TWI567337B - Intelligent control module,intelligent fan light,intelligent remote controller of the fan light and intelligent fan light control method - Google Patents

Description

Intelligent control module, intelligent light fan, intelligent light fan remote control and intelligent light fan control method

The creation department is related to the control module, the lamp fan, the lamp remote controller and the lamp fan control method, and particularly relates to a smart control module, a smart lamp fan, a smart lamp fan remote controller and a smart lamp fan control method.

For a long time, the light fan has been the most common functional decoration in interior decoration. In addition to the decorative function, the lamp fan can also provide both fan function and lighting function, while at the same time having both aesthetics and practicality. Moreover, since the height of the lamp fan is much higher than that of a general electric fan (such as a ceiling installed in a home), the temperature adjustment efficiency of the lamp fan is higher than that of a general electric fan (because the top-down airflow generated by the lamp fan is not easily set to a height) Most of the lower appliances are shielded, so air circulation efficiency is better and temperature regulation efficiency is better. Due to the above advantages, the popularity of the lamp fan is getting higher and higher.

However, the conventional light fans are required to be manually turned on/off by the user, and do not have any automatic control functions, resulting in a poor user experience for the user.

Therefore, the conventional lamp fan has the above problems, and a more effective solution is proposed.

The main object of the present invention is to provide a smart control module with an automatic timing control function, a smart light fan, a smart light fan remote control and a smart light. Fan control method.

To achieve the above objective, the present invention mainly provides a smart control module, including a first transmission module connected to a lamp control module, a control signal for receiving a first lamp control signal or a timing control signal. a receiving module, a memory, a timer, and a processor electrically connected to the first transmission module, the control signal transmission module, the memory, and the timer. The processor includes a processing module and a timing control module connected to the processing module. The processing module transmits the first lamp control signal to the lamp control module via the first transmission module to adjust the brightness of an illumination device electrically connected to the lamp control module or electrically connect the lamp The speed of a fan device of the control module is controlled, or the setting data is controlled to be stored in the memory according to the timing control signal, wherein the timing control setting data includes a trigger time and a certain time control operation parameter. The timing control module generates and transmits a second lamp control signal to the lamp control module according to the timing control operation parameter to adjust the brightness of the illumination device or the fan. The speed of the device.

As described above, the smart control module further includes a network transmission module electrically connected to the processor and connected to a user device via the Internet to obtain a user location; the memory further stores a memory The pre-activation setting data includes a light fan position, a distance threshold, and a pre-starting operation parameter; the processor further includes a pre-launching module connected to the processing module, the pre-starting module When a distance between the user position and the position of the lamp is less than the threshold value, a third lamp control signal is generated and transmitted according to the pre-start operation parameter to the lamp control module to adjust the illumination device. The brightness or the speed of the fan unit.

According to the above description, the smart control module further includes a sensor electrically connected to the processor to obtain an environmental factor sensing value; the memory further stores an environmental factor target value; A difference between the environmental factor sensing value and the environmental factor target value is calculated and a fourth lamp control signal is transmitted to the lamp control module to adjust the brightness of the lighting device or the rotational speed of the fan device.

As described above, the sensor is a temperature sensor or a humidity sensor.

According to the above description, the smart control module further includes a sensor electrically connected to the processor to obtain an environmental factor sensing value; the memory further includes a database for storing the plurality of learning setting materials, wherein The plurality of learning setting data respectively correspond to an operating parameter used by the lamp control module in different environmental factor sensing values; the processor further includes a learning module connected to the processing module, according to the current The environmental factor sensing value selects one of the plurality of learning setting data, and generates and transmits a fifth lamp control signal to the lamp control module according to the selected learning setting data to adjust the brightness of the lighting device. Or the speed of the fan unit.

As described above, the smart control module further includes a network transmission module electrically connected to the processor and connected to a user device or a cloud server via the Internet; the processor further includes a statistic The module is connected to the processing module, and calculates and transmits a statistical data to the user device or the cloud server via the network transmission module.

As described above, the statistical data includes an environmental factor sensing value, an environmental factor target value, or a lamp fan power consumption value respectively recorded at a plurality of time points in a statistical time range.

As described above, the smart control module further includes a network transmission module electrically connected to the processor and connected to a cloud server via the Internet; the processor further includes a cloud backup module, and the connection The processing module, the cloud backup module generates a backup data, and transmits the backup data to the cloud server via the network transmission module to perform data backup.

As described above, the smart control module further includes a network transmission module electrically connected to the processor and connected to the Internet; the memory further stores a webpage; the processor further includes a webpage module The webpage module provides a browsing service of the webpage via the network transmission module, and receives a user operation via the webpage, and generates the first light fan control signal or the second light fan control according to the user operation. Signal.

The invention further provides a smart lamp fan, comprising the smart control module, a fan device, a lighting device and the fan device and the electrical device A lamp control module for the lighting device. The lamp control module includes a second transmission module connected to the first transmission module of the smart control module.

The invention further provides a smart lamp remote controller, comprising the smart control module as described above, and a human machine interface electrically connected to the smart control module. The human machine interface accepts a user operation and generates the first lamp control signal or the timing control signal according to the user operation.

The invention further provides a smart lamp control method, comprising: a) receiving a first lamp control signal; b) transmitting the first lamp control signal to a lamp control module to adjust the electrical connection of the lamp The brightness of a lighting device of the control module or the speed of a fan device electrically connected to the lamp control module; c) controlling the setting data according to a user operation setting, wherein the timing control setting data includes a triggering time And controlling the operating parameters at a certain time; and d) generating, according to the timing control operating parameter, a second lamp control signal to the lamp control module to adjust the brightness of the lighting device or The speed of the fan unit.

As described above, the smart lamp control method further includes the following steps: e) obtaining a user position and a pre-activation setting data, wherein the pre-activation setting data includes a lamp position, a distance threshold, and a And pre-starting the operating parameter; and f) generating, according to the pre-starting operating parameter, a third lamp control signal to the lamp control when a distance between the user position and the lamp position is less than the distance threshold a module to adjust the brightness of the lighting device or the speed of the fan device.

As described above, the smart lamp control method further comprises the steps of: g) obtaining a current environmental factor sensing value via a sensor; h) obtaining a pre-stored environmental factor target value; and i) And calculating and transmitting a fourth lamp control signal to the lamp control module according to the difference between the environmental factor sensing value and the environmental factor target value to adjust the brightness of the lighting device or the rotating speed of the fan device.

According to the above description, the smart lamp control method further comprises the steps of: j) obtaining a current environmental factor sensing value via a sensor; k) selecting a pre-stored complex number from a database according to the environmental factor; Learning one of the setting data, wherein the plurality of learning setting data respectively correspond to the environmental factor of the lamp control module a running parameter used under the sensed value; and 1) generating and transmitting a fifth lamp control signal to the lamp control module according to the selected learning setting data to adjust the brightness of the lighting device or The speed of the fan unit.

As described above, the smart lamp control method further includes the steps of: m) calculating a statistic; and n) transmitting the statistic to a user device or a cloud server via the Internet.

As described above, the statistical data includes an environmental factor sensing value, an environmental factor target value, or a lamp fan power consumption value respectively recorded at a plurality of time points in a statistical time range.

According to the above description, the smart lamp control method further comprises the following steps: o) generating a backup data, wherein the backup data includes the timing control setting data; and p) transmitting the backup data to a cloud via the Internet The server is backed up.

The invention can automatically operate the lamp fan, and does not require the user to manually turn on/off the lamp fan, thereby providing a better user experience.

1‧‧‧Smart Control Module

10‧‧‧First transmission module

12‧‧‧Control signal receiving module

14‧‧‧ memory

140‧‧‧Time control setting data

142‧‧‧Pre-launch setting data

144‧‧‧Environmental factor target value

146‧‧‧Database

1460‧‧‧ Learning setting information

148‧‧‧Statistics

150‧‧‧Backup data

152‧‧‧Webpage

154‧‧‧ computer program

160‧‧‧Timer

162‧‧‧Network Transmission Module

164‧‧‧ sensor

18‧‧‧ processor

180‧‧‧Processing module

182‧‧‧Timed Control Module

184‧‧‧Pre-start module

186‧‧‧ learning module

188‧‧‧Statistical Module

190‧‧‧Cloud Backup Module

192‧‧‧Web module

2, 2'‧‧‧ lamp fan

20‧‧‧Lighting fan control module

200‧‧‧Second transmission module

22‧‧‧Lighting device

24‧‧‧Fan device

30‧‧‧Network

32‧‧‧User device

34‧‧‧Cloud Server

4‧‧‧Smart Light Fan Remote Control

40‧‧‧Human Machine Interface

S60-S68‧‧‧ first control step

S700-S734‧‧‧Second control steps

FIG. 1 is a structural diagram of a smart control module according to a first embodiment of the present invention.

2 is a structural diagram of a smart lamp fan according to a first embodiment of the present invention.

3 is a schematic view showing the use of a smart lamp fan according to a first embodiment of the present invention.

4 is a structural diagram of a smart lamp remote controller according to a first embodiment of the present invention.

FIG. 5 is a schematic diagram of the use of the smart lamp remote controller according to the first embodiment of the present invention.

FIG. 6 is a flowchart of a smart lamp control method according to a first embodiment of the present invention.

FIG. 7A is a first flowchart of a smart lamp control method according to a second embodiment of the present invention.

FIG. 7B is a second flowchart of a smart lamp control method according to a second embodiment of the present invention.

DETAILED DESCRIPTION OF THE INVENTION A preferred embodiment of the present invention will be described in detail with reference to the drawings.

First, please refer to FIG. 1 , which is a smart control module frame according to a first embodiment of the present invention. Composition. As shown in FIG. 1 , the smart control module 1 of the present invention mainly includes a first transmission module 10 , a control signal receiving module 12 , a memory 14 , a timer 160 , and a processor 18 . The processor 18 is electrically connected to the first transmission module 10, the control signal transmission module 12, the memory 14 and the timer 160.

The first transmission module 10 is connected to an external lamp control module 20. Specifically, the first transmission module 10 can transmit a lamp control signal from the processor 18 to the lamp control module 20, so that the lamp control module 20 adjusts the signal according to the lamp control signal. The brightness of a lighting device (such as the lighting device 22 shown in FIG. 2 and FIG. 4) connected to the lamp control module 20 or a fan device electrically connected to the lamp control module 20 (see FIG. 2 or The rotational speed of the fan unit 24) shown in FIG.

It should be noted that the lamp control module 20, the illumination device 22 and the fan device 24 are commonly disposed on a lamp fan (such as the lamp fan 2 shown in FIG. 2 or the lamp fan 2 shown in FIG. ')in.

Preferably, the first transmission module 10 is wired (eg, connected via an Ethernet cable, a signal control line, or a Power Line Communication (PLC)). The second transmission module (such as the second transmission module 200 shown in FIG. 2) is not limited thereto.

In another embodiment of the present invention, the first transmission module 10 can also be wirelessly connected (eg, via Bluetooth wireless communication, infrared (IR) wireless communication, radio frequency (RF) wireless communication). a ZigBee wireless communication or a Z-Wave wireless communication connection. The second transmission module 200 of the lamp control module 20 (the second transmission module 200 shown in FIG. 3) .

The control signal receiving module 12 is connected to a human interface 40 and can receive a first light control signal or a time control signal from the human interface 40. Specifically, a user can operate the human interface 40 (such as touching a virtual button displayed on the touch screen or pressing a physical button of the remote controller), when the user operates in a manual mode, the person The interface 40 can send the first lamp control signal to the control signal receiving module 12; when the user operates in a certain control mode, the human interface 40 can send the timing control signal to the control signal receiving Module 12. The processor 18 receives the first lamp control signal according to the control signal receiving module 12 Or the timing control signal performs corresponding processing.

Preferably. The control signal receiving module 12 is a wired connection (such as via an Ethernet route, a signal control line, or a power line communication connection), but is not limited thereto. In another embodiment of the present invention, the control signal receiving module 12 can also be wirelessly connected (eg, via Bluetooth wireless communication, infrared wireless communication, RF wireless communication, ZigBee wireless communication, or Z-Wave wireless communication connection). Machine interface 40.

The memory 14 is used to store data, such as a time control setting data 140 for automatic timing control (detailed later). Preferably, the memory 14 is a Hard Disk Drive, a flash memory, a cache memory or a register, but is not limited thereto. .

The processor 18 primarily includes a processing module 180. The processing module 180 can transmit the first lamp control signal received from the human interface 40 to the lamp control module 20 via the first transmission module 10 to control the lamp control module 20 to adjust the The brightness of the lighting device 22 or the rotational speed of the fan unit 24.

In addition, the processing module 180 can set the timing control setting data 140 to the memory 14 according to the timing control signal received from the human interface 40. Preferably, the timing control setting data 104 includes a trigger time.

This timer 160 is used for timing. The processor 18 also includes a timing control module 182 coupled to the processing module 180. When the timer 160 times the trigger time, the timer control module 182 generates and transmits a second lamp control signal to the lamp control module 20 according to the timing control setting data 140, so that the lamp control is performed. The module 20 adjusts the brightness of the illumination device 22 or the rotational speed of the fan device 24.

Specifically, the timing control setting data 140 further includes controlling the operating parameters (such as a brightness adjusting parameter of the lighting device 22 or a speed adjusting parameter of the fan device 24). The timing control module 182 generates the second lamp control signal according to the timing control operation parameter.

In another embodiment of the present invention, the smart control module 1 may further include a pre-start mode. In the pre-launch mode, the smart control module 1 can be touched according to a distance between the location of the user and the location of the user. The lamp control module 20 automatically controls the lighting device 22 and/or the fan device 24 to be turned on or off.

Specifically, the smart control module 1 further includes a network transmission module 162 electrically connected to the processor 18 and connected to an external user device 32 via a network 30. The smart control module 1 obtains a user location from the user device 32 via the network transmission module 162. Preferably, the network 30 is an internetwork, and the network transmission module 162 establishes a network connection with the user device 32 via the Internet.

The memory 14 further stores a pre-boot setting data 142. Preferably, the pre-start setting data 142 includes a lamp position, a distance threshold, and a pre-start operation parameter. The processor 18 further includes a pre-boot module 184 connected to the processing module 180.

The pre-activation module 184 can be configured according to the pre-start operation parameter (such as the brightness adjustment parameter of the illumination device 22 or the fan device 24) when the distance between the user position and the position of the lamp is less than the distance threshold. The speed adjustment parameter generates a third lamp control signal, and transmits the third lamp control signal to the lamp control module 20 via the first transmission module 10, so that the lamp control module 20 is based on The third lamp control signal automatically adjusts the brightness of the illumination device 22 or the rotational speed of the fan device 24.

For example, if the smart control module 1 is installed in a home, the user device 32 is carried by the user. The pre-activation setting data 142 is preset by the user or set before the smart control module 1 is shipped from the factory.

The user device 32 periodically sends the user location (such as the current location of the user device 32 obtained through a satellite positioning module of the user device 32) to the smart control module 1 via the network 30. .

After entering the pre-start mode, the smart control module 1 can determine whether the distance between the user position and the home is less than the distance threshold (for example, 500 meters), and trigger when the distance is less than the distance threshold. The lamp control module 20 turns on the illumination device 22 and the fan device 24. The pre-start mode described above provides an automatic start function. In this way, when the user returns to his home, he can enjoy the best room immediately. Warm up the light and get a user experience like a family waiting at home.

Further, the smart control module 1 can automatically trigger the light fan control module 20 to turn off the lighting device 22 and the fan device when determining that the distance between the user position and the home is not less than the distance threshold. twenty four. The pre-start mode described above provides an auto-shutdown function. Therefore, even if the user forgets to turn off the lighting device 22 or the fan device 24, the smart control module 1 of the embodiment can automatically turn off the lighting device 22 and the fan device 24 after the user is away from home. And can avoid unnecessary power waste, and achieve the technical effect of energy saving and energy saving.

Further, the smart control module 1 can further acquire a current time via the timer 160, and enter the pre-start mode only for a fixed period of time (such as a period preset by the user) to implement the foregoing function. If the automatic shutdown function is activated during the user's work shift, the automatic opening function is activated during the user's off work. Therefore, the smart control module 1 of the embodiment can effectively reduce the probability of misjudged that the user has left home or will return home (if the user passes near the home during working hours, the user will not be judged to be using the user. The lighting device 22 and/or the fan device 24) will be automatically turned on when they return home.

It is to be noted that, in this embodiment, the user device 32 transmits the user position to the smart control module 1, but is not limited thereto. In another embodiment of the present invention, the user device 32 stores the position of the lamp and the distance threshold of the pre-start data 142, and calculates the distance between the user position and the position of the lamp. When the distance is less than the threshold value, a pre-start trigger signal is sent to the lamp control module 1 to trigger the lamp control module 1 to transmit the third lamp control signal to the lamp control module. 20 to control the lighting device 22 or the fan device 24 to be turned on/off.

In another embodiment of the present invention, the smart control module 1 further includes a sensor 164 electrically connected to the processor 18. The sensor 164 is configured to obtain an environmental factor sensing value. The memory 14 further stores an environmental factor target value 144. The processing module 180 calculates and transmits a fourth lamp control signal to the lamp control module 20 according to the difference between the environmental factor sensing value and the environmental factor target value 144 to adjust the brightness of the lighting device 22. Or the rotational speed of the fan unit 24.

Preferably, the sensor 164 is a temperature sensor, a humidity sensor or a brightness sensor. When the sensor 164 is a temperature sensor, the environmental factor sensing value is a temperature value of a space in which the smart control module 1 is located; when the sensor 164 is a humidity sensor, the environmental factor is sensed The measured value is the humidity value of the space in which the smart control module 1 is located; when the sensor 164 is the brightness sensor, the environmental factor sensing value is the illuminance value of the space in which the smart control module 1 is located, but Not limited to this.

For example, if the sensor 164 is a temperature sensor, the environmental factor target value 144 is 25 degrees Celsius. After the processing module 180 enters a constant temperature automatic control mode, the current environmental factor sensing value is obtained through the sensor 164 (the environmental factor sensing value in the embodiment is 30 degrees Celsius as an example). The processing module 180 calculates the difference between the environmental factor sensing value and the environmental factor target value 144 (in the embodiment, the difference is 5 degrees Celsius), and calculates and transmits the fourth according to the difference. The lamp control signal is sent to the lamp control module 20 to adjust the rotational speed of the fan unit 24 (e.g., to the fifth stage wind speed).

In another example, if the environmental factor sensing value decreases to 27 degrees Celsius, the processing module 180 can calculate the environmental factor sensing value and the environmental factor target value 144 after entering the constant temperature automatic control mode. The difference (in the example, the difference is 2 degrees Celsius), and the fourth lamp control signal is calculated and transmitted according to the difference to the lamp control module 20 to adjust the fan device 24 Speed (if adjusted to level 2 wind speed). Thereby, the present invention can effectively maintain the indoor space at a constant temperature, a constant humidity or a fixed brightness, thereby providing a better user experience for the user.

In another embodiment of the present invention, the smart control module 1 can enter a learning mode and implement a learning function of the operating parameters in the learning mode.

Next, how the present invention implements the learning function will be described. In this embodiment, the memory 14 further includes a database 146 for storing the plurality of learning setting materials 1460. Preferably, the plurality of learning setting data 1460 respectively correspond to an operating parameter used when the lamp control module 1 executes under different environmental factor sensing values.

The processor 18 further includes a learning module 186. The learning module 186 is connected to the processing module 180, and the current environmental factor sensing value is obtained through the sensor 164. And selecting one of the plural learning setting materials 1460 from the database 146 according to the obtained environmental factor sensing value. Then, the learning module 186 generates and transmits a fifth lamp control signal to the lamp control module 20 according to the selected learning setting data 1460 to adjust the brightness of the lighting device 22 or the speed of the fan device 24. . Preferably, the selected learning setting material 1460 corresponds to the current environmental factor sensing value.

For example, if the lamp control module 1 has entered the learning mode in the past, it has been set to perform the first-order wind speed at 25 degrees Celsius, and is set to perform the second level at 26 degrees Celsius. The wind speed is set to perform the third-stage wind speed at a temperature of 27 degrees Celsius, and the learning module 186 can respectively correspond to the set parameters (ie, the first-stage wind speed, the second-stage wind speed, and the third-stage wind speed) to the current moment. The environmental factor sensed value (i.e., 25 degrees Celsius, 26 degrees Celsius, and 27 degrees Celsius) is stored in the database 146 as three learning settings 1460.

After the lamp control module 1 enters the learning mode again, the learning module 186 can obtain the current environmental factor sensing value (for example, 26 degrees Celsius) via the sensor 164, and the data is obtained from the data. The learning setting data 1460 (the second-level wind speed in this embodiment) corresponding to the environmental factor sensing value is selected in the library 146, and the fifth lamp control signal is generated and transmitted according to the selected learning setting data 1460. The lamp control module 20 adjusts the rotational speed of the fan device 24 to a second-order wind speed. Thereby, the present invention can effectively operate the illumination device 22 and the fan device 24 automatically according to the user's usage habits.

In another embodiment of the present invention, the smart control module 1 can enter a statistical mode. Moreover, in the statistical mode, the smart control module 1 performs a statistical function.

Next, how the present invention implements the statistical function will be described. In the embodiment, the network transmission module 162 is connected to the user device 32 or a cloud server 34 via the network 30. The processor 18 further includes a statistics module 188. The statistic module 188 is connected to the processing module 180, and can calculate a statistic 148 and store it in the memory 14. When the network transmission module 162 is connected to the network 30, the statistic 148 is transmitted. To the user device 32 or the cloud server 34.

Preferably, the statistic 148 may include an environmental factor sensed value, an environmental factor target value, or a light recorded separately at a plurality of time points (eg, noon) in a statistical time range (eg, 1 month). The fan consumes power. Therefore, the statistical module 188 of the present invention can effectively record the running history of the lamp 2 and provide the statistic 148 of the lamp 2 to the user for the user to know the lamp 2 Run related information.

In another embodiment of the present invention, the smart control module 1 can enter a cloud backup mode. Moreover, in the cloud backup mode, the smart control module 1 performs a cloud backup function.

Next, how the present invention implements the cloud backup function will be described. In this embodiment, the network transmission module 162 is connected to the cloud server 34 via the network 30. The processor 18 further includes a cloud backup module 190. The cloud backup module 190 is connected to the processing module 180 for generating a backup data 150 and temporarily storing it in the memory 14. When the cloud backup module 190 is connected to the cloud server 34 via the network transmission module 162, the backup data 150 can be transmitted to the cloud server 34 for data backup.

Preferably, the backup data 150 includes setting data of the smart control module 1 or an operation record of the light fan 2 (eg, the timing control setting data 140, the pre-start setting data 142, the environmental factor target value 144) The plural learning setting data 1460, the statistical data 148 or any combination of the above materials, but not limited thereto.

Therefore, after the user replaces or purchases the new smart control module 1, the backup data 150 can be downloaded from the cloud server 34 to the new smart control module 1 to make the new one. The smart control module 1 can operate directly according to the backup data 150. The invention can effectively save the step of manually setting the new smart control module 1 by the user, and can provide better setting convenience.

In another embodiment of the present invention, the smart control module 1 can provide a webpage operation function. Specifically, in this embodiment, the network transmission module 162 is connected to the network 30. The memory 14 further stores a web page 152. The processor 18 further includes a webpage module 192, through which the webpage 152 provides a browsing service for the webpage 152, and receives a user operation via the webpage 152, and according to the The user operates to generate a control signal (such as the first lamp control signal, the second lamp control signal, the third lamp control signal, the fourth lamp control signal, or the fifth lamp control signal) to The brightness of the lighting device 22 or the rotational speed of the fan unit 24 is adjusted.

Further, the webpage module 192 can further display the operation related information of the light fan 2 on the webpage 152. Thereby, the user can remotely control the lamp 2 via the web page 152 or obtain the current operation information of the lamp 2 from the web page 152.

It is worth mentioning that the processing module 180, the timing control module 182, the pre-activation module 184, the learning module 186, the statistics module 188, the cloud backup module 190, and the webpage module 192 It can be implemented by hardware module (such as electronic circuit or integrated circuit of programmed digital circuit), or by software module (such as program or application programming interface (API)). , but not limited to this. When the aforementioned modules are implemented via a software module, the connection between the above modules refers to a link between programs.

The processing module 180, the timing control module 182, the pre-launching module 184, the learning module 186, the statistical module 188, the cloud backup module 190, and the webpage module 192 are via a software module. When the method is implemented, the memory 14 can further store a computer program 154, and the computer program 154 records a code or a machine code for implementing each of the foregoing modules. After the processor 18 executes the program code or mechanical code of the computer program 154, the functions of the foregoing modules can be implemented.

Referring to FIG. 2, FIG. 2 is a structural diagram of a smart lamp fan according to a first embodiment of the present invention. As shown in FIG. 2 , the lamp 2 includes the smart control module 1 , the lamp control module 20 , the lighting device 22 , and the fan device 24 . The lamp control module 20 is electrically connected to the lighting device 22 and the fan device 24 . The first transmission module 10 of the smart control module 1 is wired or wirelessly connected to the second transmission module 200 of the lamp control module 20. The smart control module 1 is the same as the smart control module 1 shown in FIG. 1 and will not be described again.

Preferably, the first transmission module 10 is detachable via a plurality of metal pins. The second transmission module 200 is electrically connected to the second transmission module 200, but is not limited thereto. Thereby, the smart control module 1 can be easily mounted to or removed from the lamp 2 .

It is worth mentioning that the lamp fan 2 is a smart lamp fan by providing the smart control module 1 therein. In other words, even if the lamp fan 2 is a general lamp fan that does not have an automatic control capability, it can be upgraded to a smart lamp fan by installing the smart control module 1 of the present invention, and the foregoing functions can be performed ( Such as the timing control function, the pre-launch function, the learning function, the statistics function or the cloud backup function).

Continuing to refer to FIG. 3, FIG. 3 is a schematic diagram of the use of the smart lamp fan according to the first embodiment of the present invention to illustrate a usage scenario of the lamp fan 2 shown in FIG. 2.

As shown in FIG. 3, the user can remotely control the lamp 2 equipped with the smart control module 1 by using the user device 32 connected to the network 30. Specifically, the user device 32 is a smart phone, and after executing an application, a graphical user interface (GUI) can be displayed. The graphical user interface can include a plurality of virtual keys and at least one display area for accepting operation by the user, the display area for displaying current operation information of the light fan 2.

After the user device 32 accepts the user operation (such as a light-on operation) via the graphical user interface, a control signal corresponding to the user operation (such as the first light fan control signal) can be generated and transmitted to the smart device. Type control module 1. Then, the smart control module 1 transmits the first lamp control signal to the lamp control module 20 to control the lighting device 22 of the lamp and/or the fan device 24 (if the lighting device 22 is turned on) ).

Referring to FIG. 4, FIG. 4 is a structural diagram of a smart lamp remote controller according to a first embodiment of the present invention. As shown in FIG. 4, in the embodiment, the smart lamp remote controller 4 includes the smart control module 1 and the human machine interface 40. The smart control module 1 is electrically connected to the human interface 40, and is wirelessly connected to the second transmission module 200 of the lamp control module 20 of the lamp 2' via the first transmission module 10. The smart control module 1 is the same as the smart control module 1 shown in FIG. This will not be repeated here.

It is worth mentioning that the lamp fan 2' can be a general lamp fan that does not have automatic control capability (ie, does not have the smart control module 1), and the smart lamp fan remote controller 4 can pass the smart type. The first transmission module 10 of the control module 1 transmits a wireless control signal compatible with a general light fan to the light fan 2' to enable the light fan 2' to achieve automatic control.

Specifically, in the present embodiment, the smart control module 1 is installed in the smart card remote controller 4 in place of the original remote controller of the lamp 2'. Moreover, the smart card remote controller 4 transmits various control signals (such as the first lamp control signal, the second lamp control signal, the third lamp control signal, and the fourth lamp control signal). Or the fifth lamp control signal is transmitted to the light fan 2', and the foregoing functions (such as the timing control function, the pre-start function, the learning function, the statistical function or the cloud backup function) can be implemented.

Therefore, the user only needs to purchase the smart lamp remote controller 4, so that the lamp 2' can be equipped with the function of the smart lamp, and the cost of replacing the lamp 2' can be effectively saved.

Referring to FIG. 5, FIG. 5 is a schematic diagram of the use of the smart lamp remote controller according to the first embodiment of the present invention to illustrate a usage scenario of the smart card remote controller 4 shown in FIG.

As shown in FIG. 5, the smart type control module 1 is internally provided with the smart control module 1 and the human-machine interface 40 is disposed on the surface. In the embodiment, the human-machine interface 40 is a button and a display. ).

The user can input the user operation (eg, the light-on operation) by operating the button (ie, the human-machine interface 40). After receiving the user operation, the smart control module 1 can generate a control signal (such as the first light fan control signal) corresponding to the user operation, and wirelessly transmit the control signal to the control signal. The lamp control module 20 of the lamp 2' is configured to control the lighting device 22 or the fan device 24 of the lamp 2' (if the lighting device 22 is turned on).

Continuing to refer to FIG. 6, which is a flowchart of a smart lamp control method according to a first embodiment of the present invention. The intelligent lamp fan control method of this embodiment is mainly shown in FIG. The intelligent control module 1 is implemented.

Step S60: receiving the first lamp control signal. Specifically, the smart control module 1 receives the corresponding user operation from the human machine interface 40, via the network 30, or via the webpage 152 via the control signal receiving module 12. The first light fan controls the signal.

Step S62: transmitting the first lamp control signal to the lamp control module 20. Specifically, the processor 18 transmits the first lamp control signal to the lamp control module 20, so that the lamp control module 20 can adjust the brightness of the illumination device 22 according to the first lamp control signal. Or the rotational speed of the fan unit 24.

Step S64: The timing control setting data 140 is set. Specifically, the smart control module 1 receives another user operation from the human machine interface 40, via the network 30, or via the webpage 152 via the control signal receiving module 12, The timing control setting data 140 is set according to the user operation. Preferably, the timing control setting data 140 includes the trigger time and the timing control operation parameter.

Step S66: It is judged whether the trigger time has passed. Specifically, the smart control module 1 determines, via the timer 160, whether the trigger time of the timing control setting data 140 has passed. If the trigger time elapses, step S68 is performed; otherwise, step S66 is repeatedly executed to continuously determine whether the trigger time has elapsed.

Step S68: The second lamp control signal is generated and transmitted to the lamp control module 20. Specifically, the smart control module 1 generates the second lamp control signal according to the timing control operation parameter of the timing control setting data 140 when the trigger time elapses via the timer 160, and the second lamp control signal is generated. A transmission module 10 is transmitted to the lamp control module 20 to adjust the brightness of the illumination device 22 or the rotational speed 24 of the fan device.

It should be noted that, in FIG. 6, the steps S60-S62 are performed before the steps S64-S68, but should not be limited thereto, and the steps S60-S62 and the steps S64-S68 are Without the order relationship or the dependency relationship, only the steps S60-S62 may be performed, the steps S64-S68 may not be performed, or the steps S64-S68 may be performed first, and then the steps S60-S62 may be performed. The execution and execution of the steps S60-S62 and the steps S64-S68 The order can be adjusted arbitrarily according to the needs of the user.

Referring to FIG. 7A and FIG. 7B, FIG. 7A is a first flowchart of a smart lamp control method according to a second embodiment of the present invention, and FIG. 7B is a second embodiment of the smart lamp control method according to the second embodiment of the present invention. flow chart. The smart lamp control method of the present embodiment is mainly implemented by the smart control module 1 shown in FIG.

Step S700: Receive the first lamp control signal.

Step S702: transmitting the first lamp control signal to the lamp control module 20.

Step S704: setting the timing control setting data 140. Preferably, the timing control setting data 140 includes the trigger time and the timing control operation parameter.

Step S706: determining whether the trigger time has elapsed. If the trigger time passes, step S708 is performed; otherwise, step S706 is repeatedly performed to continuously determine whether the trigger time has elapsed.

Step S708: The second lamp control signal is generated and transmitted to the lamp control module 20.

Step S710: Acquire the user location and the pre-activation setting data 142. Specifically, the smart control module 1 can obtain the user location from the user device 32 via the network 30, and obtain the pre-boot setting data 142 from the memory 14. Preferably, the pre-activation setting data 142 is preset by the user, and includes the lamp position, the distance threshold, and the pre-start operation parameter.

Step S712: Whether the distance from the user is less than the distance threshold. Specifically, the smart control module 1 calculates the distance between the user position and the position of the lamp, and determines whether the distance is less than the distance threshold. If the distance is less than the distance threshold, step S714 is performed; otherwise, step S712 is repeatedly performed to continuously detect.

Step S714: The third lamp control signal is generated and transmitted to the lamp control module 20. Specifically, the smart control module 1 generates the third lamp control signal according to the pre-start operation parameter of the pre-activation setting data 142, and transmits the third lamp control signal to the lamp control module via the first transmission module 10. 20 to adjust the brightness of the lighting device 24 or the rotational speed of the fan unit 22.

Step S716: Acquire the environmental factor sensing value. Specifically, the smart control module 1 obtains the current environmental sensed value of the environment around the sensor 164 via the sensor 164. Preferably, the environmental factor sensing value is a temperature value, a humidity value or an illuminance value, but is not limited thereto.

Step S718: The environmental factor target value 144 is obtained. Specifically, the smart control module 1 acquires the environmental factor target value 144 from the memory 14 . Preferably, the environmental factor target value 144 is preset by the user and stored in the memory 14.

Step S720: Generate and transmit the fourth lamp control signal to the lamp control module 20. Specifically, the smart control module 1 calculates the fourth lamp control signal according to the difference between the environmental factor sensing value and the environmental factor target value 144, and transmits the fourth lamp control signal through the first transmission module 10 The lamp control module 20 is adjusted to adjust the brightness of the illumination device 22 or the rotational speed of the fan device 24.

Step S722: Acquire the current environmental factor sensing value. Specifically, the smart control module 1 obtains the current environmental sensed value of the environment around the sensor 164 via the sensor 164.

Step S724: Select one of the plural learning setting materials 1460 from the database 146. Specifically, the smart control module 1 selects the learning setting data 1460 corresponding to the current environmental factor sensing value from the complex learning setting data 1460 stored in the database 146. Preferably, the plurality of learning setting materials 1460 respectively correspond to the operating parameters used when the lamp control module 1 executes under different environmental factor sensing values.

Step S726: The fifth lamp control signal is generated and transmitted to the lamp control module 20. Specifically, the smart control module 1 generates the fifth lamp control signal according to the selected learning setting data 1460, and transmits the control signal to the lamp control module 20 via the first transmission module 10 to adjust The brightness of the illuminating device 22 or the rotational speed of the fan unit 24.

Step S728: Calculate the statistic 148. Specifically, the smart control module 1 can calculate the statistic 148 and store it in the memory 14. Preferably, the statistics 148 may be included in the plural in the statistical time range (eg, 1 week) An environmental factor sensed value, an environmental factor target value, or a lamp fan power consumption value recorded separately between points (eg, 8:00 every night).

Step S730: The statistic 148 is transmitted to the user device 32 or the cloud server 34. Specifically, the smart control module 1 transmits the statistics 148 to the user device 32 or the cloud server 34 via the network transmission module 162.

Step S732: The backup data 150 is generated. Specifically, the smart control module 1 generates the backup data 150 and temporarily stores it in the memory 14 . Preferably, the backup data 150 includes setting data of the smart control module 1 or an operation record of the light fan 2, 2' (such as the timing control setting data 140, the pre-activation setting data 142, the environmental factor target) The value 144, the plural learning setting data 1460, the statistic 148 or any combination of the above materials, but not limited thereto.

Step S734: The backup data 150 is transmitted to the cloud server 34. Specifically, the smart control module 1 is connected to the cloud server 34 via the network transmission module 162, and transmits the backup data 150 to the cloud server 34 for data backup.

It is worth mentioning that, in FIGS. 7A and 7B, the steps S700-S702, the steps S704-S708, the steps S710-S714, the steps S716-S720, the steps S722-S726, the steps S728-S730 and the There is no order relationship or dependency relationship between steps S732-S734. The steps S700-S702, the steps S704-S708, the steps S710-S714, the steps S716-S720, the steps S722-S726, the steps S728-S730 and the steps S732-S734 can be performed or not. Adjust according to the needs of the user.

The invention can automatically operate the lamp fan without the need for the user to manually turn on/off the lamp fan, thereby providing a better user experience.

The invention automatically controls the lamp fan according to the environmental factor sensing value and the environmental factor target value, and can effectively maintain the indoor space to maintain constant temperature, constant humidity or fixed brightness, thereby providing a better user experience for the user.

The invention controls the lamp fan by selecting the learning setting data corresponding to the current environment, and can effectively make the lamp fan automatically operate according to the user's usage habits.

The invention can effectively record the running history of the statistical lamp fan, and provide the statistics of the lamp fan to the user, so that the user can know the operation related information of the lamp fan.

The cloud backup function of the invention can effectively eliminate the steps for the user to manually set a new smart control module, and can provide better setting convenience.

The above is only a preferred embodiment of the present invention, and is not intended to limit the scope of the present invention. Therefore, equivalent changes to the scope of the present invention are included in the scope of the present invention. Bright.

S60-S68‧‧‧ first control step

Claims (16)

A smart control module includes: a first transmission module connected to a lamp control module; a control signal receiving module, receiving a first lamp control signal or a time control signal; a memory, storing a pre-activation setting data, wherein the pre-activation setting data includes a lamp position, a distance threshold, and a pre-starting operation parameter; a timer; a network transmission module, connecting a user device via the Internet to Obtaining a user location; and a processor electrically connecting the network transmission module, the first transmission module, the control signal transmission module, the memory, and the timer, comprising: a processing module, Transmitting the first lamp control signal to the lamp control module via the first transmission module to adjust brightness of an illumination device electrically connected to the lamp control module or electrically connecting the lamp control module The speed of a fan device, or according to the timing control signal setting, the setting data is controlled and stored in the memory, wherein the timing control setting data includes a trigger time and a certain time control operation parameter The control module is connected to the processing module, and when the trigger time expires, the second lamp control signal is generated and transmitted to the lamp control module according to the timing control operation parameter to adjust a brightness of the lighting device or a speed of the fan device; and a pre-activation module connected to the processing module, the pre-activation module obtaining a current time via the timer, and meeting the preset one at the current time And when a distance between the user position and the position of the lamp is less than the distance threshold, generating and transmitting a third lamp control signal to the lamp control module according to the pre-start operation parameter to adjust the The brightness of the illumination device or the rotation speed of the fan device, and automatically turns off the illumination when the current time meets a preset second time period and the distance between the user position and the lamp position is not less than the distance threshold Device and the fan device. The smart control module of claim 1, further comprising a sensor electrically connected to the processor to obtain an environmental factor sensing value; the memory further storing an environmental factor target value; the processing module The group is based on the environmental factor sensing value and the environmental factor target value A difference calculation calculates and transmits a fourth lamp control signal to the lamp control module to adjust the brightness of the illumination device or the rotational speed of the fan device. The smart control module of claim 2, wherein the sensor is a temperature sensor or a humidity sensor. The smart control module of claim 1, further comprising a sensor electrically connected to the processor to obtain an environmental factor sensing value; the memory further comprising a database for storing the plurality of learning setting data The plurality of learning setting data respectively correspond to an operating parameter used by the lamp control module in the different environmental factor sensing values; the processor further includes a learning module connected to the processing module, Selecting one of the plurality of learning setting data according to the current environmental factor sensing value, and generating and transmitting a fifth lamp control signal to the lamp control module according to the selected learning setting data, to adjust the lighting device The brightness or the speed of the fan unit. The smart control module of claim 1, further comprising a network transmission module electrically connected to the processor and connected to a user device or a cloud server via the Internet; the processor further includes A statistic module is connected to the processing module, and calculates and transmits a statistic to the user device or the cloud server via the network transmission module. The smart control module of claim 5, wherein the statistical data includes an environmental factor sensing value, an environmental factor target value, or a lamp fan power consumption respectively recorded at a plurality of time points in a statistical time range. value. The smart control module of claim 1, further comprising a network transmission module electrically connected to the processor and connected to a cloud server via the Internet; the processor further comprising a cloud backup module And connecting the processing module, the cloud backup module generates a backup data, and transmits the backup data to the cloud server via the network transmission module to perform data backup. The smart control module of claim 1, further comprising a network transmission module electrically connected to the processor and connected to the Internet; the memory further storing a webpage; the processor further comprising a webpage a module, the webpage module provides a browsing service of the webpage via the network transmission module, and receives a user operation via the webpage, and generates the first light fan control signal or the second light according to the user operation Fan control signal. A smart light fan, including: The smart control module of claim 1, 2, 3, 4, 5, 6, 7, or 8; a fan device; a lighting device; and a lamp control module electrically connected to the fan device The lighting device includes a second transmission module connected to the first transmission module of the smart control module. A smart lamp remote controller comprising: a smart control module as claimed in claims 1, 2, 3, 4, 5, 6, 7, or 8; and a human machine interface electrically connected to the smart control module The group receives a user operation and generates the first lamp control signal or the timing control signal according to the user operation. A smart lamp control method includes: a) receiving a first lamp control signal; b) transmitting the first lamp control signal to a lamp control module to adjust electrical connection of the lamp control module The brightness of a lighting device or the speed of a fan device electrically connected to the lamp control module; c) controlling the setting data according to a user operation setting, wherein the timing control setting data includes a trigger time and a certain time control The operation parameter; d) generating, according to the timing control operation parameter, a second lamp control signal to the lamp control module to adjust the brightness of the illumination device or the rotation speed of the fan device. And e) obtaining a current time, a user location, and a pre-activation setting data, wherein the pre-activation setting data includes a lamp position, a distance threshold, and a pre-starting operation parameter; f) conforming to the current time a preset first time period and a distance between the user position and the lamp position is less than the distance threshold, generating and transmitting a first according to the pre-start operation parameter a lamp control signal to the lamp control module to adjust a brightness of the illumination device or a rotation speed of the fan device; and g) a predetermined second time period corresponding to the current time and the user position and the light fan When the distance between the positions is not less than the distance threshold, the lighting device and the fan device are automatically turned off. The smart lamp control method as claimed in claim 11, further comprising the following steps: h) obtaining a current environmental factor sensing value via a sensor; i) obtaining a pre-stored environmental factor target value; and j) calculating a difference value according to the environmental factor sensing value and the environmental factor target value And transmitting a fourth lamp control signal to the lamp control module to adjust the brightness of the illumination device or the rotation speed of the fan device. The smart lamp control method of claim 11, further comprising the steps of: k) obtaining a current environmental factor sensing value via a sensor; and l) selecting a pre-storage from a database according to the environmental factor; One of the plural learning setting data, wherein the plurality of learning setting data respectively correspond to an operating parameter used by the lamp control module under different environmental factor sensing values; and m) according to the selected one Learning setting data generates and transmits a fifth lamp control signal to the lamp control module to adjust the brightness of the lighting device or the speed of the fan device. The smart lamp control method of claim 11, further comprising the steps of: n) calculating a statistic; and o) transmitting the statistic to a user device or a cloud server via the Internet. The smart lamp control method according to claim 14, wherein the statistical data includes an environmental factor sensing value, an environmental factor target value, or a lamp fan consumption respectively recorded at a plurality of time points in a statistical time range. Power value. The smart lamp control method of claim 11, further comprising the steps of: p) generating a backup data, wherein the backup data includes the timing control setting data; and q) transmitting the backup data to the Internet via the Internet to A cloud server for backup.