TWI602139B - Lighting and air-conditioning control system - Google Patents

Description

Lighting and air conditioning control system

The invention relates to a lighting and air conditioning control system.

The traditional lighting and air conditioning control system includes a remote control, a light fixture, an air conditioner, a gateway, and a server, wherein the light fixture and the air conditioner are wired to the gateway, and the gateway is wired or wirelessly connected to the server. The user can transmit commands to the server via the remote control, and then the server can control the lighting or air conditioning equipment through the gateway according to the received command. However, conventional lighting and air conditioning control systems have the following disadvantages. First, the installation is inconvenient: traditional lamps and air-conditioning equipment are connected to the gateway through physical lines. As the number of lamps and air-conditioning equipment increases, the number of physical lines increases and the installation complexity increases. Second, the control means are insufficient: traditionally, the user directly controls the lamps and air-conditioning equipment, and the lamps and air-conditioning equipment do not have automatic and diverse control means. Third, the cost is high: if other functions are to be added, such as constant ambient illumination, additional light sensors and associated circuitry are required to increase installation complexity. Fourth, the application level is too small: for example, the traditional approach is to change some of the physical control lines into control methods for wireless communication. There is not much change in essence, and other applications are not diversified.

The object of the present invention is to provide a lighting and air conditioning control system, which is convenient to install, has various control means, low cost, wide application level, and realizes control automation and energy saving automation.

To achieve the above object, the present invention provides a lighting and air conditioning control system including a smart device, a lighting assembly, an air conditioning device, a smart meter, and a server. The smart device is installed with a client application (application, abbreviated as APP) and is provided with a light sensor. The luminaire assembly includes a plurality of luminaires that are set by the user terminal APP into a luminaire group for group control. The air conditioner is set as an air conditioner group through the client APP to be grouped and controlled. The smart meter measures the power consumption of the luminaire assembly and air conditioning equipment. The server is connected to the smart device, the lamp assembly, the air conditioner and the smart meter. The server includes a database module, a brightness control module, an air conditioning control module, a mode switching module, a brightness compensation module, and a GPS module. The database module stores parameter setting values for controlling the lamp assembly and the air conditioning device, the human flow or ambient brightness value or the ambient temperature value detected by the lamp assembly or the air conditioning device, the GPS position of the lamp assembly or the air conditioner. The brightness control module controls the brightness of the lamp assembly according to the parameter setting value, the human flow rate, the ambient brightness value or the power consumption of the lamp assembly. The air conditioning control module controls the air conditioning equipment to change the temperature according to the parameter setting value, the human flow rate, the ambient temperature value, or the power consumption of the air conditioner. The mode switching module automatically controls the lamp assembly and the air conditioning device to switch between different working modes according to the flow of people. The brightness compensation module compares the illuminance setting value of the lamp assembly set by the user APP and the ambient illuminance value detected by the photo sensor to control the lamp assembly to perform brightness compensation. The Global Positioning System (GPS) module compares the GPS position of the smart device with the GPS position of the luminaire assembly or the air conditioner, and determines whether the smart device is within a specific range near the luminaire assembly or the air conditioner. Turn the luminaire assembly or air conditioning unit on or off.

In an embodiment, the luminaire assembly further includes a gateway, a lighting controller, and a sensor. The gateway is connected to the server. The lighting controller is in communication with the gateway and is electrically connected to at least one of the lamps. The sensor is electrically connected to the lighting controller to detect human flow, ambient brightness value or ambient temperature value.

In an embodiment, the client APP is provided with a group page, a schedule page, an advanced page, and a setting page. The group page provides the user to set the lighting group or air conditioning equipment group, and to control the opening, closing or dimming of the lighting group, or to control the opening, closing or temperature adjustment of the air conditioning equipment group. The scheduling page provides the user with setting parameter settings to schedule the action of the fixture group or air conditioning unit. The Advanced page provides the user to set the smart meter, as well as the communication connection settings and the GPS position settings of the luminaire assembly or air conditioning unit. The setting page provides the user with parameter settings for the group page, the scheduling page, and the advanced page.

In an embodiment, the group page displays a group control button, the group control button provides the user to control the opening, closing or dimming of the corresponding lighting group, or controls the opening, closing or temperature adjustment of the corresponding air conditioning device group. .

In one embodiment, the user sets a power usage target for the luminaire assembly or air conditioning device. The power usage target includes the historical average power consumption of the same segment or the user-defined power consumption or energy saving target.

In an embodiment, when the user sets the power consumption target of the lamp assembly or the air conditioner, the brightness control module or the air conditioning control module controls the lamp assembly or the air conditioner to increase or decrease in each subsequent setting cycle. The brightness setting value or temperature setting value until the power consumption target of the lamp assembly or air conditioner is reached.

In one embodiment, the sensor also detects human traffic for transmission to the repository module for storage. The mode switching module analyzes the flow of people and controls whether the luminaire assembly or the air conditioning device automatically switches between different operating modes. The working modes include a busy mode, a sensing mode, and a still mode.

In an embodiment, when the mode switching module is set to the alarm mode by the user APP, the mode switching module controls the lamp assembly or the air conditioner to be turned off, and turns on the lamp assembly when the sensor detects the flow of the person. Activate an alarm or send an alarm message to the smart device.

In an embodiment, the GPS position of the luminaire assembly includes the GPS position of the gateway. The specific range around the luminaire assembly includes a specific range near the gateway. The GPS position of the gateway is set by the user terminal APP to control the smart device to connect to the gateway to transmit the GPS position of the smart device as the GPS position of the gateway to the database module for storage.

In an embodiment, the page of the client APP displays a check-in button. When the check-in button is pressed and the smart device is within a certain range, the smart device starts to be monitored to record its check-in time and departure time in a specific range and is stored in the database module, thereby storing the data stored in the database module through analysis. All check-in and departure times provide information on the number of smart devices that the user has in a particular range.

With the above-mentioned soft and hard body, a large number of physical lines are omitted, and the installation is convenient; different functional modules can be used to realize automatic and diverse brightness and temperature changes according to different occasions, environments, demands and the like, and the control means are diverse; Excessive installation of additional devices, low cost; various settings through the remote end of the client APP, automatic switching between different working modes according to the flow of people, brightness compensation using the light sensor of the smart device, GPS device using the smart device Judging the location of smart devices for automatic switching of lamps and air-conditioning equipment, measuring power consumption with smart meters and providing set power consumption targets, etc., the application level is wider.

The above and other objects, features and advantages of the present invention will become more <RTIgt;

Please refer to FIG. 1, which is a schematic structural diagram of a lighting and air conditioning control system according to an embodiment of the present invention. The lighting and air conditioning control system includes a smart device 1, a plurality of light fixture assemblies 2, a plurality of air conditioners 3, a server 4, and a plurality of smart meters 5. The server 4 is communicably connected to the smart device 1, the lamp assembly 2, the air conditioner 3, and the smart meter 5. In the present embodiment, a wireless connection (indicated by a broken line) is employed. However, the present embodiment is not intended to limit the present invention. For example, the number of the luminaire assemblies 2 may be 1, the number of the air conditioners 3 may be 1, the number of the smart meters 5 may be 1, the server 4 and the luminaire assembly 2 and The air conditioner 3 can be wired.

The smart device 1 is equipped with a client APP 11 and is provided with a light sensor 12. The smart device 1 is, for example, a smartphone, a tablet phone or a tablet.

The luminaire assembly 2, as shown in FIG. 2, includes a gateway 21, a plurality of lighting controllers 22, a plurality of luminaires 23, and a plurality of sensors 24. The gateway 21 is wirelessly coupled to the server 4, and each of the lighting controllers 22 is wirelessly coupled to the gateway 21 and wired to the luminaire 23 and the sensor 24 (shown in solid lines). The gateway 21 serves as a communication interface for the lamp assembly 2 and the server 4 to communicate with each other. The lighting controller 22 controls the light fixture 23 to turn on, off, or dim, and transmits the data detected by the sensor 24 to the gateway 21. The sensor 24 can include a photo sensor for detecting an ambient brightness value, a temperature sensor for detecting an ambient temperature value, and passive infrared (PIR) sensing for detecting a human flow. And so on. However, the present embodiment is not intended to limit the present invention. For example, the number of the lighting controllers 22 may be 1, the number of the lamps 23 may be 1, the number of the sensors 24 may be 1, and the lighting controller 22 and the sensor 24 Wireless connection is available.

By using the lighting controller 22 between the gateway 21 and the luminaire 23, when the luminaire 23 is installed, only the connection with the lighting controller 22 needs to be considered, and there is no need to worry about its connection with the gateway 21. Therefore, a quick blind installation can be realized, and the installation becomes convenient. For example, the installer only needs to notice that the actual position of the luminaire 23 connected to the same lighting controller 22 does not cross two inappropriate areas (such as two rooms, one wall apart), and then the user By setting the grouping of the planning lamps 23 through the client APP 11 installed in the smart device 1, even the lamps 23 connected to the different lighting controllers 22 can be planned into the same lighting group, thereby greatly reducing the physical lines and indirectly reducing the lines. The problem of wrong connection greatly reduces the installation complexity.

The air conditioner 3 can adopt an architecture similar to the luminaire assembly 2 shown in Fig. 2, that is, the air conditioner 3 includes a gateway, an air conditioner controller, an air conditioner, and a sensor. The gateway device is wirelessly connected to the server 4, and each air conditioner controller is wirelessly connected to the gateway device and wiredly connected to the air conditioner and the sensor. The gateway serves as a communication interface for the air conditioner 3 to communicate with the server 4. The air conditioner controller controls the air conditioner to turn on, off, or adjust the temperature, and transmits the data detected by the sensor to the gateway. The air conditioner is, for example, an air conditioner, a heater, a radiator or a fan. The sensor can include a light sensor, a temperature sensor, a PIR sensor, and the like. Therefore, the air conditioner 3 can realize rapid blind installation, and then the user can set the grouping of the air conditioner 3 or the air conditioner by the user APP 11.

The smart meter 5 is electrically connected to the lamp assembly 2 and the air conditioner 3 to measure the power consumption of the lamp assembly 2 and the air conditioner 3. The smart meter 5 can report the instantaneous power consumption or the statistical power consumption of the lamp assembly 2 and the air conditioner 3 to the server 4, thereby providing related applications, such as energy saving or calculating power consumption.

The server 4 includes a database module 41, a brightness control module 42, an air conditioning control module 43, a mode switching module 44, a brightness compensation module 45, and a GPS module 46. The database module 41 stores parameter setting values for controlling the lamp assembly 2 and the air conditioner 3, human flow or ambient brightness values or ambient temperature values detected by the lamp assembly 2 or the air conditioner 3, the lamp assembly 2 or The GPS position of the air conditioner 3; wherein the parameter setting value is preset by the user, for example, through the user APP 11, the human flow, the ambient brightness value and the ambient temperature value are detected by the lamp assembly 2 or the air conditioner 3, GPS The position is preset by the user or provided by the luminaire assembly 2 or the GPS device of the air conditioning unit 3. The data stored in the database module 41 can be classified and stored according to different users. The brightness control module 42 controls the lamp assembly 2 to change the brightness according to the parameter setting value, the human flow rate or the ambient brightness value obtained by the database module 41, or the power consumption of the lamp assembly 2 measured according to the smart meter 5. . The air conditioning control module 43 controls the air conditioner 3 to perform temperature change based on the parameter setting value, the human flow rate, or the ambient temperature value obtained by the database module 41 or the power consumption of the air conditioner 3 measured based on the smart meter 5. The mode switching module 44 controls the lamp assembly 2 and the air conditioner 3 to automatically switch between different operating modes based on the flow rate of the person acquired by the database module 41. The brightness compensation module 45 compares the illuminance setting value of the lamp assembly 2 set by the client APP 11 with the ambient illuminance value detected by the photo sensor 12 provided in the smart device 1 to control the luminaire assembly 2 Brightness compensation. The GPS module 46 compares the GPS position of the smart device 1 with the GPS assembly 2 of the light fixture module 41 or the air conditioner 3, and determines whether the smart device 1 is specific to the vicinity of the light fixture assembly 2 or the air conditioner 3. Within the range, the luminaire assembly 2 or the air conditioner 3 is automatically turned on or off.

Please refer to FIG. 3 , which is a schematic diagram of a page of the client APP 11 shown in FIG. 1 . The client APP 11 installed in the smart device 1 is provided with a group page 111, a schedule page 112, an advanced page 113, and a setting page 114.

The group page 111 provides a user to set the luminaire to at least one luminaire group and generate a corresponding group control button, and then the user can control the opening, closing or dimming of the corresponding luminaire group by pressing the group control button to implement group control. Lighting. The group page 111 further provides a user to set the air conditioner or the air conditioner to at least one air conditioner group and generate corresponding group control buttons, and then the user can control the opening and closing of the corresponding air conditioner group by pressing the group control button. Or temperature adjustment, to achieve group control air conditioning equipment or air conditioning units. In the present embodiment, the group page 111 displays five group control buttons. The group control button named "living room" can be set as the lamp group G1 composed of the lamp assembly for controlling the living room position, and the group control button named "bedroom" can be set to be composed of the lamp assembly for controlling the position of the bedroom. The lighting group G2, the group control button named "kitchen" can be set as the lighting group G3 composed of the lighting assembly for controlling the kitchen position, and the group control button named "full bright" can be set to control the lighting group G1. G2 and G3, the group control buttons named "Restaurant" can be set to control the lighting groups G1 and G3. When a group control button is pressed for the first time, the group control button will be highlighted in a highlighted manner, indicating that it is being turned on, and the corresponding lighting group is turned on; when the group control button is When pressed again, it will be dimmed from high brightness, indicating that it is not turned on. At this time, the corresponding lamp group will be turned off; when the group control button is pressed long, it can enter the setting page of the corresponding lamp group, for example, modify Its brightness setting. As the number of luminaires increases, the way the packet control is controlled more efficiently. In addition, the air conditioning apparatus can also be efficiently controlled in such a manner as to be grouped and controlled.

Schedule page 112 provides the user with settings for parameter settings to schedule the operation of the fixture group or group of air conditioners. In this embodiment, the parameter setting values of the lamp group include a time range setting value, a brightness change setting value, and a group range setting value. The time range setting value is used to set the time interval for the lamp group to be turned on and off; the brightness change setting value is used to set the brightness change of the lamp group; the group range setting value is used to set which lamp group to change according to the above time range setting value and brightness. Set the value to operate. Different brightness or temperature changes can be automatically provided at different times by scheduling the luminaire group or the air conditioning unit.

The advanced page 113 provides some complicated settings for the user, such as the smart device 1, the fixture assembly 2 or the gateway of the air conditioner 3, the communication connection between the server 4 and the smart meter 5, or the lighting assembly. 2 or the setting of the GPS position of the gateway of the air conditioner 3, or the setting of the sensor. In an embodiment, the GPS position of the gateway 21 can be set to control the smart device 1 to be close to the wireless device such as Wi-Fi by bringing the smart device 1 closer to the gateway 21 and then opening the advanced page 113 of the client APP 11. The network is connected to the gateway 21 to use the GPS position of the smart device 1 as the GPS position of the gateway 21 and transmitted to the database module 41 for storage. The advanced page 113 also provides a user-set smart meter 5. For example, the user can set the power consumption target of the light fixture assembly 2 or the air conditioner 3 through the advanced page 113, and the lighting and air conditioning control system will use the power target. And comparing the power consumption measured by the smart meter 5, and controlling the lamp assembly 2 or the air conditioner 3 through the brightness control module 42 or the air conditioning control module 43 to increase or decrease the brightness setting value in each subsequent setting cycle or The temperature setting is used to adjust the brightness or temperature until the power consumption target of the lamp assembly 2 or the air conditioner 3 is reached. The power usage target can be the historical average power consumption at the same time, or it can be the user-defined power consumption or energy saving target. Compared with traditional physical meters, smart meters can provide real-time or statistical power consumption data reporting servers to provide related applications such as energy saving or computing power efficiency. In addition, the statistical power consumption can be measured by the time provided by the server, which is closer to the actual use time and has more accurate statistical results.

The setting page 114 provides the user with parameter setting for the group page 111, the scheduling page 112, and the advanced page 113. For example, some details of the sensor, such as detection frequency, distance, sensitivity, etc., can be set on this page.

Please refer to FIG. 4 , which is a timing diagram of brightness control of the lamp assembly 2 shown in FIG. 1 . In the foregoing, the brightness control module 42 controls the lamp assembly 2 to change the brightness according to the parameter setting value, the human flow rate, the ambient brightness value or the power consumption of the lamp assembly 2, thereby saving energy or providing automatic and diverse The brightness changes. Since the brightness provided by the luminaire assembly 2 is higher, the power consumption is relatively higher, so that the portion without the slash in the figure can be regarded as the power consumption or the consumed power of the luminaire assembly 2, and the slashed portion is Can be regarded as saved power. In the embodiment shown in FIG. 4, the brightness control module 42 controls the lamp assembly 2 to change the brightness according to the flow rate of the person.

As shown in the upper diagram of FIG. 4, in this embodiment, the target area detected by the sensor 24 is unmanned, and the brightness setting value of the lamp 23 is set to 5% of the maximum brightness value as the brightness value when no one is present. In other embodiments, the brightness value of the unmanned time can be designed to be 0%, that is, the luminaire 23 is completely unlit. At time t1, the sensor 24 detects that there is a person in the target area, and the brightness setting value of the lamp 23 is set to rise at a rising speed. At time t2, the brightness setting of the luminaire 23 has risen to the maximum brightness value (i.e., 100%), at which point the luminaire 23 provides the brightest brightness and then begins to maintain a hold time at the maximum brightness value. At time t3, after the hold time elapses, the sensor 24 detects that the number of people in the target area is reduced, and the brightness setting value of the lamp 23 is set to decrease at a down-regulation speed. At time t4, the brightness setting of the luminaire 23 has been reduced to a particular level of 60% of the maximum brightness value, beginning to maintain a hold time at that particular level. At time t5, after the hold time has elapsed, the sensor 24 detects that the target area is unmanned, and the brightness setting value of the lamp 23 is further lowered at a down-regulation speed. At time t6, the brightness setting value of the lamp 23 has been reduced to 5% of the maximum brightness value (i.e., the brightness value when no one is present), so the brightness value is maintained until the sensor 24 detects that the target area has talents and changes. In addition, the brightness setting value of the lamp 23 can be designed to be reduced to 0% after a period of time of 5% of the maximum brightness value (that is, the brightness value when no one is used), that is, the lamp 23 is completely off, so as to save energy and save power. Moreover, the above-mentioned speed up, down speed, specific level, hold time, and brightness value when no one is set by the user.

As shown in the lower diagram of FIG. 4, in this embodiment, at time t7 to t8, the brightness setting value of the lamp 23 adopts an extremely fast adjustment speed, so that the lamp 23 is almost instantaneously changed from no light to brightest. The application has a deterrent effect when someone illegally invades. At time t9 to t10, the brightness setting value of the lamp 23 adopts an extremely fast down-conversion speed, so that the lamp 23 is almost instantaneously changed from the brightest to the completely non-bright, which can save energy and save power. For the rest of the time, there are only two brightness settings for the luminaire 23, 0% of the maximum brightness value (ie, no light at all) and 100% (ie, the brightest). This type of lighting control is suitable for use in warehouses or after-hours offices.

Please refer to FIG. 5 , which is a timing diagram of the power consumption control of the air conditioner 3 shown in FIG. 1 . It has been mentioned above that the power consumption of the air conditioner 3 can be measured by the smart meter 5 and the server 4 can be reported, thereby providing related applications, for example, the user can set the power consumption target of the air conditioner 3, and the air conditioning control module 43 The air conditioner 3 is controlled to raise or lower the temperature set value for each subsequent set period until the power consumption target of the air conditioner 3 is reached. In this embodiment, the user initially sets the power usage target to the simultaneous historical average power consumption Pa. At time t1, when the power consumption of the air conditioner 3 exceeds a certain proportion (for example, more than 10%) of the historical average power consumption Pa of the same period, the air conditioning control module 43 controls the air conditioner 3 to raise the temperature setting value in the next set period Ts. (such as 1 °C). At time t2, that is, at the beginning of the next set period Ts of the aforementioned time t1, the air conditioning control module 43 controls the air conditioner 3 to raise the temperature set value (e.g., 1 °C). At time t3, when the power consumption of the air conditioner 3 is lower than a certain percentage of the historical average power consumption Pa (for example, less than 10%), the air conditioning control module 43 controls the air conditioner 3 to lower the temperature in the next set period Ts. Set value (such as 1 °C). At time t4, that is, at the beginning of the next set period Ts of the aforementioned time t3, the air conditioning control module 43 controls the air conditioner 3 to lower the temperature set value (e.g., down 1 °C). At time t5, the user changes the power usage target to the energy saving target and sets it to be 15% less than the historical average power consumption Pa at the same time. At time t6, that is, at the beginning of the next set period Ts of the aforementioned time t5, the air conditioning control module 43 controls the air conditioner 3 to raise the temperature set value (e.g., 1 °C). At time t7, since the energy saving target has not been reached, the air conditioning control module 43 again controls the air conditioner 3 to raise the temperature setting value (e.g., 1 degree C).

Please refer to FIG. 6 , which is a schematic diagram of the brightness compensation of the lamp assembly 2 and the smart device 1 shown in FIG. 1 . The existing smart device 1, such as a smart phone, is generally provided with a light sensor 12. The user can perform the brightness compensation function through the user APP 11 installed on the smart device 1. At this time, the user APP 11 turns on the photo sensor 12 on the smart device 1 to periodically detect the ambient illuminance value and transmit it to the server. 4. After the user sets the illuminance setting value of the luminaire assembly 2 through the user APP 11, the user APP 11 also transmits the illuminance setting value to the server 4, and then the brightness compensation module 45 will receive the ambient illuminance value and the illuminance. The set values are compared to control the lamp assembly 2 for brightness compensation, so that the ambient illuminance value detected by the light sensor 12 on the smart device 1 reaches the illuminance set value set by the user. With the light sensor 12 of the existing smart device 1 and the brightness compensation module 45 of the present invention, on-site brightness compensation can be realized without additionally providing a light sensor and related lines.

Please refer to FIG. 7, which is a schematic diagram of the lamp assembly 2 of FIG. 1 in different working modes. It has been mentioned above that the mode switching module 44 controls the lamp assembly 2 and the air conditioner 3 to automatically switch between different operating modes based on the flow of the person obtained by the database module 41. In the present embodiment, taking the luminaire assembly 2 as an example, the sensor 24 of the luminaire assembly 2 detects the flow of people and transmits it to the database module 41 for storage. The mode switching module 44 obtains the human traffic data from the database module 41 and analyzes it, and then automatically switches between the different working modes according to the human flow control lamp assembly 2, in this embodiment, in the busy mode, Switch between sensing mode and still mode. Specifically, the sensor 24 periodically detects that a person is triggered once and transmits to the server 4, and then determines the number of triggers of the sensor 24 in a time interval to determine that the lamp 23 is switched to Which working mode. When the number of triggers of the sensor 24 exceeds the high value in the time interval, it indicates that the current person flow rate is high, and it is not suitable for the control lamp 23 to change the brightness at this time, so the mode switching module 44 controls the lamp 23 to switch to busy. The mode is such that the brightness setting of the luminaire 23 is the maximum brightness value (ie, 100%). When the number of triggers of the sensor 24 is less than the high value but exceeds the low value during the time interval, it indicates that the current person flow is normal, so the mode switching module 44 controls the light fixture 23 to switch to the sensing mode, so that the light fixture 23 is based on the person. The flow rate changes the brightness. For example, the brightness setting value changes between 20% and 100% of the maximum brightness value, which saves energy. When the number of triggers of the sensor 24 is less than the low value in the time interval, it indicates that the current human flow is extremely low, so the mode switching module 44 controls the lamp 23 to switch to the stationary mode, so that the brightness setting value of the lamp 23 is the maximum brightness value. 0%, that is, the luminaire 23 is completely off (ie, the brightness value when no one is present).

In summary, the brightness setting values of the lamps 23 of the lamp assembly 2 in the busy mode, the sensing mode, and the still mode may be 100%, 20 to 100%, and 0% of the maximum brightness value, respectively; but are not limited thereto, for example, The brightness setting value in the sensing mode can be set to 30~90% of the maximum brightness value, and the brightness setting value in the static mode can be set to 5% of the maximum brightness value, so that the lamp 23 is slightly bright and convenient for people to pass. Similarly, the air conditioner 3 can also automatically switch between different working modes according to the flow rate of the person, and the temperature setting values in the busy mode, the sensing mode, and the static mode can be T, T~(T+?T1), respectively. (T+△T1)~(T+△T1+△T2) or off, where T is an integer and ΔT1 and △T2 are non-zero integers; for example, the temperature setting in busy mode can be set to 25 °C, The temperature setting value in the sensing mode can be set to 25~30°C, and the temperature setting value in the static mode can be set to 30~32°C or the air conditioner 3 can be turned off. In addition, the user can set the working mode to the alert mode through the client APP 11. In the alarm mode, the mode switching module 44 controls the lamp assembly 2 or the air conditioner 3 to be turned off, but the sensor 24 for detecting the flow of people does not turn off. When the sensor 24 detects the flow of people, If the person is illegally invaded, the mode switching module 44 sends an alarm message to the user's smart device 1, and at the same time, the luminaire 23 can be controlled to open up extremely brightly as shown in the lower figure of FIG. Acting, or turning on other peripheral devices, such as activating an alarm to produce an audible sound to create a deterrent effect, or turning on the camera to capture the scene to transmit images to the user's smart device 1.

Please refer to FIG. 8 , which is a schematic diagram of the luminaire assembly 2 of FIG. 1 automatically switched according to the position of the smart device 1 . It is mentioned above that the GPS module 46 compares the GPS position of the smart device 1 with the GPS position of the luminaire assembly 2 or the air conditioner 3 obtained by the database module 41, and determines whether the smart device 1 is in the luminaire assembly 2 or Within a specific range near the air conditioner 3, the luminaire assembly 2 or the air conditioner 3 is automatically turned on or off to provide a user GPS automatic switching function. In the present embodiment, taking the luminaire assembly 2 as an example, the GPS position of the luminaire assembly 2 is taken from the GPS position of the gateway 21 and stored in the database module 41, correspondingly the specific range of the vicinity of the luminaire assembly 2 Its gateway 21 has a range Rs formed by a certain distance. After the user turns on the GPS automatic switch function through the client APP 11, the user APP 11 periodically transmits the GPS position of the smart device 1 to the server 4, and then the GPS module 46 will receive the smart device 1 The GPS position and the GPS position of the gateway 21 obtained by the database module 41 are compared to determine whether the smart device 1 has entered the range Rs. When it is judged that the smart device 1 enters the range Rs, it means that the user carrying the smart device 1 enters the range Rs. If the lamp assembly 2 is not yet turned on, the GPS module 46 controls the lamp assembly 2 to automatically turn on. Then, when it is determined that the smart device 1 leaves the range Rs, it means that the user carrying the smart device 1 leaves the range Rs, and if the range Rs has no other users carrying the smart device, the GPS module 46 controls the lighting assembly 2 Automatically shut down. Further, the page of the client APP 11 of the smart device 1 may display a check-in button, when the check-in button is pressed and the smart device 1 is within the range Rs, the smart device 1 starts to be monitored to record its check-in time and departure in the range Rs. The time is stored in the database module 41, whereby the server 4 can obtain the information of the number of smart devices in the range Rs by analyzing all the check-in time and the departure time stored in the database module 41 to provide users or management. The person knows that it can be used as employee attendance management.

Although the present invention has been disclosed in the above embodiments, it is not intended to limit the present invention, and any person skilled in the art can make some modifications and retouchings without departing from the spirit and scope of the present invention. This is subject to the definition of the scope of the attached patent application.

1‧‧‧Smart device

11‧‧‧User APP

111‧‧‧Group page

112‧‧‧ Schedule page

113‧‧‧Advanced page

114‧‧‧Setting page

12‧‧‧Light sensor

2‧‧‧Lighting assembly

21‧‧‧ gateway

22‧‧‧Lighting controller

23‧‧‧Lights

24‧‧‧ Sensor

3‧‧‧Air conditioning equipment

4‧‧‧Server

41‧‧‧Database Module

42‧‧‧Brightness control module

43‧‧‧Air conditioning control module

44‧‧‧Mode Switching Module

45‧‧‧Brightness compensation module

46‧‧‧GPS module

5‧‧‧Smart meter

Pa‧‧‧ historical average electricity consumption at the same time

Rs‧‧ range

Ts‧‧‧Setting cycle

T1~t10‧‧‧Time

1 is a schematic structural diagram of a lighting and air conditioning control system according to an embodiment of the present invention; FIG. 2 is a schematic structural diagram of a lighting assembly according to an embodiment of the present invention; FIG. 3 is a schematic diagram of a page of a client APP according to an embodiment of the present invention; FIG. 4 is a timing diagram of brightness control of a lamp assembly according to an embodiment of the present invention; FIG. 5 is a timing diagram of power consumption control of an air conditioner according to an embodiment of the present invention; FIG. FIG. 7 is a schematic diagram of a lamp assembly in different working modes according to an embodiment of the present invention; and FIG. 8 is a schematic diagram of an automatic assembly of a lamp assembly according to an intelligent device position according to an embodiment of the present invention; .

1‧‧‧Smart device

11‧‧‧User APP

12‧‧‧Light sensor

2‧‧‧Lighting assembly

3‧‧‧Air conditioning equipment

4‧‧‧Server

41‧‧‧Database Module

42‧‧‧Brightness control module

43‧‧‧Air conditioning control module

44‧‧‧Mode Switching Module

45‧‧‧Brightness compensation module

46‧‧‧GPS module

5‧‧‧Smart meter

Claims (10)

A lighting and air conditioning control system includes: a smart device, a user terminal APP is installed, and a light sensor is disposed; at least one light fixture assembly includes a plurality of light fixtures, and the light fixtures are set to at least one through the user end APP The lighting group is controlled by grouping; at least one air conditioning device is set to at least one air conditioning device group to be grouped and controlled by the user terminal APP; at least one smart meter is used to measure power consumption of the lamp assembly and the air conditioning device; and a servo The server is connected to the smart device, the lamp assembly, the air conditioner, and the smart meter; wherein the server includes: a database module for storing parameter settings for controlling the lamp assembly and the air conditioner a person flow or ambient brightness value or an ambient temperature value detected by the lamp assembly or the air conditioner, a GPS position of the lamp assembly or the air conditioner; a brightness control module, according to the parameter setting value, a person The flow rate, the ambient brightness value or the power consumption of the lamp assembly, controlling the brightness of the lamp assembly; and an air conditioning control module, according to the parameter setting value, a flow rate, an ambient temperature value or a power consumption of the air conditioner, controlling the air conditioner to perform a temperature change; and a mode switching module, according to the flow of the person, controlling the lamp assembly and the air conditioner to automatically work differently Switching between modes; a brightness compensation module compares the illuminance setting value of the lamp assembly set by the user APP and the ambient illuminance value detected by the photo sensor to control the luminaire The assembly performs brightness compensation; and a GPS module compares the GPS position of the smart device with the GPS position of the lamp assembly or the air conditioner, and determines whether the smart device is specific to the lamp assembly or the air conditioner Within the scope to automatically turn the luminaire assembly or air conditioning equipment on or off. The lighting and air conditioning control system of claim 1, wherein the lighting assembly further comprises: a gateway connected to the server; and at least one lighting controller communicating with the gateway Connecting and electrically connecting with at least one of the lamps; and at least one sensor electrically connected to the lighting controller to detect the human flow, ambient brightness value or ambient temperature value. The lighting and air conditioning control system of claim 2, wherein the client APP provides: a group of pages, providing a user to set the lighting group or the air conditioning device group, and controlling the lighting group. Turning on, off or dimming, or controlling the opening, closing or temperature adjustment of the air conditioning device group; a scheduling page, providing a user to set the parameter setting value to arrange the action of the lighting group or the air conditioning device group; The advanced page provides a user setting the smart meter, and performing a communication connection between the smart device, the illuminator of the luminaire assembly or the air conditioner, the communication connection between the server and the smart meter, and the luminaire The GPS position setting of the gateway of the assembly or the air conditioner; and a setting page for providing the user with parameter setting of the group page, the scheduling page and the advanced page. The lighting and air conditioning control system of claim 3, wherein the group page displays at least one set of control buttons, the group control button provides a user to control the opening, closing or corresponding of the corresponding lighting group Dim, or control the opening, closing or temperature adjustment of the corresponding air conditioning unit. The lighting and air conditioning control system of claim 3, wherein the user sets a power consumption target of the lighting assembly or the air conditioning device, wherein the power consumption target includes a historical average power consumption at the same time or User-defined power consumption or energy saving goals. The lighting and air conditioning control system of claim 5, wherein the brightness control module or the air conditioning control module control unit is configured when a user sets a power consumption target of the lamp assembly or the air conditioner The luminaire assembly or the air conditioning device raises or lowers the brightness set value or the temperature set value in each subsequent set period until the power consumption target of the luminaire assembly or the air conditioner is reached. The lighting and air conditioning control system of claim 2, wherein the sensor further detects the human flow for transmission to the database module for storage, and the mode switching module analyzes the human flow. And controlling the lamp assembly or the air conditioning device to automatically switch between different operating modes, the busy mode, the sensing mode, and the stationary mode. The lighting and air conditioning control system of claim 7, wherein the mode switching module controls the lighting assembly or the air conditioning device to be turned off when the mode switching module is set to an alarm mode through the user terminal APP. And turning on the luminaire assembly, starting an alarm or sending an alarm message to the smart device when the sensor detects a flow of people. The lighting and air conditioning control system of claim 3, wherein the GPS position of the luminaire assembly includes a GPS position of the gantry, and the specific range near the luminaire assembly includes a specific vicinity of the gantry a range, wherein the GPS position of the gateway is set by the user terminal APP to control the smart device to connect to the gateway to transmit the GPS position of the smart device to the GPS position of the gateway to the device Library module storage. The lighting and air conditioning control system of claim 1, wherein the page of the client APP displays a check-in button, and when the check-in button is pressed and the smart device is within the specific range, the smart device Starting to be monitored to record their check-in time and departure time in the specified range and stored in the database module, thereby providing the user with access to all the check-in and departure times stored in the database module. The quantity information of a specific range of smart devices.