201240525 六、發明說明: 【發明所屬之技術領域】 [0001] 本揭示内容是有關於一種照明系統,且特別是有關於一 種具有多個可遙控之節能燈具的照明系統。 【先前技術】 [0002] 在現今的社會中,各式照明燈具已成為生活必需品,可 以在夜間提供燈光,或作為指標、安全警示等等用途。 隨著社會經濟發展,現今大城市不論日夜都是燈火通明 ,大量的照明裝置逐漸對電力供應上造成負擔。 目前,隨著世界各國對能源節約的重視逐漸加深,電力 資源的節約也日益成爲各國爭相解決的課題。節能燈 (compact fluorescent lamp, CFL)的問世解決了部 分能源浪費的問題。 節能燈(CFL)是指將螢光燈管與安定器組合成一個整體的 照明設備。一般來說,節能燈的效率比傳統電燈泡來得 高,同樣照明條件下,節能燈所消耗的電能較少,所以 被稱為節能燈。 一般情況下的照明燈具經常是固定在最高能耗最高亮度 下運作,不論使用人數多寡、使用用途為何、周圍環境 明暗,這樣會帶來很多的能源浪費、折損燈泡壽命並產 生較多的廢熱。 【發明内容】 [0003] 因此,為了解決上述問題,本發明揭露一種照明系統, 其中的節能燈具可根據使用者的需求提供不同的亮度級 方案。本發明的目的就是要利用電路的不同輸出,實現 100110256 表單編號A0101 第4頁/共21頁 1002017281-0 201240525 節能燈具上不同亮度的調節。此外,本發明的照明系統 中包含一個可以無線控制多個節能燈具的遙控裝置,藉 此,使用者可以隨心所欲的遙控節能燈具的照明亮度, 並可得知節能燈具目前的狀態(如亮度、工作溫度、環境 溫度等)。 Ο 因此,本發明内容之一態樣是在提供一種照明系統,其 中該照明系統包含一遙控裝置以及複數個節能燈具。其 中每一節能燈具各自包含節能燈管、調光模組、系統模 組以及電連接器。系統模組用以供電給該調光模組。電 連接器耦接於該系統模組與該調光模組之間。而調光模 組包含Zi gbee無線通訊單元、調光單元以及開關控制單 元,調光單元及開關控制單元分別與Zigbee無線通訊單 元耗接,Zigbee無線通訊單元自遙控裝置或由其中一個 節能燈具接收第一控制指令,調光單元與開關控制單元 分別根據第一控制指令產生調光控制訊號以及開關控制 訊號。該系統模組根據該調光控制訊號以及該開關控制 訊號驅動該節能燈管。 ❹ 根據本發明之一實施例,其中每一該等節能燈具另包含 第一電路板以及第二電路板。該系統模組係設置於該第 一電路板上。該調光模組係設置於該第二電路板上,該 電連接器係設置以電性連接該第一電路板與該第二電路 板。 根據本發明之另一實施例,其中該Zigbee無線通訊單元 、該調光單元以及該開關控制單元係設置於該第二電路 板之同一侧表面上。 100110256 根據本發明之另一實施例,其中該第一電路板具有一插 表單編號A0101 第5頁/共21頁 1002017281-0 201240525 孔’該第二電路板之至少-部份插接至該第一電路板之 該插孔,該第-電路板與該第二電路板大致垂直。 根據本發明之另―實施例,其中該第1路板之形狀為 一六邊形。 根據本發明之另-實施例,其中該系統模組包含一供電 單元以及-驅動電路,該供電單元用以變壓、整流並供 電給該調光模組,㈣動電路用以根據該調光控制訊號 以及該開關控制訊號驅動該節能燈管,其中該調光控制 錢對應該節能燈管之-亮度,而該開關控制訊號對應 該節能燈管之一開關狀態& 根據本發狀另-實㈣,其巾料節随具分為複數 個群组,每-群組包含至少-節能燈具,該遙控裝置進 一步以群組為單位遙控該等節能燈具:·,。 根據本發明之另一實施例,其中該等節能燈具之中其中 一個節能燈具為一通訊協調節點,該通訊協調節點用以 轉送源自該遙控裝置之一第二控制指令至其他節能燈具 〇 根據本發明之另一實施例,其辛每一該等節能燈具另包 含一溫度感測單元’該溫度感測單元與該Zigbee無線通 訊單元電性連接’該溫度感測單元用以感測該節能燈管 之一工作溫度或該節能燈異周圍之一環境溫度產生一溫 度讀數,並透過該Zigbee無線通訊單元將該溫度讀數傳 送至該遙控裝置。 本發明内容之另一態樣是在提供一種節能燈具,其與一 遙控裝置形成無線通訊連结’ 3亥節能燈具包含節能燈管 、調光模組、系統模組以及電連接器。系統模組用以供 100110256 表單編號A0101 第6頁/共21頁 201240525 電給該調光模組。電連接器耦接於該系統模組與該調光 模組之間。而調光模組包含Zigbee無線通訊單元、調光 單元以及開關控制單元,調光單元及開關控制單元分別 與Zigbee無線通訊單元耦(接,Zigbee無線通訊單元自遙 控裝置或由其中一個節能燈具接收第一控制指令,調光 單元與開關控制單元分別根據第一控制指令產生調光控 制訊號以及開關控制訊號。該系統模組根據該調光控制 訊號以及該開關控制訊號驅動該節能燈管。 【實施方式】 [0004] 請參閱第1圖,其繪示根據本發明之一實施例中一種照明 系統100的示意圖。如第1圖所示,照明系統100包含複數 個節能燈具120以及一遙控裝置140。如圖所示,節能燈 具12 0可被設置在各個空間的各個角落,以供照明之用。 為了提高控制效率並使照明亮度均勻,各空間的節能燈 具120可分別形成一群組(如第1圖中的五個群組G1〜G5) ,每一群組G卜G5包含至少一節能燈具120,於此實施例 中,遙控裝置140進一步以群組為單位形成無線通訊連結 ,並遙控單位群組中的節能燈具120,但本發明並不以此 為限。於另一實施例中,遙控裝置140亦可分別與每一個 節能燈具120形成無線通訊連結,並進行遙控。 請參閱第2圖,其繪示根據一實施例中照明系統100中一 個節能燈具120的功能方塊圖,如圖所示,節能燈具120 各自包含節能燈管122、系統模組124以及調光模組126 。系統模組124用以供電給該調光模組126。而調光模組 126包含Zigbee無線通訊單元126a、調光單元1 26b以及 100110256 開關控制單元126c。 表單編號A0101 第7頁/共21頁 1002017281-0 201240525 調光單元126b及開關控制單元126〇:分別與Zigbee無線通 訊單元126a耦接,Zigbee無線通訊單元i26a自遙控裝置 140或由附近其他的節能燈具12〇處接收控制指令(例如調 売、調暗 '開啟、關閉等),調光單元1 26b與開關控制單 兀126c分別根據控制指令產生調光控制訊號以及開關控 制訊號,並傳送給系統模組124。系統模組丨24根據該調 光控制訊號以及該開關控制訊號驅動節能燈管丨2 2。 凊一併參閱第3圖,其繪示根據一實施例中節能燈具丨2〇 的結構示意圖。如圖所示,節能燈具丨2 〇進一步包含第一 電路板121、第二電路板123以及電連接器128。系統模 組124係設置於第一電路板1.21上,該調先模組12β係設 置於第二電路板123上。電連接器128潜設置以於第一電 路板121與第二電路板123之間,藉此電連接器128可電 性連接系統模組124與調光模組126。 凊一併參閱第4圖,其緣示根據一實施例中節能燈具1 2 〇 的第一電路板121與第二電路板1烈的結構爆炸圖。 如第4圖所示,第一電路板121具有一插孔121a,該第二 電路板123之至少一部份插接至該第一電路板丨21之該插 孔121a ’該第一電路板121與該第二電路板123大致垂直 。於此實施例中’第一電路板121之形狀可為六邊形,藉 此可配合節能燈具120的燈罩設計,但本發明並不此以為 限。 系統模組124包含供電單元124a以及驅動電路124b,供 電單元124a用以變壓、整流並供電給該調光模組126,驅 動電路124b用以根據調光控制訊號以及開關控制訊號驅 動節能燈管122,其中調光控制訊號對應該節能燈管122 100110256 表單編號A0101 第8頁/共21頁 1002017281-0 201240525 之亮度,而開關控制訊號對應節能燈管122之開關狀態。 第一電路板121的系統模組124因具有供電用途,一般來 說,第一電路板1 21需設置有整流濾波所需的濾波電容、 諧振電感、電解電容以及變壓器等元件,這些元件在工 作中發熱,為了儘量減少這些元件產生的熱量對溫度敏 感元件(如Zigbee無線通訊單元126a及其天線、調光單 元126b等)的影響,應儘量使這些發熱電路元件側對或遠 離較重要的溫度敏感元件等。 於此實施例中,Zigbee無線通訊單元126a、調光單元 〇 126b以及開關控制單元126c係設置於第二電路板123之 同一侧表面上,如第3圖所示。在基板上佈置電路元件時 ,由於Zigbee無線通訊單元126a中的電路元件、以及調 光單元126b等對溫度特別敏感,應儘量將其佈置在遠離 熱源的位置。此外,可將Zigbee無線通訊單元126a配合 的天線結構129設置於第二電路板123下方的位置,便於 天線結構129可遠離熱源干擾,並提高接收靈敏度。 Zigbee無線通訊單元126a用於接收來自遙控裝置140的 ^ 控制訊號,Zigbee無線通訊單元126a可配合第二電路板 123下方的天線結構129來收發訊息。同時Zigbee無線通 訊單元126a可根據接收到的控制指令產生脈寬調變 (PWM)訊號,然後通過RC轉換電路轉換為電頻訊號,通過 脈寬調變產生不同的電頻訊號作為調光單元126b的參考 控制訊號,調光單元126b藉由調整PWM訊號的設定,產生 不同的調光控制訊號至系統模組124中的驅動電路124b, 進而控制節能燈管122產生不同的亮度級。 另一方面,開關控制單元126c可用於控制調光單元126b 100110256 表單編號A0101 第9頁/共21頁 100201728卜0 201240525 的電源開關,從而控制節能燈管122的亮滅。舉例來說, 在節能燈具120關閉狀態下,開關控制單元126c中的電晶 體開關(如M0SFET電晶體)為第一開關狀態,此時調光單 元126b的工作電壓為0V ;當使用者操作遙控裝置發送開 啟節能燈具1 20的控制指令時,Z i gbee無線通訊單元 1 2 6 a可接收控制指令並觸發開關控制單元1 2 6 c中的電晶 體開關切換至第二開關狀態,此時開關控制單元126c就 產生開關控制訊號至系統模組124,透過系統模組124將 調光單元126 b供電電壓設定為14. 5V,如此一來,調光 單元126b便可順利運作,產生調光PWM訊號,從而點亮節 能燈管122。其中,上述第一、第二開關狀態分別為導通 或關閉狀態,視電路的邏輯設計而定。 此外,每個節能燈具120可進一步包含溫度感測單元(未 繪示),温度感測單元與該Zigbee無線通訊單元126a電 性連接,該溫度感測單元用以感測節能燈管12 0之一工作 溫度或節能燈具120周圍之環境溫度,進而產生溫度讀數 〇 舉例來說,當節能燈管120點亮運行中,溫度感測單元可 感測節能燈管120之一工作溫度;當節能燈管120關閉時 ,溫度感測單元可感測節能燈具120周圍之環境溫度。溫 度感測單元產生的溫度讀數可透過Zigbee無線通訊單元 126a將傳送至遙控裝置140。 請一併參閱第5圖,其繪示於一實施例中遙控裝置140的 按鍵示意圖。遙控裝置140内含有無線通訊收發電路,可 以與節能燈具120中的Zigbee無線通訊單元126a進行無 線通訊。 100110256 表單編號A0101 第10頁/共21頁 1002017281-0 201240525 於此實施例中,遙控裝置140可包含顯示屏141、調光亮 度燈號142、操控按鈕143~149,遙控裝置140可以實現 隨時將多個節能燈具120進行分組、更換分組、添加、刪 除、調光、開啟/關閉等動作,並且可將節能燈具120的 溫度信息回傳,顯示在節能燈具120的遙控裝置140的顯 示屏141上。201240525 VI. Description of the Invention: [Technical Field of the Invention] [0001] The present disclosure relates to an illumination system, and more particularly to an illumination system having a plurality of remotely controllable energy-saving lamps. [Prior Art] [0002] In today's society, various types of lighting fixtures have become a necessity, providing lighting at night, or as an indicator, safety warning, and the like. With the development of social economy, today's big cities are brightly lit day and night, and a large number of lighting devices are gradually burdening the power supply. At present, as countries around the world pay more and more attention to energy conservation, the conservation of power resources has increasingly become a topic that countries are competing to solve. The advent of compact fluorescent lamps (CFLs) solved some of the problem of wasted energy. Energy-saving lamps (CFLs) are lighting devices that combine a fluorescent tube with a ballast. In general, energy-saving lamps are more efficient than conventional electric bulbs. Under the same lighting conditions, energy-saving lamps consume less energy, so they are called energy-saving lamps. Under normal circumstances, lighting fixtures are often fixed at the highest energy consumption and maximum brightness, regardless of the number of people used, the purpose of use, and the surrounding environment, which will bring a lot of energy waste, damage the life of the bulb and generate more waste heat. SUMMARY OF THE INVENTION [0003] Accordingly, in order to solve the above problems, the present invention discloses a lighting system in which energy-saving lamps can provide different brightness level schemes according to user needs. The object of the present invention is to utilize the different outputs of the circuit to achieve 100110256 Form No. A0101 Page 4 of 21 1002017281-0 201240525 Adjustment of different brightness on energy-saving lamps. In addition, the illumination system of the present invention includes a remote control device capable of wirelessly controlling a plurality of energy-saving lamps, whereby the user can remotely control the illumination brightness of the energy-saving lamps, and can know the current state of the energy-saving lamps (such as brightness, work). Temperature, ambient temperature, etc.). Ο Accordingly, one aspect of the present invention is to provide a lighting system that includes a remote control device and a plurality of energy efficient lighting fixtures. Each of the energy-saving lamps includes an energy-saving lamp, a dimming module, a system module, and an electrical connector. The system module is used to supply power to the dimming module. The electrical connector is coupled between the system module and the dimming module. The dimming module comprises a Zi gbee wireless communication unit, a dimming unit and a switch control unit, the dimming unit and the switch control unit are respectively respectively connected with the Zigbee wireless communication unit, and the Zigbee wireless communication unit is received by the remote control device or by one of the energy-saving lamps. The first control command, the dimming unit and the switch control unit respectively generate the dimming control signal and the switch control signal according to the first control command. The system module drives the energy saving lamp according to the dimming control signal and the switch control signal. According to an embodiment of the invention, each of the energy-saving lamps further includes a first circuit board and a second circuit board. The system module is disposed on the first circuit board. The dimming module is disposed on the second circuit board, and the electrical connector is configured to electrically connect the first circuit board and the second circuit board. According to another embodiment of the present invention, the Zigbee wireless communication unit, the dimming unit, and the switch control unit are disposed on the same side surface of the second circuit board. 100110256 according to another embodiment of the present invention, wherein the first circuit board has a plug-in form number A0101 page 5 / 21 pages 1002017281-0 201240525 hole 'at least - part of the second circuit board is plugged into the first The jack of a circuit board, the first circuit board being substantially perpendicular to the second circuit board. According to another embodiment of the present invention, the shape of the first road plate is a hexagon. According to another embodiment of the present invention, the system module includes a power supply unit and a driving circuit for transforming, rectifying, and supplying power to the dimming module, and (4) a driving circuit for performing the dimming according to the dimming The control signal and the switch control signal drive the energy-saving lamp, wherein the dimming control money corresponds to the brightness of the energy-saving lamp, and the switch control signal corresponds to a switch state of the energy-saving lamp & In fact, (4), the towel section is divided into a plurality of groups, each group includes at least - energy-saving lamps, and the remote control device further remotely controls the energy-saving lamps in units of groups: ·,. According to another embodiment of the present invention, one of the energy-saving lamps is a communication coordination node, and the communication coordination node is configured to forward a second control command from the remote control device to other energy-saving lamps. In another embodiment of the present invention, each of the energy-saving lamps further includes a temperature sensing unit that is electrically connected to the Zigbee wireless communication unit. The temperature sensing unit is configured to sense the energy saving. A temperature reading is generated by one of the operating temperatures of the lamp or an ambient temperature of the ambient lamp, and the temperature reading is transmitted to the remote control device via the Zigbee wireless communication unit. Another aspect of the present invention is to provide an energy-saving luminaire that forms a wireless communication link with a remote control device. The energy-saving luminaire includes an energy-saving lamp, a dimming module, a system module, and an electrical connector. The system module is used to supply the dimming module to the 100110256 form number A0101 page 6 / 21 page 201240525. The electrical connector is coupled between the system module and the dimming module. The dimming module comprises a Zigbee wireless communication unit, a dimming unit and a switch control unit, and the dimming unit and the switch control unit are respectively coupled with the Zigbee wireless communication unit, and the Zigbee wireless communication unit is received by the remote control device or by one of the energy-saving lamps. The first control command, the dimming unit and the switch control unit respectively generate the dimming control signal and the switch control signal according to the first control command. The system module drives the energy saving lamp according to the dimming control signal and the switch control signal. Embodiments [0004] Referring to Figure 1, there is shown a schematic diagram of an illumination system 100 in accordance with an embodiment of the present invention. As shown in Figure 1, the illumination system 100 includes a plurality of energy-saving lamps 120 and a remote control device. 140. As shown, the energy-saving lamps 120 can be disposed at various corners of each space for illumination. To improve control efficiency and uniform illumination, the energy-saving lamps 120 of each space can form a group ( As shown in FIG. 1 , five groups G1 G G5), each group G G G5 includes at least one energy saving lamp 120, and this embodiment The remote control device 140 further forms a wireless communication link in groups, and remotely controls the energy-saving lamps 120 in the unit group. However, the present invention is not limited thereto. In another embodiment, the remote control device 140 may also be separately configured. A wireless communication link is formed with each of the energy-saving lamps 120, and remote control is performed. Referring to FIG. 2, a functional block diagram of an energy-saving lamp 120 in the illumination system 100 according to an embodiment is illustrated. Each includes an energy-saving lamp tube 122, a system module 124, and a dimming module 126. The system module 124 is configured to supply power to the dimming module 126. The dimming module 126 includes a Zigbee wireless communication unit 126a and a dimming unit 1 26b and 100110256 switch control unit 126c. Form No. A0101 Page 7 / Total 21 pages 1002017281-0 201240525 Dimming unit 126b and switch control unit 126〇: respectively coupled with Zigbee wireless communication unit 126a, Zigbee wireless communication unit i26a remote control The device 140 receives control commands (such as tuning, dimming 'on, off, etc.) from other nearby energy-saving lamps 12, the dimming unit 1 26b and the switch control The 兀126c generates a dimming control signal and a switch control signal according to the control command, and transmits the signal to the system module 124. The system module 丨24 drives the energy-saving lamp 丨2 2 according to the dimming control signal and the switch control signal. 3 is a schematic structural diagram of an energy-saving lamp 丨 2 根据 according to an embodiment. As shown, the energy-saving lamp 丨 2 〇 further includes a first circuit board 121, a second circuit board 123, and an electrical connector. 128. The system module 124 is disposed on the first circuit board 1.21. The first module 12β is disposed on the second circuit board 123. The electrical connector 128 is disposed between the first circuit board 121 and the second circuit board 123. The electrical connector 128 is electrically connected to the system module 124 and the dimming module 126. Referring to Fig. 4, there is shown a structural exploded view of the first circuit board 121 and the second circuit board 1 of the energy-saving lamp 1 2 根据 according to an embodiment. As shown in FIG. 4, the first circuit board 121 has a socket 121a, and at least a portion of the second circuit board 123 is inserted into the jack 121a of the first circuit board 21. 121 is substantially perpendicular to the second circuit board 123. In this embodiment, the shape of the first circuit board 121 may be hexagonal, so that the lamp cover design of the energy-saving lamp 120 can be matched, but the invention is not limited thereto. The system module 124 includes a power supply unit 124a for driving, rectifying, and supplying power to the dimming module 126. The driving circuit 124b is configured to drive the energy-saving lamp according to the dimming control signal and the switch control signal. 122, wherein the dimming control signal corresponds to the brightness of the energy saving lamp 122 100110256 form number A0101 page 8 / 21 page 1002017281-0 201240525, and the switch control signal corresponds to the switching state of the energy saving lamp 122. The system module 124 of the first circuit board 121 has a power supply application. Generally, the first circuit board 121 needs to be provided with components such as a filter capacitor, a resonant inductor, an electrolytic capacitor, and a transformer required for rectifying and filtering. These components are working. In order to minimize the influence of the heat generated by these components on temperature sensitive components (such as Zigbee wireless communication unit 126a and its antenna, dimming unit 126b, etc.), these heating circuit components should be as close as possible to or away from the more important temperature. Sensitive components, etc. In this embodiment, the Zigbee wireless communication unit 126a, the dimming unit 126 126b, and the switch control unit 126c are disposed on the same side surface of the second circuit board 123, as shown in FIG. When the circuit elements are arranged on the substrate, since the circuit elements in the Zigbee wireless communication unit 126a, and the dimming unit 126b and the like are particularly sensitive to temperature, they should be placed as far as possible from the heat source. In addition, the antenna structure 129 of the Zigbee wireless communication unit 126a can be disposed at a position below the second circuit board 123, so that the antenna structure 129 can be separated from the heat source and the receiving sensitivity can be improved. The Zigbee wireless communication unit 126a is configured to receive the ^ control signal from the remote control device 140, and the Zigbee wireless communication unit 126a can cooperate with the antenna structure 129 under the second circuit board 123 to send and receive messages. At the same time, the Zigbee wireless communication unit 126a can generate a pulse width modulation (PWM) signal according to the received control command, and then converts into a frequency signal by the RC conversion circuit, and generates different electrical frequency signals as the dimming unit 126b by pulse width modulation. The reference control signal, the dimming unit 126b generates different dimming control signals to the driving circuit 124b in the system module 124 by adjusting the setting of the PWM signal, thereby controlling the energy saving lamp 122 to generate different brightness levels. On the other hand, the switch control unit 126c can be used to control the power switch of the dimming unit 126b 100110256 Form No. A0101, page 9 / 21 page 100201728, 0 201240525, thereby controlling the lighting of the energy saving lamp 122. For example, in the off state of the energy-saving lamp 120, the transistor switch (such as the MOSFET transistor) in the switch control unit 126c is in the first switch state, and the operating voltage of the dimming unit 126b is 0V; when the user operates the remote control When the device sends a control command to turn on the energy-saving lamp 120, the Z i gbee wireless communication unit 1 2 6 a can receive the control command and trigger the transistor switch in the switch control unit 1 2 6 c to switch to the second switch state, at this time, the switch The control unit 126c generates a switch control signal to the system module 124, and sets the power supply voltage of the dimming unit 126b to 14.5V through the system module 124. Thus, the dimming unit 126b can operate smoothly to generate the dimming PWM. A signal, thereby illuminating the energy saving lamp 122. The first and second switch states are respectively turned on or off, depending on the logic design of the circuit. In addition, each energy-saving lamp 120 may further include a temperature sensing unit (not shown), and the temperature sensing unit is electrically connected to the Zigbee wireless communication unit 126a, and the temperature sensing unit is configured to sense the energy-saving lamp 12 a working temperature or an ambient temperature around the energy-saving lamp 120, thereby generating a temperature reading. For example, when the energy-saving lamp 120 is lit, the temperature sensing unit can sense the operating temperature of the energy-saving lamp 120; When the lamp 120 is turned off, the temperature sensing unit can sense the ambient temperature around the energy saving lamp 120. The temperature readings produced by the temperature sensing unit can be transmitted to the remote control unit 140 via the Zigbee wireless communication unit 126a. Please refer to FIG. 5, which is a schematic diagram of a button of the remote control device 140 in an embodiment. The remote control device 140 includes a wireless communication transceiver circuit for wireless communication with the Zigbee wireless communication unit 126a in the energy saving lamp 120. 100110256 Form No. A0101 Page 10 / Total 21 Page 1002017281-0 201240525 In this embodiment, the remote control device 140 can include a display screen 141, a dimming brightness indicator 142, and control buttons 143~149, and the remote control device 140 can be implemented at any time. The plurality of energy-saving lamps 120 are grouped, replaced, grouped, added, deleted, dimmed, turned on/off, and the like, and the temperature information of the energy-saving lamps 120 can be returned and displayed on the display screen 141 of the remote control device 140 of the energy-saving lamp 120. .
D 此外,請參照第1圖,因本發明的照明系統100可包含許 多個分佈於各個空間的節能燈具120,並希望能夠讓使用 者透過單一遙控裝置140控制上述多個節能燈具120運作 。本發明的節能燈具120之間進一步採用了群組網路的功 能。當節能燈具120數目較多,且距離較遠時,在上述節 能燈具120之中選定至少一個節能燈具120作為通訊協調 (coordinator)節點,如第1圖中的通訊協調節點Co。 Ο 於第1圖所示,將通訊協調節點Co的節能燈具120可設置 在適宜的位置。當遙控裝置140無法直接控制遠距離或者 位置偏僻的節能燈具120的時候,通訊協調節點Co作爲服 務中轉系統,通訊協調節點Co用以轉送源自該遙控裝置 140之一第二控制指令至其他節能燈具,如此一來,可以 大大增加其無線遙控距離,減少訊號在傳輸過程中的失 真。 綜上所述,本發明的照明系統中,節能燈具可根據使用 者的需求提供不同的亮度級方案。本發明的目的就是要 利用電路的不同輸出,實現節能燈具上不同亮度的調節 。此外,本發明的照明系統中包含一個可以無線控制多 個節能燈具的遙控裝置,藉此,使用者可以隨心所欲的 遙控節能燈具的照明亮度,並可得知節能燈具目前的狀 100110256 表單編號A0101 第11頁/共21頁 1002017281-0 201240525 態(如亮度、工作溫度、環境溫度等)。 雖然本揭示内容已以實施方式揭露如上,然其並非用以 限定本揭示内容,任何熟習此技藝者,在不脫離本揭示 内容之精神和範圍内,當可作各種之更動與潤飾,因此 本揭示内容之保護範圍當視後附之申請專利範圍所界定 者為準。 【圖式簡單說明】 [0005] 為讓本揭示内容之上述和其他目的、特徵、優點與實施 例能更明顯易懂,所附圖式之說明如下: 第1圖繪示根據本發明之一實施例中一種照明系統的示意 圖; 第2圖繪示根據一實施例中照明系統中一個節能燈具的功 能方塊圖; 第3圖繪示根據一實施例中節能燈具的結構示意圖; 第4圖繪示根據一實施例中節能燈具的第一電路板與第二 電路板的結構爆炸圖;以及 第5圖繪示於一實施例中遙控裝置的按鍵示意圖。 【主要元件符號說明】 [0006] 100 :照明系統 120 :節能燈具 140 :遙控裝置 122 :節能燈管 124 ··系統模組 126 :調光模組 128 :電連接器 129 :天線結構 124a :供電單元 124b :驅動電路 12 6a : Zigbee無線通訊單元 126b :調光單元 表單編號A0101 第12頁/共21頁 1002017281-0 [0007] 100110256 以126c :開關控制單元 121 :第一電路板 123 :第二電路板 121a :插孔 141 :顯示屏 142 :調光亮度燈號 143〜149 ··操控按鈕 G1〜G5 :群組 Co :通訊協調節點 201240525 Ο 100110256 表單編號Α0101 第13頁/共21頁 1002017281-0Further, referring to Fig. 1, the illumination system 100 of the present invention may include a plurality of energy-saving lamps 120 distributed in respective spaces, and it is desirable to allow the user to control the operation of the plurality of energy-saving lamps 120 through a single remote control device 140. The function of the group network is further adopted between the energy-saving lamps 120 of the present invention. When the number of the energy-saving lamps 120 is large and the distance is long, at least one energy-saving lamp 120 is selected among the above-mentioned energy-saving lamps 120 as a communication coordinator node, such as the communication coordination node Co in FIG.节能 As shown in Fig. 1, the energy-saving luminaire 120 of the communication coordination node Co can be placed at an appropriate position. When the remote control device 140 cannot directly control the long-distance or remotely located energy-saving lamps 120, the communication coordination node Co serves as a service relay system, and the communication coordination node Co transmits a second control command originating from the remote control device 140 to the other. Energy-saving lamps, in this way, can greatly increase their wireless remote control distance, reducing the distortion of the signal during transmission. In summary, in the illumination system of the present invention, the energy-saving lamps can provide different brightness level schemes according to the needs of the user. The object of the present invention is to achieve different brightness adjustments on energy-saving lamps using different outputs of the circuit. In addition, the illumination system of the present invention includes a remote control device capable of wirelessly controlling a plurality of energy-saving lamps, whereby the user can remotely control the illumination brightness of the energy-saving lamps, and can learn the current shape of the energy-saving lamps 100110256 Form No. A0101 11 pages / 21 pages 1002017281-0 201240525 state (such as brightness, operating temperature, ambient temperature, etc.). The present disclosure has been disclosed in the above embodiments, but it is not intended to limit the disclosure, and any person skilled in the art can make various changes and refinements without departing from the spirit and scope of the disclosure. The scope of protection of the disclosure is subject to the definition of the scope of the patent application. BRIEF DESCRIPTION OF THE DRAWINGS [0007] The above and other objects, features, advantages and embodiments of the present disclosure will become more apparent and understood. A schematic diagram of a lighting system in an embodiment; FIG. 2 is a functional block diagram of an energy-saving lamp in an illumination system according to an embodiment; FIG. 3 is a schematic structural view of an energy-saving lamp according to an embodiment; An exploded view of the structure of the first circuit board and the second circuit board of the energy-saving lamp according to an embodiment; and FIG. 5 is a schematic diagram of a button of the remote control device in an embodiment. [Main component symbol description] [0006] 100: illumination system 120: energy-saving lamp 140: remote control device 122: energy-saving lamp 124 · system module 126: dimming module 128: electrical connector 129: antenna structure 124a: power supply Unit 124b: drive circuit 12 6a: Zigbee wireless communication unit 126b: dimming unit form number A0101 page 12 / total 21 page 1002017281-0 [0007] 100110256 to 126c: switch control unit 121: first circuit board 123: second Circuit board 121a: jack 141: display screen 142: dimming brightness lamp number 143 to 149 · · control buttons G1 to G5: group Co: communication coordination node 201240525 Ο 100110256 Form number Α 0101 Page 13 / 21 pages 1002017281- 0