TWI832773B - Light energy transmission device - Google Patents
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Description
本發明關於一種光能量傳輸裝置,特別關於一種可用以於供電或充電的光能量傳輸裝置。The present invention relates to an optical energy transmission device, and in particular to an optical energy transmission device that can be used for power supply or charging.
太陽能電池是一種暴露在陽光下便會產生直流電的發電裝置,由幾乎全部以半導體物料(例如矽)製成的薄身固體光伏電池組成,簡單的光伏電池可為手錶及電腦提供能源,較複雜的光伏系統可為房屋提供照明,並為電網供電。現在,太陽能的利用還不是很普及,利用太陽能發電還存在成本高、轉換效率低的問題,但是太陽能電池在功耗小的電子產品中得到較來越廣泛的應用。A solar cell is a power generation device that generates direct current when exposed to sunlight. It consists of thin solid photovoltaic cells that are almost entirely made of semiconductor materials (such as silicon). Simple photovoltaic cells can provide energy for watches and computers. More complex ones can provide energy for watches and computers. The photovoltaic system lights the house and supplies power to the grid. At present, the use of solar energy is not very popular, and the use of solar energy to generate electricity still has problems such as high cost and low conversion efficiency. However, solar cells are increasingly widely used in electronic products with low power consumption.
然而,太陽能為間歇性能源,受氣候、晝夜的影響很大,室內或室外沒有陽光之處就無法提供穩定電力給電子裝置。因此,如何不受天候影響而可提供電子裝置穩定的供電,一直是業界相當重視的課題之一。However, solar energy is an intermittent energy source that is greatly affected by climate, day and night. It cannot provide stable power to electronic devices in places where there is no sunlight indoors or outdoors. Therefore, how to provide stable power supply for electronic devices without being affected by weather has always been one of the issues that the industry attaches great importance to.
有鑑於上述課題,本發明的目的為提供一種可用於傳輸光能量的光能量傳輸裝置。本發明不受氣候、晝夜的影響,即使在室內或室外沒有陽光之處一樣可以穩定地提供光能量給電子裝置。In view of the above problems, an object of the present invention is to provide an optical energy transmission device that can be used to transmit optical energy. The invention is not affected by climate, day and night, and can stably provide light energy to electronic devices even indoors or outdoors where there is no sunlight.
為達上述目的,本發明提出一種光能量傳輸裝置,與至少一電子裝置配合應用,光能量傳輸裝置包括一光傳輸模組、一透鏡模組以及一控制模組。透鏡模組與光傳輸模組對應設置,透鏡模組設置於光傳輸模組與電子裝置之間,且光傳輸模組發出的光線穿過透鏡模組並照射電子裝置。控制模組與光傳輸模組及透鏡模組連接,控制模組依據電子裝置的放置位置和面積改變穿過透鏡模組之出光光型與照射面積,俾使具有照射面積的光線至少涵蓋電子裝置。To achieve the above object, the present invention proposes an optical energy transmission device that is used in conjunction with at least one electronic device. The optical energy transmission device includes an optical transmission module, a lens module and a control module. The lens module and the light transmission module are arranged correspondingly. The lens module is arranged between the light transmission module and the electronic device, and the light emitted by the light transmission module passes through the lens module and illuminates the electronic device. The control module is connected to the light transmission module and the lens module. The control module changes the light pattern and irradiation area that passes through the lens module according to the placement position and area of the electronic device, so that the light with the irradiation area at least covers the electronic device. .
在一實施例中,光傳輸模組包括紅外線雷射發射器、紅外線發光二極體、紫外線發光二極體或照明發光二極體、或其組合。In one embodiment, the light transmission module includes an infrared laser emitter, an infrared light emitting diode, an ultraviolet light emitting diode or an illumination light emitting diode, or a combination thereof.
在一實施例中,透鏡模組包括複眼透鏡或菲涅耳透鏡。In one embodiment, the lens module includes a fly-eye lens or a Fresnel lens.
在一實施例中,控制模組與光傳輸模組電性連接,光傳輸模組包含複數個區域的多個發光元件,控制模組依據電子裝置的放置位置和面積控制至少其中一個區域的發光元件發光,俾使具有照射面積的光線涵蓋電子裝置。In one embodiment, the control module is electrically connected to the light transmission module. The light transmission module includes a plurality of light-emitting elements in a plurality of areas. The control module controls the light emission of at least one of the areas according to the placement position and area of the electronic device. The component emits light so that the light having an irradiation area covers the electronic device.
在一實施例中,控制模組改變光傳輸模組的傾斜角度以改變光傳輸模組發出光線的出射角度,進而改變穿過透鏡模組之光線的出光光型與照射面積以涵蓋電子裝置。In one embodiment, the control module changes the tilt angle of the light transmission module to change the exit angle of the light emitted by the light transmission module, thereby changing the light exit pattern and illumination area of the light passing through the lens module to cover the electronic device.
在一實施例中,控制模組改變光能量傳輸裝置的傾斜角度,進而改變穿過透鏡模組之光線的出光光型與照射面積以涵蓋電子裝置。In one embodiment, the control module changes the tilt angle of the light energy transmission device, thereby changing the light output pattern and illumination area of the light passing through the lens module to cover the electronic device.
在一實施例中,控制模組依據電子裝置的放置位置和面積改變光傳輸模組與透鏡模組之間的距離,進而改變穿過透鏡模組之光線的出光光型與照射面積以涵蓋電子裝置。In one embodiment, the control module changes the distance between the light transmission module and the lens module according to the placement position and area of the electronic device, thereby changing the light emission pattern and irradiation area of the light passing through the lens module to cover the electronic device. device.
在一實施例中,光能量傳輸裝置更包括一影像擷取模組,影像擷取模組與控制模組電性連接,影像擷取模組擷取及辨識電子裝置的放置位置和面積並輸出一控制訊號,控制模組依據控制訊號改變穿過透鏡模組之光線的出光光型與照射面積,俾使具有照射面積的光線涵蓋電子裝置。In one embodiment, the light energy transmission device further includes an image capture module. The image capture module is electrically connected to the control module. The image capture module captures and identifies the placement position and area of the electronic device and outputs A control signal, the control module changes the light output pattern and irradiation area of the light passing through the lens module according to the control signal, so that the light with the irradiation area covers the electronic device.
在一實施例中,光能量傳輸裝置更包括一定位模組,定位模組發出光線標示出電子裝置的放置位置與面積,控制模組依據定位模組標示出的放置位置與面積改變穿過透鏡模組之光線的出光光型與照射面積,俾使具有照射面積的光線涵蓋電子裝置。In one embodiment, the optical energy transmission device further includes a positioning module. The positioning module emits light to mark the placement position and area of the electronic device. The control module changes the light passing through the lens according to the placement position and area marked by the positioning module. The light emitting pattern and irradiation area of the module are such that the light with the irradiation area covers the electronic device.
在一實施例中,光能量傳輸裝置更包括一照明模組,照明模組與光傳輸模組及透鏡模組整合成單一構件。In one embodiment, the light energy transmission device further includes an illumination module, which is integrated with the light transmission module and the lens module into a single component.
承上所述,在本發明的光能量傳輸裝置中,透過透鏡模組與光傳輸模組對應設置,透鏡模組設置於光傳輸模組與電子裝置之間,且光傳輸模組發出的光線穿過透鏡模組並照射電子裝置;以及,控制模組與光傳輸模組及透鏡模組連接,並可依據電子裝置的放置位置和面積改變穿過透鏡模組之光線的出光光型與照射面積,俾使具有照射面積的光線至少涵蓋電子裝置的設計,使本發明不受氣候、晝夜的影響,可以根據電子裝置的放置位置和面積而使具有一定照射面積的光線可以涵蓋電子裝置,藉此,即使在室內或室外沒有陽光之處,本發明一樣可以穩定地提供光能量並傳輸至電子裝置以產生電力,供電子裝置使用,或對電子裝置進行充電。As mentioned above, in the light energy transmission device of the present invention, the lens module and the light transmission module are arranged correspondingly, the lens module is arranged between the light transmission module and the electronic device, and the light emitted by the light transmission module Passing through the lens module and illuminating the electronic device; and, the control module is connected to the light transmission module and the lens module, and can change the light output pattern and illumination of the light passing through the lens module according to the placement position and area of the electronic device. area, so that the light with a certain irradiation area can at least cover the design of the electronic device, so that the invention is not affected by climate, day and night, and the light with a certain irradiation area can cover the electronic device according to the placement position and area of the electronic device. Therefore, even if there is no sunlight indoors or outdoors, the present invention can stably provide light energy and transmit it to electronic devices to generate electricity for use by electronic devices or to charge electronic devices.
以下將參照相關圖式,說明依本發明一些實施例之光能量傳輸裝置,其中相同的元件將以相同的參照符號加以說明。以下實施例出現的各元件只是用以說明其相對關係,並不代表真實元件的比例或尺寸。The following will describe an optical energy transmission device according to some embodiments of the present invention with reference to the relevant drawings, in which the same components will be described with the same reference symbols. The components appearing in the following embodiments are only used to illustrate their relative relationships and do not represent the proportions or sizes of the actual components.
圖1為本發明一實施例之一種光能量傳輸裝置的功能方塊示意圖。FIG. 1 is a functional block diagram of an optical energy transmission device according to an embodiment of the present invention.
請參考圖1,光能量傳輸裝置1可與至少一電子裝置2配合應用。其中,電子裝置2可包含一光伏模組21,而光能量傳輸裝置1是一種無線的光能量傳輸器,其可傳輸光線能量至電子裝置2,使光伏模組21可產生電能以供電子裝置2使用,或對電子裝置2充電。在一些實施例中,光伏模組21可包含光伏電池(Photovoltaic Cell),例如太陽能電池,照光後可產生電力。在一些實施例中,電子裝置2可包括顯示面板、顯示螢幕(器)或監視攝影機(例如Wi-Fi攝影機)的顯示裝置,或其他需要用電的電子設備。在一些實施例中,電子裝置2例如但不限於為手機、平板電腦、筆記型電腦、電子紙顯示器(E-paper Device, EPD)、監視器、或其他可用於顯示影像的顯示設備。Please refer to FIG. 1 . The optical
在一些實施例中,除了光伏模組21外,電子裝置2還可包含例如電源管理模組及二次電池(未繪示),光伏模組21所產生的電能可經由電源管理模組的管理及控制直接提供給電子裝置2使用(不經由二次電池);或者,光伏模組21所產生的電能可經由電源管理模組的管理、控制並對二次電池充電;又或者,光伏模組21儲存的電力也可經由電源管理模組的管理及控制提供給電子裝置2使用,同時也對二次電池進行充電,視電源管理模組的管理、運作而定。在一些實施例中,二次電池可包含鋰離子電池,其可儲存光伏模組21所產生的電力。在一些實施例中,光伏模組21所產生的電能也可直接提供給電子裝置2使用,不需設置二次電池。In some embodiments, in addition to the
如圖1所示,本實施例之光能量傳輸裝置1可包括一光傳輸模組11、一透鏡模組12以及一控制模組13。As shown in FIG. 1 , the optical
光傳輸模組11可發出不可見光及/或可見光的光線。在一些實施例中,光傳輸模組11可包括紅外線雷射(IR Laser)發射器、紅外線發光二極體(IR LED)、紫外線發光二極體(UV LED)或照明發光二極體、或其組合。其中,紅外線雷射發射器、紅外線發光二極體可發出紅外光(不可見光),紫外線發光二極體可發出紫外光(不可見光)。本實施例的光傳輸模組11是以發出紅外光為例。紅外光的波長範圍可介於840奈米與1800奈米之間(840nm≦波長≦1800nm)。The
透鏡模組12與光傳輸模組11對應設置。在此,透鏡模組12設置於光傳輸模組11與電子裝置2之間,且光傳輸模組11所發出的光線能量可穿過透鏡模組12並照射在電子裝置2(光伏模組21)上,因此,即使在室內或室外沒有陽光之處,光傳輸模組11的光線能量照射在電子裝置2一樣可以持續使光伏模組21產生電力。在一些實施例中,透鏡模組12至少可包括複眼透鏡(Fly-eye Lens)、菲涅耳透鏡(Fresnel lens)、凸透鏡或凹透鏡,或其任意組合,視設計而定。在一些實施例中,光傳輸模組11與透鏡模組12可分別為獨立構件;或者光傳輸模組11與透鏡模組12可整合為單一構件,並可例如安裝於室內的天花板或牆壁上,且發出光線照射在位於例如桌上或牆上的電子裝置2(光伏模組21),以供電子裝置2使用及/或對電子裝置2充電,藉此達到強行傳輸光能量給電子裝置2的目的。The
控制模組13與光傳輸模組11及透鏡模組12連接。控制模組13可用以改變光傳輸模組11及/或透鏡模組12的位置或狀態。其中,控制模組13可依據電子裝置2的放置位置和面積改變穿過透鏡模組12之光線L的出光光型(Light type)與照射面積A,俾使具有照射面積A的光線L可至少涵蓋電子裝置2。在此,光線L的照射面積A為具有一定面積的平面,並不是一個光點。在一些實施例中,可透過控制模組13依據一個或多個電子裝置2的放置位置和面積自動調整光傳輸模組11及/或透鏡模組12的狀態或位置、或依據一個或多個電子裝置2的放置位置和面積自動調整光傳輸模組11中的一個或一些區域的發光元件發光,以提供光能量給一個或多個電子裝置2;在一些實施例中,使用者也可手動透過控制模組13調整光傳輸模組11及/或透鏡模組12的狀態或位置、或調整光傳輸模組11中的一個或一些區域的發光元件發光,以提供光能量給一個或多個電子裝置2,本發明不限制。The
以下,請分別參考圖2A至圖6B的實施例以說明上述技術的詳細內容。其中,圖2A至圖6B分別為本發明之光能量傳輸裝置不同實施例的示意圖。Below, please refer to the embodiments of FIGS. 2A to 6B respectively to describe the details of the above technology. 2A to 6B are schematic diagrams of different embodiments of the optical energy transmission device of the present invention.
如圖2A所示,在本實施例的光能量傳輸裝置1a中,光傳輸模組11可包括設置於基板112上的複數個發光元件111(例如但不限於LED),而透鏡模組12可包括依序排列的兩個單面的複眼透鏡121、122及一個單凸透鏡123。另外,控制模組(未繪示)可與光傳輸模組11電性連接,且控制模組可控制至少一個發光元件111發出光線,而穿過複眼透鏡121、122及單凸透鏡123後的光線L可照射在某一位置的電子裝置2(光伏模組)上。As shown in FIG. 2A , in the light energy transmission device 1a of this embodiment, the
在本實施例中,基板112的這些發光元件111例如可排列成矩陣狀,矩陣狀的發光元件111可區分為多個區域(例如九宮格),每一個區域包含有複數個發光元件111,並且不同區域的發光元件111發出的光線在穿過透鏡模組12後,可以產生不同的出光光型、照射面積和照射位置,而控制模組可根據電子裝置2的放置位置和面積控制至少一個(可一個或大於一個)區域的發光元件111發光,俾使具有照射面積的光線L可涵蓋電子裝置2。In this embodiment, the light-emitting
另外,如圖2B所示,控制模組(未繪示)還可藉由改變光傳輸模組11的傾斜角度θa以改變光傳輸模組11發出光線的出射角度,進而改變穿過透鏡模組12之光線L的出光光型與照射面積以涵蓋位於另一位置的電子裝置2。在一些實施例中,控制模組可透過馬達驅動機構的方式改變光傳輸模組11的傾斜角度θa,進而改變光線L的出光光型與照射面積以涵蓋電子裝置2。In addition, as shown in FIG. 2B , the control module (not shown) can also change the exit angle of the light emitted by the
換句話說,本實施例的光能量傳輸裝置1a可根據電子裝置2放置例如桌面上的位置和電子裝置2的面積,透過控制模組控制至少一個區域的發光元件111發光,俾使具有照射面積的光線L可涵蓋電子裝置2。另外,控制模組還可改變光傳輸模組11的傾斜角度θa以改變光傳輸模組11發出光線的出射角度,讓至少一個區域的發光元件111發出且穿過透鏡模組12之光線L的照射面積可以涵蓋不同位置的電子裝置2,藉此傳輸光能量給電子裝置2。至於控制模組13如何依據電子裝置2放置的位置和面積改變穿過透鏡模組12之光線L的出光光型與照射面積以涵蓋電子裝置2,以下會再說明。In other words, the light energy transmission device 1a of this embodiment can control the light-emitting
另外,如圖3所示,本實施例的光能量傳輸裝置1b與前述的光能量傳輸裝置1a大致相同。與前述光能量傳輸裝置1a主要的不同在於,本實施例之光能量傳輸裝置1b的透鏡模組12包括依序排列的兩個單面的複眼透鏡124、125及一個雙凸透鏡126。另外,光傳輸模組11可包含複數個區域的多個發光元件111設置於基板112上,且控制模組可依據電子裝置2的放置位置和面積控制至少其中一個區域(例如區域Z1)的複數個發光元件111發光,俾使具有照射面積的光線L可涵蓋電子裝置2。In addition, as shown in FIG. 3 , the optical
詳細來說,基板112上設置有多個發光元件111,這些發光元件111例如可排列成矩陣狀,矩陣狀的發光元件111可區分為多個區域(例如九宮格),每一個區域包含有複數個發光元件111,並且不同區域的發光元件111發出的光線在穿過透鏡模組12後,可以產生不同的出光光型、照射面積和照射位置,而控制模組可根據電子裝置2的放置位置和面積控制一個或大於一個區域的發光元件111發光,俾使穿過透鏡模組12之光線L的照射面積可以涵蓋在位於某一位置的電子裝置2。舉例來說,電子裝置2可放在桌上的第一位置,則開啟對應第一位置之區域Z1的發光元件111發光可涵蓋第一區域的電子裝置2;若電子裝置2放在桌上第二位置,則開啟對應第二位置之區域Z2的發光元件111發光可涵蓋第二區域的電子裝置2,以此類推。Specifically, a plurality of light-emitting
另外,如圖4所示,本實施例的光能量傳輸裝置1c與前述的光能量傳輸裝置1b大致相同,與前述光能量傳輸裝置1b主要的不同在於,本實施例的光能量傳輸裝置1c的透鏡模組12包括依序排列的一個雙面的複眼透鏡127及一個雙凸透鏡126。同樣地,控制模組可依據電子裝置2的放置位置和面積控制至少其中一個區域Z1的複數個發光元件111發光,俾使具有照射面積的光線L可涵蓋電子裝置2。In addition, as shown in Figure 4, the optical energy transmission device 1c of this embodiment is substantially the same as the aforementioned optical
另外,如圖5A與圖5B所示,本實施例的光能量傳輸裝置1d與前述的光能量傳輸裝置大致相同,與前述光能量傳輸裝置主要的不同在於,本實施例的光能量傳輸裝置1c的光傳輸模組11包括至少一個發光元件111,且透鏡模組12包括一個菲涅耳透鏡128,而控制模組可依據電子裝置的放置位置和面積改變光傳輸模組11(發光元件111)與透鏡模組12(菲涅耳透鏡128)之間的距離,進而改變穿過透鏡模組12之光線L的出光光型與照射面積以涵蓋電子裝置。在一些實施例中,控制模組可透過馬達驅動機構的方式改變光傳輸模組11與透鏡模組12之間的距離,進而改變光線L的出光光型與照射面積以涵蓋電子裝置。In addition, as shown in FIGS. 5A and 5B , the optical energy transmission device 1d of this embodiment is substantially the same as the aforementioned optical energy transmission device. The main difference from the aforementioned optical energy transmission device is that the optical energy transmission device 1c of this embodiment The
此外,如圖6A與圖6B所示,本實施例的光能量傳輸裝置1e與前述的光能量傳輸裝置大致相同,與前述光能量傳輸裝置主要的不同在於,本實施例的光能量傳輸裝置1e的光傳輸模組、透鏡模組可整合為單一構件,且光能量傳輸裝置1e可安裝於例如天花板C,並可相對天花板C轉動角度。其中,控制模組可改變整體光能量傳輸裝置1e(光傳輸模組與透鏡模組)相對天花板C的傾斜角度θb,進而改變穿過透鏡模組之光線L的出光光型與照射面積A以涵蓋電子裝置2。在一些實施例中,控制模組可透過馬達驅動機構的方式改變光能量傳輸裝置1e相對天花板C的傾斜角度θb,進而改變光線L的出光光型與照射面積以涵蓋電子裝置2。在一些實施例中,控制模組可依據電子裝置2的放置位置和面積控制至少其中一個區域的複數個發光元件111發光,同時還可改變整體光能量傳輸裝置1e(光傳輸模組與透鏡模組)相對天花板C的傾斜角度θb,使具有照射面積的光線L可涵蓋電子裝置2,本發明不限制。In addition, as shown in FIGS. 6A and 6B , the optical energy transmission device 1e of this embodiment is substantially the same as the aforementioned optical energy transmission device. The main difference from the aforementioned optical energy transmission device is that the optical energy transmission device 1e of this embodiment The light transmission module and lens module can be integrated into a single component, and the light energy transmission device 1e can be installed on, for example, the ceiling C, and can rotate relative to the ceiling C. Among them, the control module can change the inclination angle θb of the overall light energy transmission device 1e (light transmission module and lens module) relative to the ceiling C, thereby changing the light emission pattern and illumination area A of the light L passing through the lens module. Covers electronic devices2. In some embodiments, the control module can change the inclination angle θb of the light energy transmission device 1e relative to the ceiling C through a motor drive mechanism, thereby changing the light emission pattern and irradiation area of the light L to cover the
可理解的是,前述圖2A至圖6B的實施例只是舉例,不可用以限制本發明。It should be understood that the aforementioned embodiments in FIGS. 2A to 6B are only examples and cannot be used to limit the present invention.
另外,圖7、圖8及圖9A分別本發明之光能量傳輸裝置的另一功能方塊示意圖,而圖9B為圖9A之光能量傳輸裝置1h的一實施例示意圖。In addition, FIG. 7 , FIG. 8 and FIG. 9A are respectively another functional block diagram of the optical energy transmission device of the present invention, and FIG. 9B is a schematic diagram of an embodiment of the optical
請先參考圖7,為了使前述實施例的控制模組13可以依據電子裝置2的放置位置和面積改變穿過透鏡模組12之光線L的出光光型與照射面積A,本實施例的光能量傳輸裝置1f更可包括一影像擷取模組14,影像擷取模組14與控制模組13電性連接。其中,影像擷取模組14可以擷取及辨識電子裝置2的放置位置和面積並輸出一控制訊號CS,使控制模組13可以依據控制訊號CS改變穿過透鏡模組12之光線L的出光光型與照射面積A,俾使照射面積A涵蓋電子裝置2。在此,影像擷取模組14可為攝影裝置,利用攝影裝置擷取及辨識例如位於桌上的電子裝置2的放置位置和面積後,攝影裝置可輸出控制訊號CS傳送至控制模組13,使控制模組13可以如上述實施例,自動調整及控制以改變穿過透鏡模組12之光線L的出光光型與照射面積A以涵蓋電子裝置2。在一些實施例中,即使桌上有複數個電子裝置2,同樣可以透過影像擷取模組14分別擷取及辨識出每一個電子裝置2的放置位置與面積,再藉由控制模組13控制一個或多個區域的發光元件發光以涵蓋這些不同位置的電子裝置2,使光能量傳輸裝置1可同時傳輸光能量給複數個電子裝置2。Please refer to FIG. 7 first. In order to enable the
另外,如圖8所示,本實施例與前述的光能量傳輸裝置1大致相同,與前述光能量傳輸裝置1主要的不同在於,本實施例之光能量傳輸裝置1g更可包括一定位模組15。其中,定位模組15發出光線標示出例如位於桌上之電子裝置2的放置位置與面積後,控制模組13可依據定位模組15標示出的放置位置與面積改變穿過透鏡模組12之光線L的出光光型與照射面積A,俾使具有照射面積A的光線L可涵蓋電子裝置2。在一些實施例中,定位模組15為可見光(例如紅光)雷射***或不可見光(例如紅外線)雷射***,並不限制。In addition, as shown in Figure 8, this embodiment is substantially the same as the aforementioned optical
此外,如圖9A所示,本實施例與前述的光能量傳輸裝置1大致相同,與前述光能量傳輸裝置1主要的不同在於,本實施例之光能量傳輸裝置1h更可包括一照明模組16,照明模組16可提供照明光線,並與光傳輸模組11及透鏡模組12整合成單一構件。如圖9B所示,本實施例的光能量傳輸裝置1h為一照明裝置,並可更包括照明模組16及燈罩17。照明模組16例如可為燈泡,並發出可見光以提供照明,而光傳輸模組11與透鏡模組12則設置於照明模組16的內部,亦即光傳輸模組11、透鏡模組12及照明模組16整合成單一構件。因此,即使沒有開啟照明模組16,光傳輸模組11及透鏡模組12仍可提供穩定的光能量照射在電子裝置2上。In addition, as shown in FIG. 9A , this embodiment is substantially the same as the aforementioned light
在不同的實施例中,光傳輸模組11及透鏡模組12也可設置於照明模組16旁邊、或設置於燈罩17上;在不同的實施例中,照明模組16可包括一燈管(未繪示),整合於單一構件的光傳輸模組11及透鏡模組12可設置於燈管的內部、設置於燈罩或設置於燈管的旁邊,本發明皆不限制。可理解的是,前述的影像擷取模組14或定位模組15也可應用於本實施例之光能量傳輸裝置1h中。In different embodiments, the
圖10為本發明之光能量傳輸裝置的一實施例應用示意圖。Figure 10 is an application schematic diagram of an embodiment of the optical energy transmission device of the present invention.
在一應用例中,本發明的光能量傳輸裝置可應用於例如智慧平安符。例如圖10所示,智慧平安符3可例如具有光伏電池的小型電子紙顯示裝置(EPD)。其中,智慧平安符3的正面可具有電子紙顯示器31,其可顯示祈福祝賀詞(例如好運平安、業績長紅、長命百歲、…),智慧平安符3的背面具有光伏模組32,而光能量傳輸裝置4可設置於神壇或廟宇的牆壁上。在使用者拿取智慧平安符3在神壇或廟宇祈福、或是繞過多次香爐的同時,透過光能量傳輸裝置4發出的光線L可對智慧平安符3背面的光伏模組32進行充電,讓智慧平安符3的正面可自動更新祈福祝賀詞。因此,可以一個光能量傳輸裝置4對多個智慧平安符3同時供電,讓每一個智慧平安符3背面的光伏模組32都能產生光電流以更新祈福祝賀詞。相對於現有利用有線或無線方式對電子裝置充電來說,應用本實施例之光能量傳輸裝置4進行充電的實用性與便利性可以大大地提高。在此,光能量傳輸裝置4可為前述實施例之光能量傳輸裝置1, 1a~1h的其中之一,或其組合,並不限定。In an application example, the light energy transmission device of the present invention can be applied to, for example, a smart peace charm. For example, as shown in FIG. 10 , the
在另一應用例中,本發明的光能量傳輸裝置也可應用於例如電子貨架標籤(Electronic Shelf Label,ESL),透過光能量傳輸裝置發出的光線照射位於貨架上與電子紙顯示器電性連接的光伏模組,使光伏模組可產生電力提供給電子紙顯示器使用,藉此達到省電及減少電池污染環境的問題。In another application example, the light energy transmission device of the present invention can also be applied to, for example, an electronic shelf label (ESL). The light emitted by the light energy transmission device irradiates a device located on the shelf that is electrically connected to the electronic paper display. Photovoltaic modules can generate electricity for use in e-paper displays, thereby saving power and reducing battery pollution to the environment.
上述的實施例應用例只是舉例,不可用以限制本發明。The above-mentioned embodiment application examples are only examples and cannot be used to limit the present invention.
綜上所述,在本發明的光能量傳輸裝置中,透過透鏡模組與光傳輸模組對應設置,透鏡模組設置於光傳輸模組與電子裝置之間,且光傳輸模組發出的光線穿過透鏡模組並照射電子裝置;以及,控制模組與光傳輸模組及透鏡模組連接,並可依據電子裝置的放置位置和面積改變穿過透鏡模組之光線的出光光型與照射面積,俾使具有照射面積的光線至少涵蓋電子裝置的設計,使本發明不受氣候、晝夜的影響,可以根據電子裝置放置的位置和面積而使具有一定照射面積的光線可以涵蓋電子裝置,藉此,即使在室內或室外沒有陽光之處,本發明一樣可以穩定地提供光能量並傳輸至電子裝置以產生電力,供電子裝置使用,或對電子裝置進行充電。To sum up, in the optical energy transmission device of the present invention, the lens module and the optical transmission module are arranged correspondingly, the lens module is arranged between the optical transmission module and the electronic device, and the light emitted by the optical transmission module Passing through the lens module and illuminating the electronic device; and, the control module is connected to the light transmission module and the lens module, and can change the light output pattern and illumination of the light passing through the lens module according to the placement position and area of the electronic device. area, so that the light with a certain irradiation area can at least cover the design of the electronic device, so that the invention is not affected by climate, day and night, and the light with a certain irradiation area can cover the electronic device according to the location and area of the electronic device. Therefore, even if there is no sunlight indoors or outdoors, the present invention can stably provide light energy and transmit it to electronic devices to generate electricity for use by electronic devices or to charge electronic devices.
以上所述僅為舉例性,而非為限制性者。任何未脫離本發明之精神與範疇,而對其進行之等效修改或變更,均應包含於後附之申請專利範圍中。The above is only illustrative and not restrictive. Any equivalent modifications or changes that do not depart from the spirit and scope of the present invention shall be included in the appended patent scope.
1,1a~1h,4:光能量傳輸裝置1,1a~1h,4: Optical energy transmission device
11:光傳輸模組11: Optical transmission module
111:發光元件111:Light-emitting component
112:基板112:Substrate
12:透鏡模組12: Lens module
121,122,124,125,127:複眼透鏡121,122,124,125,127: compound eye lens
123:單凸透鏡123: Single convex lens
126:雙凸透鏡126: Biconvex lens
128:菲涅耳透鏡128: Fresnel lens
13:控制模組13:Control module
14:影像擷取模組14:Image capture module
15:定位模組15: Positioning module
16:照明模組16:Lighting module
17:燈罩17:Lampshade
2:電子裝置2: Electronic devices
21,32:光伏模組21,32: Photovoltaic module
3:智慧平安符3: Wisdom and Peace Talisman
31:電子紙顯示器31: E-paper display
A:照射面積A:Irradiation area
C:天花板C:ceiling
CS:控制訊號CS: control signal
L:光線L:Light
Z1:區域Z1:Zone
θa,θb:角度θa, θb: angle
圖1為本發明一實施例之一種光能量傳輸裝置的功能方塊示意圖。 圖2A至圖6B分別為本發明之光能量傳輸裝置不同實施例的示意圖。 圖7、圖8及圖9A分別本發明之光能量傳輸裝置的另一功能方塊示意圖。 圖9B為圖9A之光能量傳輸裝置的一實施例示意圖。 圖10為本發明之光能量傳輸裝置的一實施例應用示意圖。 FIG. 1 is a functional block diagram of an optical energy transmission device according to an embodiment of the present invention. 2A to 6B are schematic diagrams of different embodiments of the optical energy transmission device of the present invention. FIG. 7 , FIG. 8 and FIG. 9A are respectively another functional block diagram of the optical energy transmission device of the present invention. FIG. 9B is a schematic diagram of an embodiment of the optical energy transmission device of FIG. 9A. Figure 10 is an application schematic diagram of an embodiment of the optical energy transmission device of the present invention.
1:光能量傳輸裝置 1: Light energy transmission device
11:光傳輸模組 11: Optical transmission module
12:透鏡模組 12: Lens module
13:控制模組 13:Control module
2:電子裝置 2: Electronic devices
21:光伏模組 21: Photovoltaic module
A:照射面積 A:Irradiation area
L:光線 L:Light
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