 6. The air conditioner according to claim 5, wherein in the process, the top of the air deflector (1) is at a position configured to prevent interference with the air outlet (2).   The first power means comprises a first stepper motor, the second power means comprises a second stepper motor, and after the start command is received, the first power means comprises X steps (X = 1,2,3 ...) operation, the second power means is configured to control the air deflector (1) to rotate for deployment, and wherein the first power means The air conditioner according to claim 7, wherein the air deflector (1) is configured to move from the air outlet (2) to the non-interference position when performing the X step operation.   After the shutdown command is received, to start moving the air deflector (1) from the preset position to the air outlet (2) and to start rotating the air deflector (1) so as to fold. The air conditioner of claim 5, wherein the first power means and the second power means are configured to start operating simultaneously.   After the shutdown command is received, after the second power means controls the air deflector (1) to rotate for folding, the first power means causes the air deflector (1) to The first power means is configured to control to move from a preset position to the outlet (2) or after a shutdown command is received, the first power means causes the air deflector (1) to move from the preset position. The method according to claim 5, wherein after controlling to move to the outlet (2), the second power means is configured to control the air deflector (1) to rotate for folding. Air conditioning.