WO2018112955A1 - 一种基于ZigBee和智能手机的家庭LED照明控制装置 - Google Patents

一种基于ZigBee和智能手机的家庭LED照明控制装置 Download PDF

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WO2018112955A1
WO2018112955A1 PCT/CN2016/111883 CN2016111883W WO2018112955A1 WO 2018112955 A1 WO2018112955 A1 WO 2018112955A1 CN 2016111883 W CN2016111883 W CN 2016111883W WO 2018112955 A1 WO2018112955 A1 WO 2018112955A1
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module
zigbee
home
led
sensor module
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PCT/CN2016/111883
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English (en)
French (fr)
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孙雪刚
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孙雪刚
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Priority to PCT/CN2016/111883 priority Critical patent/WO2018112955A1/zh
Publication of WO2018112955A1 publication Critical patent/WO2018112955A1/zh

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    • GPHYSICS
    • G05CONTROLLING; REGULATING
    • G05BCONTROL OR REGULATING SYSTEMS IN GENERAL; FUNCTIONAL ELEMENTS OF SUCH SYSTEMS; MONITORING OR TESTING ARRANGEMENTS FOR SUCH SYSTEMS OR ELEMENTS
    • G05B19/00Programme-control systems
    • G05B19/02Programme-control systems electric
    • G05B19/04Programme control other than numerical control, i.e. in sequence controllers or logic controllers
    • G05B19/048Monitoring; Safety
    • YGENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
    • Y02TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
    • Y02BCLIMATE CHANGE MITIGATION TECHNOLOGIES RELATED TO BUILDINGS, e.g. HOUSING, HOUSE APPLIANCES OR RELATED END-USER APPLICATIONS
    • Y02B20/00Energy efficient lighting technologies, e.g. halogen lamps or gas discharge lamps
    • Y02B20/40Control techniques providing energy savings, e.g. smart controller or presence detection

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  • the utility model relates to the technical field of LED lamp control applications, in particular to a home LED lighting control device based on ZigBee and a smart phone.
  • This project combines ZigBee wireless sensor network, GPRS broadband mobile communication technology, ARM embedded technology and mobile APP mobile application development technology to design a smart home LED light control system based on intelligent wireless sensor network; this work is in smart home and Intelligent building lighting, even in the fields of municipal lighting and landscape lighting, has good practical application value.
  • the utility model combines sensor technology, ZigBee wireless network and GPRS broadband mobile communication technology, and proposes a scheme of a home LED lighting control device based on ZigBee and smart phone; the purpose is to overcome the above
  • the shortcoming provides a kind of real-time monitoring of the indoor LED lights and the state of the indoor environment, and the automatic shutdown and automatic brightness adjustment of the terminal LED lights according to the presence of no one, and also the basic monitoring of the surrounding environment.
  • LED energy-saving lamp control system that can be used for remote service of mobile phones.
  • the utility model provides a design scheme of a home LED lighting control device based on ZigBee and a smart phone.
  • the system component comprises: a ZigBee node terminal, a router, a coordinator, a GPRS module, a server, a web server and a mobile client software;
  • the ZigBee node terminal comprises a sensor module, a ZigBee node module, an A/D conversion module, an LED energy-saving lamp module, a PWM dimming module, a security alarm module, a light intensity detecting module and a power driving module;
  • the sensor module comprises: a photosensitive sensor a module, a temperature sensor module, a humidity sensor module, and a gas concentration sensor module; the photosensitive sensor module, the temperature sensor module, the humidity sensor module, and the gas concentration sensor module are all connected to the A/D conversion module data;
  • the A/D converter includes High-precision 16-bit A/D conversion chip and peripheral circuit;
  • ZigBee node module includes CC2530
  • the router includes: ZigBee All functional modules of the node terminal, wherein the communication mode of the CC2530 chip is set as a router; the coordinator includes a CC2530 chip and its peripheral circuits, wherein the communication mode is set as a coordinator; the GPRS module includes: a GPRS communication chip And the peripheral circuit thereof; the server comprises a motherboard, a CPU, a memory stick, a hard disk and a service system thereof; the web server comprises: a web server software and a server computer; and the web server software is installed in a server computer, And the software is properly configured; the mobile client software includes a mobile client software developed under the Android system and the Apple system.
  • the photosensitive sensor module is a photosensitive sensor and a peripheral circuit thereof;
  • the temperature module is a thermal sensor and a peripheral circuit; and
  • the humidity module is a humidity sensor and a peripheral circuit thereof;
  • the gas concentration sensor module is an oxygen sensor, a carbon dioxide sensor, a zirconia sensor, a zirconia concentration battery type gas sensor, a solid electrolyte type zirconia gas sensor, a titanium oxide oxygen sensor, and a peripheral circuit.
  • the utility model has the beneficial effects that the system is a self-organizing network type terminal LED lamp, and the system needs to be added to the terminal LED lamp without complicated system setting, which greatly facilitates the expansion of the system; LED lights can be automatically turned on and off and automatic brightness adjustment according to the indoors, which realizes the automation and intelligence of LED node lighting control, which can further reduce the power consumption.
  • the terminal LED light can also perform basic environmental monitoring on the room in which it is located, and improve the detection of the home environment to a certain extent; the system can also realize remote monitoring function through the mobile phone client, and real-time understanding of the operating status and family of each light fixture.
  • the parameters of the indoor environment can be controlled accordingly at special festivals
  • the information can be automatically sent to the user's mobile phone or emergency center, which can reduce the loss as much as possible; if the system equipment fails or the LED light fails, the mobile phone customer
  • the terminal will receive the reminder at the first time.
  • the user can know the specific location of the faulty device through the reminder, which greatly improves the system maintenance and maintenance efficiency. While energy saving, safety and environmental protection, it also meets the basic needs of intelligent home lighting.
  • Figure 1 is a schematic view of the structure of the present invention
  • 101 - power management module 101 - power management module, 102-A area, 103-ZigBee node, 104-B area, 105-PC server, 106-mobile terminal 106, 201 - photosensitive sensor module, 202 - human body infrared sensor module 203-temperature and humidity sensor module, 204-gas concentration sensor module, 205-A/D conversion module, 206-LED drive module, 207-PWM dimming sensor module, 208-light intensity detection module, 209-LED energy-saving lamp Module, 210-CC2530ZigBee node module, 211-5V and 3.3V voltage regulator module, 212-alarm module, 213-mains and short circuit protection module, 401-user management area, 402-for PC management page, 403-user Login area, 404-operation control area, 405-parameter display area, 406-mobile APP management page, 407-mobile APP control area, 408-parameter display area, 409-user notice.
  • a ZigBee-based and smart phone-based home LED lighting control device includes a power management module 101, an A area 102, a ZigBee node 103, a B area 104, a mobile terminal 106, and a PC server 105;
  • the PC server 105 is the core of the entire system, and is mainly responsible for collecting data collected by each terminal light device and obtaining the data of the lamp in a certain area to meet the working and living needs at that time.
  • Each regional device is mainly responsible for self-organizing, self-regulating, self-detecting and self-acquisition data; among them, A area is divided into four modules: PWM dimming module, led energy-saving lamp, sensor, intelligent switch; among them, PWM dimming module is mainly Adjusting the driving voltage to change the brightness of the lamp, the LED energy-saving lamp is mainly used for illumination, the sensor is mainly used to collect signals, the intelligent switch is mainly the automatic control circuit switching; the device B area is divided into three modules: GPRS module , ARM, ZigBee coordinator; GPRS module is mainly responsible for the coordinator and server communication work, ARM is mainly responsible for analyzing and processing the data of ZigBee coordinator, ZigBee coordinator is mainly responsible for finding and establishing the wireless network of the terminal ZigBee node, and Accept data collected from ZigBee nodes.
  • PWM dimming module is mainly Adjusting the driving voltage to change the brightness of the lamp
  • the LED energy-saving lamp is mainly used for illumination
  • the terminal street lamp module of the utility model comprises: a photosensitive sensor module 201, a human body infrared sensor module 202, a temperature and humidity sensor module 203, a gas concentration sensor module 204, an A/D conversion module 205, an LED driving module 206, and a PWM dimming sensor.
  • CC2530ZigBee node module 210 is the core of the terminal street light module, It is mainly responsible for the signal processing and network joining of the whole module; after the sensor module collects the data, it sends the data to the coordinating controller through the CC2530ZigBee node module 210 and then sends it to the server. If the server has control instructions to be executed, it is coordinated.
  • the device is transmitted to the node module in the manner of a multicast network, and the control command is set as an external interrupt signal of the node module (the transmitted command is an interrupt from the network in the program flow chart), then the CC2530ZigBee node module 210 receives
  • the instruction is executed immediately after the instruction; wherein the A/D conversion module 205 is a high-precision 16-bit A/D converter, which is mainly responsible for digitizing the collected analog signal; wherein the LED driving module 206 is mainly responsible for the LED energy-saving lamp module current and voltage.
  • the supply which is based on the CC2530ZigBee node module 210 output signal to control the duty cycle of the PWM dimming module 207 to supply the LED energy-saving lamp module 209 current and voltage; wherein the PWM dimming module 207 is mainly responsible for detecting the LED energy-saving lamp module 209 The light-off condition; wherein the LED energy-saving lamp module 209 is mainly mixed by a certain number of LED lamp beads
  • the light source is a light source of the terminal module; wherein the alarm module 212 is mainly responsible for the alarm after the system error; the mains and short circuit protection module 213 is mainly responsible for protecting the circuit.
  • the working process of the utility model is as follows: the working process can be divided into two relatively independent working parts, wherein: the first part is the self-organizing network and data collection of the system control end; the working process is that the server is first connected to the GPRS module, the server After confirming the success of connecting to the GPRS module, the network is established and the network is configured accordingly. Then the router finds, establishes and repairs the network packet, and finally the terminal device joins the network, thus forming a ZigBee IoT network; after the network is set up, The coordinator sends a test command to the terminal device. After receiving the test command, the terminal device sends test feedback information to the coordinator, and the coordinator receives the feedback information and starts to work normally.
  • the first part is the self-organizing network and data collection of the system control end
  • the working process is that the server is first connected to the GPRS module, the server After confirming the success of connecting to the GPRS module, the network is established and the network is configured accordingly. Then the router finds, establish
  • the ZigBee wireless sensor network transmits to the coordinator to process the data, and then the coordinator transmits the data to the server through the GPRS module.
  • the server stores and manages the data, and the terminal street lamp also performs automatic brightness adjustment while the terminal street lamp collects data. Fault detection, each parameter is sent to the server storage management together with the collected data.
  • the server can manually control the running status of the terminal lights according to the environment.
  • the second part is the control and service of the remote device of the system.
  • the server computer is connected to the Internet through the network interface. Therefore, you only need to apply for a domain name to the server and make basic configuration for the mobile phone APP software and PC control software. Then the mobile phone customer
  • the end user and the user can remotely access the server; when the user inputs the previously registered user name information into the PC management page, the user needs to be selected in the PC management page to access the server.
  • the server transmits the feedback information to the output page through the network according to the request, so that the parameters that the user needs to understand are finally fed back to the user in the form of a page.
  • the PC page requests the request.
  • the server sends the command to send and execute, and finally changes the state of the light and then sends the feedback information to the PC page for the user to browse; the mobile client user only needs to open the software to directly operate, and can browse the system information more intuitively. Control the operating status.
  • the devices of the family LED lighting control device based on the ZigBee and the smart phone of the present invention are powered on, and the components of the system are automatically initialized.
  • the workflow of the coordinator is: first, each interface is initialized, and then the GPRS module is connected to the server. After the connection is successful, the network is established and monitored. If a signal is received, the judgment is added. The incoming signal is that the terminal device joins the signal and approves to join and assign the address, and then sends the test signal. After joining the network, the server is set to an interrupt entry. If there is an interrupt, the interrupt service routine is executed immediately. If not, the receiving router and the terminal device send the interrupt. The incoming packet is sent to the server via the GPRS module.
  • the workflow of the terminal node is: first, each port is automatically initialized, and then joins the network.
  • the terminal light equipment newly joined to the network needs to receive the test information of the coordinator.
  • a terminal entrance from the coordinator is set to perform an emergency.
  • the control command issued by the coordinator then reads the value of the photosensor, compares the value with the standard value range, and if not, directly enables the alarm module to alarm the photosensor error, and sends the fault information to the user's mobile phone. For timely maintenance. And jump to read other sensor values, package the values together to the coordinator management.
  • the PWM dimming module adjusts the voltage and current supplied to the LED energy-saving lamp module according to the read value to achieve the purpose of automatic brightness adjustment, and then reads the value of the light intensity sensor to determine Whether the value is within the standard range, if it is not in the range, the alarm module alarm LED energy-saving lamp module error is enabled, and the fault information is sent to the user's mobile phone for timely maintenance; and jumps to read other sensor values, and the value is packaged. Server management. In the dead of night, the LED energy-saving lamp automatically converts to a low-light mode.
  • the corresponding operation is performed according to the data feedback of the sensor to turn the LED energy-saving module into a highlight mode, and the human body is removed according to the human body.
  • the data collected by the infrared sensor performs corresponding operations to restore the LED energy-saving lamp to the low-light mode; when a gas leak or fire occurs indoors, the accident information is notified to the user by SMS or telephone, and the loss is minimized. Safeguarding the safety of life and property.
  • the sleep mode is set to extend the hardware life and reduce the energy consumption of the device; the mode setting can be set in the service or in the terminal device. Set it yourself to be more user-friendly.
  • the user management area 401 is divided into two parts, namely, a PC management page 402 and a mobile APP management page 406; the PC management page includes a user login area 403, an operation control area 404, and a parameter display area 405; and the mobile phone management page 406 includes a mobile APP.
  • the block diagram is as follows: user and password registration area 403, operation control area 404, parameter display area 405, mobile APP control area 407, parameter display area 408, and user notice 409.
  • the user login area 403 is mainly for the user login port
  • the operation control area 404 is mainly for the emergency on/off of the LED light
  • the parameter display area 405 can display and display the data required by the user
  • the mobile APP control area 407 is mainly for the LED.
  • the parameter display area 408 is mainly to display the environmental parameters of the room
  • the user notice 409 mainly includes a text type description of the utility model, including a workflow, instructions for use, operation instructions, and the like.

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  • Physics & Mathematics (AREA)
  • General Physics & Mathematics (AREA)
  • Engineering & Computer Science (AREA)
  • Automation & Control Theory (AREA)
  • Circuit Arrangement For Electric Light Sources In General (AREA)

Abstract

公开了一种基于ZigBee和智能手机的家庭LED照明控制装置,它包括ZigBee节点终端、协调器、GPRS模块、服务器、Web服务器与手机客户端软件;系统架构为自组网络结构,当系统需要加入终端LED灯时无需复杂的系统设置,极大地方便了系统的扩展;终端LED灯可以根据室内环境实现自动通断或者亮度调节,可以对室内进行基本环境监测;该系统可以提高LED家庭照明系统的智能化管理水平,同时进一步促进电能的节约,并在一定程度上提高家庭环境的检测力度;系统还可以通过手机客户端实现远程监控功能,以及实时的了解各个灯具的运行状态和家庭室内环境的参数,而且能够在特殊节日进行相应的控制;在节能、安全、环保的同时,也满足了家庭照明智能化的基本需求。

Description

一种基于ZigBee和智能手机的家庭LED照明控制装置 技术领域
本实用新型涉及LED灯控制应用技术领域,尤其是一种基于ZigBee和智能手机的家庭LED照明控制装置。
背景技术
室内照明系统普遍存在过度照明和无效照明现象,电能浪费严重;同时,随着移动互联网、信息技术和新材料技术的快速发展以及现代人生活品质的提高,人们对于家居生活的无线化、网络化、智能化、节能化的需要越来越强烈;在这种背景之下,本项目将照明灯具、照明控制、安防警报等模块通过网络技术集成到控制平台,实现远程和移动环境下室内LED照明系统的智能控制和管理,是实现智能家居不可或缺的重要组成部分。
在人们传统意识中,照明系统仅以照明为目的;但是在科技日异月新的现在,人们对于家居照明控制系统的功能需求也是日益俱增,包括现场环境采集(光照强度、温度、湿度等)、人体感应、智能调光调色温、场景设置、无线远程监管等等;传统的照明控制系统存在布线繁琐、扩展性差、人工管理、功能单一、“长明灯”耗能严重等诸多缺陷。本项目将ZigBee无线传感器网络、GPRS宽带移动通信技术、ARM嵌入式技术和手机APP移动应用开发技术相结合,设计了基于智能无线传感网络的智能家居LED灯控制系统;本作品在智能家居和智能楼宇照明、甚至于市政照明和景观照明等领域具有很好的实际应用价值。
正是在上述背景之下,本实用新型结合传感器技术、ZigBee无线网络和GPRS宽带移动通信技术,提出了一种基于ZigBee和智能手机的家庭LED照明控制装置的方案;其目的在于克服以上所述的缺点,提供一种既能实时监控室内LED灯以及室内环境的状态,又能根据有无人进行终端LED灯的自动关断与自动亮度调节,还能在对周围环境进行基本监测的同时也能供手机进行远程服务的LED节能灯控制系统。
实用新型内容
本实用新型提出一种基于ZigBee和智能手机的家庭LED照明控制装置的设计方案,系统组件具体包括:ZigBee节点终端、路由器、协调器、GPRS模块、服务器、Web服务器与手机客户端软件;所述的ZigBee节点终端包括传感器模块、ZigBee节点模块、A/D转换模块、LED节能灯模块、PWM调光模块、安防警报模块、光强检测模块及电源驱动模块;所述的传感器模块包括:光敏传感器模块、温度传感器模块、湿度传感器模块和气体浓度传感器模块;光敏传感器模块、温度传感器模块、湿度传感器模块和气体浓度传感器模块均与A/D转换模块数据连接;所述的A/D转换器包括高精度的16位A/D转换芯片及外围电路;ZigBee节点模块包括CC2530芯片及其外围电路;LED节能灯模块包括高效LED节能灯珠混联及其外围电路;安防警报模块包括喇叭、LED指示灯及其外围电路;所述的电源模块包括12V和3.3V稳压电源模块及电路短路保护模块。
作为本实用新型的进一步技术方案:所述的路由器包括:ZigBee 节点终端的所有功能模块,其中把CC2530芯片的通信模式设置为路由器;所述的协调器包括CC2530芯片及其外围电路,其中把通信模式设置为协调器;所述的GPRS模块包括:GPRS通信芯片及其外围电路;所述的服务器包括主板、CPU、内存条、硬盘及其服务系统;所述的Web服务器包括:Web服务器软件、服务器电脑;所述的Web服务器软件需安装在服务器电脑中,并对软件做好正确的配置;所述的手机客户端软件包括基于安卓系统及苹果系统下开发的一款手机客户端软件。
作为本实用新型的进一步技术方案:所述的光敏传感器模块为光敏传感器及其外围电路;所述的温度模块为热敏传感器及外围电路;所述的湿度模块为湿度传感器及其外围电路;所述的气体浓度传感器模块为氧传感器、二氧化碳传感器、氧化锆传感器、氧化锆浓差电池型气体传感器、固体电解质式氧化锆气体传感器、另外还有二氧化钛氧传感器及外围电路。
与现有技术相比,本实用新型的有益效果是:该系统为自组网式加入终端LED灯,当系统需要加入终端LED灯时无需复杂的系统设置,极大地方便了系统的扩展;终端LED灯可以根据室内有无人进行自动通断与自动亮度调节,实现了LED节点照明控制的自动化和智能化,可以进一步降低电能的消耗。终端LED灯还可以对它所在的房间进行基本环境监测,并在一定程度上提高家庭环境的检测力度;系统还可以通过手机客户端实现远程监控功能,以及实时的了解各个灯具的运行状态和家庭室内环境的参数,而且能够在特殊节日进行相应的控 制,与此同时当出现火灾、煤气泄漏等突发情况时,可以自动的将信息发送到用户手机或急救中心,最大可能的降低了损失;如果系统设备出现故障或者LED灯出现故障,手机客户端会第一时间收到提醒,用户通过提醒,可以了解到故障设备的具体位置,极大地提高了系统维修、维护效率。在节能、安全、环保的同时,也满足了家庭照明智能化的基本需求。
附图说明
图1是本实用新型的结构示意图;
附图标记中:101-电源管理模块、102-A区域、103-ZigBee节点、104-B区域、105-PC服务器、106-手机终端106、201-光敏传感器器模块、202-人体红外传感器模块、203-温湿度传感器模块、204-气体浓度传感器模块、205-A/D转换模块、206-LED驱动模块、207-PWM调光感器模块、208-光强检测模块、209-LED节能灯模块、210-CC2530ZigBee节点模块、211-5V及3.3V稳压电压模块、212-报警模块、213-市电及短路保护模块、401-用户管理区域、402-为PC机管理页面、403-用户登录区域、404-操作控制区域、405-参数显示区域、406-手机APP管理页面、407-手机APP控制区域、408-参数显示区域、409-用户须知。
具体实施方式
下面将结合本实用新型实施例中的附图,对本实用新型实施例中的技术方案进行清楚、完整地描述。显然,所描述的实施例仅仅是本实用新型一部分实施例,而不是全部的实施例。基于本实用新型中的 实施例,本领域普通技术人员在没有做出创造性劳动前提下所获得的所有其它实施例,都属于本实用新型保护的范围。
参见图1,本实用新型实施例中,一宗基于ZigBee和智能手机的家庭LED照明控制装置包括电源管理模块101、A区域102、ZigBee节点103、B区域104、手机终端106、PC服务器105;具体如图1所示,PC服务器105是整个系统的核心,主要负责收集各终端灯设备采集反馈得到数据及其强制调控某区域的灯的运行状态以便满足当时的工作和生活需求。各区域设备主要负责自组网、自调节、自检测和自采集数据;其中A区域有分为四大模块:PWM调光模块、led节能灯、传感器、智能开关;其中PWM调光模块主要是调节驱动电压来改变灯的亮度,LED节能灯主要是用来照明,传感器主要是用来采集信号,智能开关主要是自动的控制电路的通断;设备B区域有分为三大模块:GPRS模块、ARM、ZigBee协调器;其中GPRS模块主要负责协调器与服务器的联通工作,ARM主要负责对ZigBee协调器的数据进行分析与处理,ZigBee协调器主要负责寻找、建立终端ZigBee节点的无线网络,并接受来自ZigBee节点采集的数据。
本实用新型的终端路灯模块包括:光敏传感器器模块201、人体红外传感器模块202、温湿度传感器模块203、气体浓度传感器模块204、A/D转换模块205、LED驱动模块206、PWM调光感器模块207、光强检测模块208、LED节能灯模块209、CC2530ZigBee节点模块210、5V稳压电压模块及3.3V稳压电压模块211、报警模块212和市电及短路保护模块213;其中CC2530ZigBee节点模块210为终端路灯模块的核心, 它主要负责整个模块的信号处理和网络加入;当传感器模块采集到数据后,通过CC2530ZigBee节点模块210将数据发送到协调控制器之后再发送到服务器,如果服务器有控制指令需要执行时,通过协调控制器以组播网的方式传送给节点模块,并设定控制指令为节点模块的外部中断信号(此传送的指令即为程序流程图中的来自网络中的中断),那么CC2530ZigBee节点模块210收到指令后则立即执行指令;其中A/D转换模块205为高精度16位的A/D转换器,主要负责把采集到的模拟信号数字化;其中LED驱动模块206主要负责LED节能灯模块电流及电压的供给,它是根据CC2530ZigBee节点模块210输出信号控制PWM调光模块207的占空比来供给LED节能灯模块209电流和电压的大小;其中PWM调光模块207主要负责检测LED节能灯模块209实际亮灭情况;其中LED节能灯模块209主要由一定数量的LED灯珠混联而成,是终端模块的光源;其中报警模块212主要负责系统出错后的报警;市电及短路保护模块213主要负责保护电路。
本实用新型的工作流程为:其工作过程可以分为两个相对独立工作的部分,其中:第一部分是系统控制端的自组网和数据采集;其工作过程是,首先由服务器连接GPRS模块,服务器确认连接GPRS模块成功后,接着进行网络的建立以及网络的相关配置,再由路由器寻找、建立及修复网络报文,最后终端设备加入网络,这样就组成一个ZigBee物联网络;网络组建好之后,协调器发送测试指令到终端设备,终端设备收到测试指令后,将发送测试反馈信息到协调器,协调器接收到反馈信息便开始正常工作。此时终端路灯将采集到的数据通过 ZigBee无线传感网络传送至协调器对数据进行处理,之后再由协调器通过GPRS模块传送到服务器,服务器对其数据进行存储和管理,在终端路灯采集数据的同时终端路灯也进行自动亮度调节和故障检测,各项参数与采集到的数据一起送服务器存储管理。服务器除了管理存储数据外,还可以根据环境情况需要手动控制终端灯的运行状态。
第二部分是系统的远程设备的控制与服务。在服务器电脑端同时安装手机APP软件与PC控制软件,服务器电脑通过网络接口与互联网相连通,因此只需给服务器申请一个域名,并对手机APP软件与PC控制软件做好基本配置,那么手机客户端用户与用户就可以远程访问服务器;当用户输入之前注册的用户名信息进入PC管理页面后,在PC管理页面中选择用户需要的请求,访问服务器。服务器根据请求将反馈信息通过网络传送到输出页面,这样,用户需要了解的各项参数最终以页面的形式反馈给用户浏览,如果用户有请求需要控制终端灯设备的运行状态,则PC页面把请求直接送控制系统的服务器,服务器发送指令下送执行,最后改变灯的状态再把反馈信息送PC页面供用户浏览;手机客户端用户只需打开软件直接操作,便可更直观的浏览系统信息和控制运行状态。
下面结合具体实施例进一步具体说明本实用新型的终端模块与协调器的工作流程;将本实用新型基于ZigBee和智能手机的家庭LED照明控制装置的各个器件通电,系统的各个部件进行自动初始化。
协调器的工作流程即:首先是各接口初始化,然后GPRS模块连接到服务器,连接成功后,建立网络并监控,如果收到信号,则判断加 入信号,是终端设备加入信号则批准加入并分配地址,再发送测试信号,加入网络完成后,给服务器设定一个中断入口,有中断则马上执行中断服务程序,没有则接收路由器和终端设备发送过来的数据包,并通过GPRS模块把数据发送到服务器。
终端节点的工作流程即:首先各端口自动初始化,然后加入网络,新加入网络的终端灯设备需要接收协调器的测试信息,此时在此设定一个来自协调器的终端入口,以便执行紧急情况时协调器下发的控制指令,接着读取光敏传感器的数值,把数值与标准值范围进行比较,如不在范围则直接使能报警模块报警光敏传感器错误,同时将故障信息发送到用户的手机,以便及时维护。并跳转到读取其他传感器数值,把数值一起打包送协调器管理。如在标准范围内则开启LED驱动模块,之后PWM调光模块根据读取到的值调整供给LED节能灯模块的电压和电流,使其达到自动亮度调节目的,接着读取光强传感器数值,判断数值是否在标准范围内,如果不在范围则使能报警模块报警LED节能灯模块错误,同时将故障信息发送到用户的手机,以便及时维护;并跳转到读取其他传感器数值,把数值打包送服务器管理。在夜深人静的时候LED节能灯自动的转换为低亮的模式,当人体红外传感器检测到有人时,根据传感器的数据反馈来执行相应的操作使LED节能模块转为高亮模式,人离开之后根据人体红外传感器采集到的数据,执行相应的操作使LED节能灯恢复到低亮模式;当室内发生煤气泄漏或火灾时,会将事故信息以短信或电话的形式通知用户,最大可能的降低了损失,保障了生命和财产安全。最后设置一种休眠模式,在某个时 间段不需要进行上述工作过程,当休眠时间到,自动又返回上述工作模式工作,设置休眠模式是为了延长硬件寿命、降低设备能耗;模式设置可以在服务中设定也可以在终端设备中自行设置,从而更加人性化。
用户管理区域401分为两部分,分别为PC机管理页面402和手机APP管理页面406;PC机管理页面包含用户登录区域403、操作控制区域404和参数显示区域405;手机管理页面406包含手机APP控制区域407、参数显示区域408;用户登录后点击确定便访问到服务器。结构框图如下:用户及密码登录区域403、操作控制区域404、参数显示区域405、手机APP控制区域407、参数显示区域408和用户须知409。用户登录区域403主要是对用户登录端口,操作控制区域404主要是对LED灯的应急开/关;参数显示区域405可以对用户需要的数据进行显示与显示;手机APP控制区域407主要是对LED灯的一个远程应急控制,参数显示区域408主要是显示室内的环境参数;用户须知409主要包括文字型的对本实用新型的说明,其中包括工作流程、使用说明、操作说明等。
对于本领域技术人员而言,本实用新型不限于上述示范性实施例的细节,而且在不背离本实用新型的精神或基本特征的情况下,能够以其它的具体形式实现本实用新型。因此,无论从哪一点来看,均应将实施例看作是示范性的,而且是非限制性的,本实用新型的范围由所附权利要求而不是上述说明限定,因此旨在将落在权利要求的等同要件的含义和范围内的所有变化囊括在本实用新型内。不应将权利要 求中的任何附图标记视为限制所涉及的权利要求。
以上所述,仅为本实用新型的较佳实施例,并不用以限制本实用新型,凡是依据本实用新型的技术实质对以上实施例所作的任何细微修改、等同替换和改进,均应包含在本实用新型技术方案的保护范围之内。

Claims (1)

  1. 一种基于ZigBee和智能手机的家庭LED照明控制装置,包括ZigBee节点终端、协调器、GPRS模块、服务器、Web服务器与手机客户端软件;其特征在于:所述的ZigBee节点终端包括传感器模块、ZigBee节点模块、A/D转换模块、LED节能灯模块、PWM调光模块、安防警报模块、光强检测模块及电源驱动模块;所述的传感器模块包括:光敏传感器模块、温度传感器模块、湿度传感器模块和气体浓度传感器模块;光敏传感器模块、温度传感器模块、湿度传感器模块和气体浓度传感器模块均与A/D转换模块数据连接;所述的A/D转换器包括高精度的16位A/D转换芯片及外围电路;ZigBee节点模块包括CC2530芯片及其外围电路;LED节能灯模块包括高效LED节能灯珠混联及其外围电路;安防警报模块包括喇叭、LED指示灯及其外围电路;所述的电源模块包括12V稳压电源模块和3.3V稳压电源模块及电路短路保护模块。
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