CN115095971B - Air conditioner installation simulator, control method thereof and readable storage medium - Google Patents

Abstract

The invention provides an air conditioner installation simulator, a control method thereof, and a readable storage medium. The simulator includes: a laser light, which is used to simulate the air outlet direction of the air conditioner to be installed; a shading plate; a control device, which controls the rotation of the shading plate, so that the shading plate and the laser light can cooperate to simulate the air outlet of the air conditioner to be installed scope. The problem solved by the present invention is that the technical solutions in the related art cannot accurately locate the best installation position of the air conditioner.

Description

An air conditioner installation simulator, its control method, and a readable storage medium

technical field

The invention relates to the technical field of air conditioners, in particular to an air conditioner installation simulator, a control method thereof, and a readable storage medium.

Background technique

In the prior art, the installation of the air conditioner mainly relies on the installer to install the air conditioner at the installation location reserved by the user. Because there is no support from professional on-site environmental test data, or the installers have not received professional training, they cannot install the air conditioner to the best position. The best indoor location prevents users from getting the best cooling and heating effects. Since the air conditioner needs to be drilled for installation, once the installation is completed, it is difficult to change the location of the air conditioner, and the perforation of the wall affects the appearance.

It can be seen that the problem in the related art is that the technical solution in the related art cannot accurately locate the best installation position of the air conditioner.

Contents of the invention

The problem solved by the present invention is that the technical solutions in the related art cannot accurately locate the best installation position of the air conditioner.

To solve the above problems, the first object of the present invention is to provide an air conditioner installation simulator.

A second object of the present invention is to provide a control method for an air conditioner installation simulator.

The third object of the present invention is to provide a readable storage medium.

In order to realize the first object of the present invention, the embodiment of the present invention provides a kind of air conditioner installation simulator, and the simulator comprises: laser lamp, and laser lamp is used for simulating the air outlet direction of the air conditioner to be installed; Shade plate; Control device , the control device controls the rotation of the shading plate, so that the shading plate cooperates with the laser light to simulate the air outlet range of the air conditioner to be installed.

Compared with the existing technology, the technical effect achieved by adopting this technical solution: the solution of this embodiment uses laser light to simulate the air outlet direction of the air conditioner to be installed, and predicts the direct blowing range of the air conditioner in advance through direct laser irradiation, which can Help installers to intuitively and accurately determine the best installation position of the air conditioner, making the installation position of the air conditioner more standardized and professional, and the air conditioner installed in the best installation position can also make users more comfortable and effectively improve the use of users experience.

In one embodiment of the present invention, the laser light includes: a first laser light, which is used to simulate the air outlet direction in the cooling mode; a second laser light, which is used to simulate the wind direction in the heating mode; Wind outlet direction; wherein, the colors of the first laser light and the second laser light are different.

Compared with the existing technology, the technical effect achieved by adopting this technical solution: the laser light includes two colors, which is convenient for the installer to observe the air outlet range of the simulator in different modes more intuitively when installing the simulator, and then The best installation position of the simulator, that is, the best installation position of the air conditioner to be installed, can be judged more accurately.

In one embodiment of the present invention, the simulator includes: a signal receiving device, which is communicatively connected with the control device and used to receive a signal from the client.

Compared with the existing technology, the technical effect achieved by adopting this technical solution is that the signal receiving device can facilitate the installer to set the model of the air conditioner to be installed for the simulator, and facilitate the installer to control the simulator to switch between different modes. The solution of this embodiment effectively simplifies the installation personnel's operation and improves the installation efficiency.

In one embodiment of the present invention, the control device includes: a controller; a stepping motor, the stepping motor is connected with the shading plate, the stepping motor is connected with the controller in communication, and the controller controls the stepping motor to drive the shading plate to rotate.

Compared with the prior art, the technical effect achieved by adopting this technical solution: the solution of this embodiment uses a stepping motor to control the rotation of the shading plate, the control performance of the stepping motor is better, and its step distance value is free from various interferences Factors, and its error will not accumulate for a long time, can accurately control the corresponding angle of the shading plate rotation, so that the simulator can realize the simulation of different modes of the air conditioner to be installed.

In one embodiment of the present invention, the simulator includes a housing, one end of the shading plate is connected with the stepper motor 400 , and the opposite end of the shading plate is connected with the housing roller.

Compared with the prior art, the technical effect achieved by adopting this technical solution: the solution of this embodiment only uses one stepper motor 400 to realize the rotation control of the shading plate, which effectively reduces the weight of the simulator and realizes The lightweight design of the simulator enables the installer to install, remove or replace the simulator more quickly and conveniently, thereby effectively improving the installation efficiency of the air conditioner to be installed.

In order to achieve the second purpose of the present invention, an embodiment of the present invention provides a control method for an air conditioner installation simulator, the control method is used to control the simulator as in any embodiment of the present invention, and the control method includes: receiver type Parameter signal, according to the model parameter signal, determine the model parameter of the air conditioner to be installed; receive the remote control signal, determine the control command according to the remote control signal; control the rotation of the shading plate according to the model parameter and control command, so that the shading plate and the laser light Cooperate with simulating the air outlet range of the air conditioner to be installed.

Compared with the prior art, the technical effect achieved by adopting this technical solution: the solution of this embodiment first determines information such as the model parameters of the air conditioner to be installed to be simulated by the simulator, and then installs the simulator to a preliminary position, controls The simulator runs to simulate the sweeping range of the air conditioner to be installed. The laser range is the sweeping range of the air conditioner to be installed. The installer adjusts the installation position of the simulator according to the sweeping range until the best installation position is determined. The solution of this embodiment can help the installer quickly and accurately obtain the best installation position, thereby improving the user experience.

In one embodiment of the present invention, the receiver type parameter signal determines the model parameter of the air conditioner to be installed according to the model parameter signal, including: receiving the type parameter signal and identifying the model parameter of the air conditioner to be installed ; Determine whether the parameter of the model to be confirmed is correct; if it is judged to be yes, determine that the parameter of the model to be confirmed is the model parameter.

Compared with the existing technology, the technical effect achieved by adopting this technical solution: In the solution of this embodiment, the simulator will perform identification and judgment after receiving the model parameter signal, and will not start until the model parameter is confirmed to be correct. The next step of control will be carried out, which effectively increases the accuracy and work efficiency of the controller in the simulator, and reduces the possibility of errors during the simulator operation.

In one embodiment of the present invention, receiving the remote control signal, and determining the control command according to the remote control signal, includes: receiving the remote control signal, identifying the control command to be confirmed; judging whether the control command to be confirmed matches the model parameters; if it is judged to be yes, Then it is determined that the control instruction to be confirmed is a control instruction.

Compared with the prior art, the technical effect achieved by adopting this technical solution: in the solution of this embodiment, after identifying and obtaining the control command to be confirmed, the accuracy of the control command to be confirmed will be further judged, avoiding The installer made a mistake in the process of inputting the parameters of the model, and the simulator directly began to control the shading plate after receiving the remote control signal, which led to the inconsistency between the rotation angle of the shading plate and the actual rotation angle of the air conditioner to be installed. The solution of this embodiment can effectively increase the accuracy of the simulator running process, and effectively increase the reliability of the simulation result of the optimal installation position.

In one embodiment of the present invention, the laser light includes a first laser light and a second laser light, and the shading plate is controlled to rotate according to model parameters and control instructions, so that the shading plate and the laser light cooperate to simulate the air outlet of the air conditioner to be installed. The range includes: determining the model of the air conditioner to be installed and the swing angle under different operating modes according to the model parameters; determining whether the operating mode of the simulator is cooling mode or heating mode according to the control instructions; In the cooling mode, the controller controls the rotation of the shading plate so that the shading plate cooperates with the first laser light to simulate the air outlet range of the air conditioner to be installed; in the heating mode, the controller controls the rotation of the shading plate so that the shading plate and the first laser light The second laser light cooperates to simulate the air outlet range of the air conditioner to be installed.

Compared with the existing technology, the technical effect achieved by adopting this technical solution: the solution of this embodiment uses laser lights of different colors to distinguish different operating modes of the air conditioner, enabling installers to intuitively and accurately observe the different operating modes of the air conditioner. The air blowing range in the air conditioner mode can determine the best installation location more quickly, making the installation location of the air conditioner more standardized and professional, improving the user experience and simplifying the installation process.

In order to achieve the third purpose of the present invention, an embodiment of the present invention provides a readable storage medium, on which a program or instruction is stored, and when the program or instruction is executed by a processor, it can realize the process as described in any embodiment of the present invention. The steps of the control method.

The readable storage medium in the embodiment of the present invention implements the steps of the control method in any embodiment of the present invention, and thus has all the beneficial effects of the control method in any embodiment of the present invention, which will not be repeated here.

Description of drawings

Fig. 1 is the structural representation of the simulator of some embodiments of the present invention;

Fig. 2 is one of the flow charts of the control method of the air conditioner installation simulator in some embodiments of the present invention;

Fig. 3 is the second flow chart of the control method of the air conditioner installation simulator in some embodiments of the present invention.

Explanation of reference signs:

100-simulator; 200-laser light; 210-first laser light; 220-second laser light; 300-shading plate; 500-control device; 510-controller; 520-stepper motor; ;700-housing.

Detailed ways

In order to make the above objects, features and advantages of the present invention more comprehensible, specific embodiments of the present invention will be described in detail below in conjunction with the accompanying drawings.

【The first embodiment】

Referring to Fig. 1, the present embodiment provides an air conditioner installation simulator, the simulator 100 includes: a laser light 200, the laser light 200 is used to simulate the air outlet direction of the air conditioner to be installed; a shading plate 300; a control device 500, a control device 500 controls the rotation of the shading plate 300 so that the shading plate 300 cooperates with the laser light 200 to simulate the air outlet range of the air conditioner to be installed.

In this embodiment, the simulator 100 includes a laser lamp 200 , a light shield 300 and a control device 500 . The appearance of the simulator 100 is similar to that of the real machine, but the weight is much lighter than that of the real machine.

In actual use, the laser light 200 is installed inside the simulator 100, and the control device 500 controls the rotation of the shading plate 300, so that the laser light emitted by the laser light 200 is irradiated on the floor or wall of the room after being blocked by the shading plate 300. Simulate the cooling or heating blowing range of the air conditioner. When the blowing range of the air conditioner is not suitable, adjust the position of the simulator 100 and repeat the above operations until the best position of the air conditioner is determined. At this time, the installation position of the simulator 100 is The best place to install the air conditioner.

It can be understood that the solution of this embodiment uses the laser light 200 to simulate the air outlet direction of the air conditioner to be installed, and predicts the direct blowing range of the air conditioner in advance through direct laser irradiation, which can help installers intuitively and accurately determine the best air conditioner. The installation position makes the installation position of the air conditioner more standardized and professional, and the air conditioner installed in the best installation position can also make the user more comfortable and effectively improve the user experience.

【Second Embodiment】

Referring to Fig. 1, in a specific embodiment, the laser lamp 200 includes: a first laser lamp 210, the first laser lamp 210 is used to simulate the air outlet direction in cooling mode; a second laser lamp 220, the second laser lamp 220 It is used to simulate the air outlet direction in heating mode; wherein, the colors of the first laser light 210 and the second laser light 220 are different.

In this embodiment, the laser lamp 200 includes a first laser lamp 210 and a second laser lamp 220 , and the colors of the first laser lamp 210 and the second laser lamp 220 are different.

Preferably, the color of the first laser light 210 is blue, and the first laser light 210 is used to simulate the air outlet direction in cooling mode.

Preferably, the color of the second laser light 220 is red, and the second laser light 220 is used to simulate the air outlet direction in the heating mode.

It can be understood that the laser light 200 includes two colors so that the installer can more intuitively observe the air outlet range of the simulator 100 in different modes when installing the simulator 100, and thus can more accurately judge the maximum range of the simulator 100. The best installation position is the best installation position of the air conditioner to be installed.

[Third embodiment]

Referring to FIG. 1 , in a specific embodiment, the simulator 100 includes: a signal receiving device 600 , which is communicatively connected with the control device 500 and configured to receive a signal from a client.

In this embodiment, the simulator 100 includes a signal receiving device 600, which is communicatively connected with the control device 500, and the signal receiving device 600 can receive infrared signals or electromagnetic wave signals.

It should be noted that the client may be the mobile phone of the user, or the remote controller of the air conditioner to be installed. The user can send electromagnetic waves or infrared signals to the simulator 100 through the mobile phone software, so that the simulator 100 can obtain information such as the model parameters of the air conditioner to be installed, that is, the model information of the air conditioner to be installed and the swing angle in different modes, etc. information; the user can send an infrared signal to the simulator 100 through the remote controller of the air conditioner to be installed, so that the simulator 100 starts simulating the swing state of the air conditioner to be installed in different modes, so that the installer can judge the status of the simulator 100. Whether the installation location is suitable.

Understandably, the signal receiving device 600 can facilitate the installer to set the model of the air conditioner to be installed for the simulator 100 , and facilitate the installer to control the simulator 100 to switch between different modes. The solution of this embodiment effectively simplifies the installation personnel's operation and improves the installation efficiency.

[Fourth Embodiment]

Referring to Fig. 1, in a specific embodiment, the control device 500 includes: a controller 510; a stepper motor 520, the stepper motor 520 is connected with the light shield 300, the stepper motor 520 is connected with the controller 510 in communication, and the controller 510 controls the stepper motor 520 to drive the visor 300 to rotate.

It can be understood that the solution of this embodiment uses the stepping motor 520 to control the rotation of the visor 300. The stepping motor 520 has better control performance, and its step distance value is not affected by various interference factors, and its error will not last for a long time. Cumulatively, it is possible to accurately control the rotation angle of the visor 300 so that the simulator 100 can simulate different modes of the air conditioner to be installed.

[fifth embodiment]

Referring to FIG. 1 , in a specific embodiment, the simulator 100 includes a casing 700 , one end of the shading plate 300 is mated with the stepper motor 400 , and the opposite end of the shading plate 300 is connected to the casing 700 by a roller.

In this embodiment, the simulator 100 includes a casing 700 , and the visor 300 includes two opposite ends, one end is connected with the stepper motor 400 , and the other end is connected with the casing 700 through a roller.

It can be understood that the solution of this embodiment can realize the rotation control of the visor 300 by using only one stepping motor 400, which effectively reduces the weight of the simulator 100, realizes the lightweight design of the simulator 100, and further makes the installation It is faster and more convenient for personnel to install, remove or replace the position of the simulator 100, thereby effectively improving the installation efficiency of the air conditioner to be installed.

[Sixth embodiment]

Referring to Fig. 2, the present embodiment provides a control method for an air conditioner installation simulator, the control method is used to control the simulator as in any embodiment of the present invention, and the control method includes:

S100: Receive the model parameter signal, and determine the model parameter of the air conditioner to be installed according to the model parameter signal;

S200: receiving a remote control signal, and determining a control instruction according to the remote control signal;

S300: Control the rotation of the shading plate according to the model parameters and control instructions, so that the shading plate and the laser light can cooperate to simulate the air outlet range of the air conditioner to be installed.

Further, in S100, the signal receiving device receives the model parameter signal sent from the client software, and the controller determines the model parameter of the air conditioner to be installed according to the model parameter signal. Wherein, the model parameter includes information such as model information of the air conditioner to be installed and its up and down wind angles in each mode.

Further, in S200, the signal receiving device receives a remote control signal from a remote controller of the air conditioner to be installed, and the controller determines a corresponding control instruction according to the remote control signal. Wherein, the control instruction includes controlling the simulator to switch to different operating modes.

Further, in S300, the controller controls the shading plate to rotate according to the model parameters and control instructions, so that the shading plate cooperates with the laser light to simulate the air outlet range of the air conditioner to be installed in different operating modes.

Understandably, the solution of this embodiment first determines information such as the model parameters of the air conditioner to be installed to be simulated by the simulator, and then installs the simulator to a preliminary position, controls the simulator to run and simulate the sweeping range of the air conditioner to be installed, The laser range is the sweeping range of the air conditioner to be installed. The installer adjusts the installation position of the simulator according to the sweeping range until the best installation position is determined. The solution of this embodiment can help the installer quickly and accurately obtain the best installation position, thereby improving the user experience.

[Seventh embodiment]

In a specific embodiment, the receiver type parameter signal determines the type parameter of the air conditioner to be installed according to the type parameter signal, including:

S110: Receive the type parameter signal, and identify the type parameters to be confirmed of the air conditioner to be installed;

S120: judging whether the parameters of the model to be confirmed are correct;

S130: If the judgment is yes, determine that the model parameter to be confirmed is the model parameter.

Further, in S110, the signal receiving device receives the model parameter signal sent from the client software, the controller identifies the model parameter signal, and obtains the model parameter of the air conditioner to be installed to be confirmed.

Further, in S120, the controller judges whether the parameters of the model to be confirmed are correct. A database of air conditioner model parameters is stored in the controller, and the model parameters to be confirmed are compared with the data in the database for judgment.

Further, in S130, if the model parameter to be confirmed is correct, determine that the model parameter to be confirmed is the model parameter.

It can be understood that in the solution of this embodiment, the simulator will perform identification and judgment after receiving the model parameter signal, and will not proceed to the next step of control until the model parameter is confirmed to be correct, effectively increasing the number of simulators. The accuracy and work efficiency of the internal controller operation process reduce the possibility of errors during the operation of the simulator.

[eighth embodiment]

In a specific embodiment, the remote control signal is received, and the control instruction is determined according to the remote control signal, including:

S210: receiving a remote control signal, and identifying a control command to be confirmed;

S220: judging whether the control instruction to be confirmed matches the model parameter;

S230: If the judgment is yes, determine that the control instruction to be confirmed is a control instruction.

Further, in S210, the signal receiving device receives the remote control signal from the remote controller of the air conditioner to be installed, and the controller identifies and acquires the control instruction to be confirmed.

Further, in S220, the controller can identify the model of the air conditioner to which the control command to be confirmed belongs through the control command to be confirmed, and the controller judges whether the control command to be confirmed matches the model parameter confirmed in S100.

Further, in S230, if the control instruction to be confirmed matches the model parameter, it is determined that the control instruction to be confirmed is the control instruction.

It can be understood that in the solution of this embodiment, after identifying and obtaining the control command to be confirmed, the accuracy of the control command to be confirmed will be further judged, so as to avoid the installation personnel inputting model parameters in S100. An error occurs, and the simulator directly starts to control the shading plate after receiving the remote control signal, which leads to the inconsistency between the rotation angle of the shading plate and the actual rotation angle of the air conditioner to be installed. The solution of this embodiment can effectively increase the accuracy of the simulator running process, and effectively increase the reliability of the simulation result of the optimal installation position.

[Ninth Embodiment]

Referring to Fig. 3, in a specific embodiment, the laser light includes a first laser light and a second laser light, and controls the rotation of the shading plate according to the model parameters and control instructions, so that the light shading plate and the laser light cooperate to simulate the air conditioner to be installed The wind range, including:

S310: Determine the model of the air conditioner to be installed and the swing angle under different operating modes according to the model parameters;

S320: Determine according to the control instruction that the operating mode of the simulator is one of cooling mode or heating mode;

S330: when it is in cooling mode, the controller controls the rotation of the shading plate, so that the shading plate cooperates with the first laser light to simulate the air outlet range of the air conditioner to be installed;

S340: When in the heating mode, the controller controls the shading plate to rotate, so that the shading plate cooperates with the second laser light to simulate the air outlet range of the air conditioner to be installed.

In this embodiment, the rotation angle of the shading plate is consistent with the actual opening angle of the air guide door of the air conditioner to be installed, and the range of laser irradiation is the actual blowing range of the air conditioner to be installed.

It should be noted that the opening angles of the air guide doors in cooling mode and heating mode are inconsistent, and laser lights of different colors can help installers more intuitively observe the range of blowing in different modes.

It can be understood that the solution of this embodiment uses laser lights of different colors to distinguish different operating modes of the air conditioner, enabling the installer to intuitively and accurately observe the air blowing range of the air conditioner in different modes, and then to determine the optimum operating mode more quickly. The optimal installation position makes the installation position of the air conditioner more standardized and professional, improves the user experience and simplifies the installation process.

[Tenth Embodiment]

This embodiment provides a readable storage medium, on which a program or instruction is stored, and when the program or instruction is executed by a processor, the steps of the control method according to any embodiment of the present invention are implemented.

The readable storage medium in the embodiment of the present invention implements the steps of the control method in any embodiment of the present invention, and thus has all the beneficial effects of the control method in any embodiment of the present invention, which will not be repeated here.

Although the present invention is disclosed above, the present invention is not limited thereto. Any person skilled in the art can make various changes and modifications without departing from the spirit and scope of the present invention, so the protection scope of the present invention should be based on the scope defined in the claims.

Claims (8)

1. An air conditioner installation simulator, characterized in that the simulator (100) comprises:

the laser lamp (200) is used for simulating the air outlet direction of the air conditioner to be installed;

a light shielding plate (300);

the control device (500) is used for controlling the light shielding plate (300) to rotate, so that the light shielding plate (300) and the laser lamp (200) are matched to simulate the air outlet range of the air conditioner to be installed;

the laser lamp (200) includes:

the first laser lamp (210), the said first laser lamp (210) is used for simulating the direction of wind-out under the refrigeration mode;

the second laser lamp (220) is used for simulating the air outlet direction in the heating mode;

wherein the first laser lamp (210) and the second laser lamp (220) are different in color;

the simulator (100) may implement a control method of an air conditioner installation simulator, the control method including:

receiving model parameter signals, and determining model parameters of an air conditioner to be installed according to the model parameter signals;

receiving a remote control signal, and determining a control instruction according to the remote control signal;

according to the model parameters and the control instructions, the light shielding plate is controlled to rotate, so that the light shielding plate and the laser lamp are matched to simulate the air outlet range of the air conditioner to be installed;

the laser lamp includes first laser lamp and second laser lamp, according to the model parameter with control command control light screen rotates, so that the light screen with the laser lamp cooperation simulation wait to install the air-out scope of air conditioner, include:

determining the model of the air conditioner to be installed and the wind swinging angles under different operation modes according to the model parameters;

determining that the operation mode of the simulator is one of a refrigeration mode and a heating mode according to the control instruction;

when the air conditioner is in a refrigerating mode, the controller controls the light shielding plate to rotate, so that the light shielding plate and the first laser lamp are matched to simulate the air outlet range of the air conditioner to be installed;

and when the air conditioner is in a heating mode, the controller controls the light shielding plate to rotate, so that the light shielding plate and the second laser lamp are matched to simulate the air outlet range of the air conditioner to be installed.

2. The simulator (100) according to claim 1, wherein the simulator (100) comprises:

and a signal receiving device (600), wherein the signal receiving device (600) is in communication connection with the control device (500) and is used for receiving signals from a client.

3. The simulation machine (100) according to any of the claims 1 to 2, wherein the control device (500) comprises:

a controller (510);

the stepping motor (520), step motor (520) with light screen (300) cooperation is connected, step motor (520) with controller (510) communication connection, controller (510) control step motor (520) drive light screen (300) rotate.

4. A simulation machine (100) according to claim 3, wherein the simulation machine (100) comprises a housing (700), one end of the light shielding plate (300) is cooperatively connected with the stepper motor (520), and the opposite end of the light shielding plate (300) is connected with a roller of the housing (700).

5. A control method of an air conditioner installation simulator, the control method being for controlling an air conditioner installation simulator, the simulator (100) comprising:

the laser lamp (200) is used for simulating the air outlet direction of the air conditioner to be installed;

a light shielding plate (300);

the control device (500) is used for controlling the light shielding plate (300) to rotate, so that the light shielding plate (300) and the laser lamp (200) are matched to simulate the air outlet range of the air conditioner to be installed;

the laser lamp (200) includes:

the first laser lamp (210), the said first laser lamp (210) is used for simulating the direction of wind-out under the refrigeration mode;

the second laser lamp (220) is used for simulating the air outlet direction in the heating mode;

wherein the first laser lamp (210) and the second laser lamp (220) are different in color;

the control method comprises the following steps:

receiving model parameter signals, and determining model parameters of an air conditioner to be installed according to the model parameter signals;

receiving a remote control signal, and determining a control instruction according to the remote control signal;

according to the model parameters and the control instructions, the light shielding plate is controlled to rotate, so that the light shielding plate and the laser lamp are matched to simulate the air outlet range of the air conditioner to be installed;

the laser lamp includes first laser lamp and second laser lamp, according to the model parameter with control command control light screen rotates, so that the light screen with the laser lamp cooperation simulation wait to install the air-out scope of air conditioner, include:

determining the model of the air conditioner to be installed and the wind swinging angles under different operation modes according to the model parameters;

determining that the operation mode of the simulator is one of a refrigeration mode and a heating mode according to the control instruction;

when the air conditioner is in a refrigerating mode, the controller controls the light shielding plate to rotate, so that the light shielding plate and the first laser lamp are matched to simulate the air outlet range of the air conditioner to be installed;

and when the air conditioner is in a heating mode, the controller controls the light shielding plate to rotate, so that the light shielding plate and the second laser lamp are matched to simulate the air outlet range of the air conditioner to be installed.

6. The control method according to claim 5, wherein the receiver type parameter signal, according to which the type parameter of the air conditioner to be installed is determined, includes:

receiving the model parameter signal, and identifying the model parameter to be confirmed of the air conditioner to be installed;

judging whether the model parameters to be confirmed are correct or not;

and if so, determining the model parameter to be confirmed as the model parameter.

7. The control method according to claim 5, wherein the receiving a remote control signal, determining a control instruction based on the remote control signal, comprises:

receiving the remote control signal, and identifying a control instruction to be confirmed;

judging whether the control instruction to be confirmed is matched with the model parameter;

and if so, determining the control instruction to be confirmed as the control instruction.

8. A readable storage medium, characterized in that it stores thereon a program or instructions that, when executed by a processor, implement the steps of the control method according to any one of claims 5 to 7.