本創作之一目的,提供一種一第一無線信號收發模組及一風扇設置在一機板經由該機板供電,且機板的信號通過該第一無線信號收發模組以無線的方式輸出給該風扇,及以無線的方式接收該風扇的一風扇資訊的風扇無線訊號傳輸系統。 本創作之一目的,提供一種減少單一風扇的排線的線量,進而減少系統空間內流動氣體受到干擾的風扇無線訊號傳輸系統。 本創作之一目的,減少機板上的連接風扇的連接器的端子孔,以使該連接器的體積變小進而增加機板上的佈線區域的風扇無線訊號傳輸系統。 本創作之一目的,提供一種機板以無線方式控制機板上的至少一風扇,並以無線的方式接收該至少一風扇回傳的風扇資訊的風扇無線訊號傳輸系統。 本創作之一目的,提供一種風扇無線訊號傳輸系統具有一第一無線信號傳輸模組可以插接或固定在一機板上以控制該機板上的至少一風扇。 本創作之一目的,提供一種風扇無線訊號傳輸系統具有一機板利用紅外線或射頻或藍牙或Zigbee或NFC或WiF或5G的傳輸協定跟該機板上的至少一風扇無線傳輸溝通。 為達成上述之目的,本創作提供一種風扇無線訊號傳輸系統,包括:一機板,包含一機板輸出端、一機板輸入端、一機板電源端及一機板接地端;一第一無線信號收發模組,連接該機板輸出端、該機板輸入端、該機板電源端及該機板接地端,且該經由該機板輸出端接收該機板的一輸出信號,並根據該輸出信號產生一無線控制信號;至少一風扇,連接該機板的該電源端及該接地端,且具有一第二無線信號收發模組接收該無線控制信號,且該風扇通過該第二無線信號收發模組以無線的方式回傳一風扇資訊;其中該第一無線信號收發模組以無線的方式接收該風扇資訊,並通過該機板輸入端回傳該風扇資訊至該機板。 本創作另外提供一種風扇無線訊號傳輸系統,包括:一機板,包含一輸出端、一輸入端、一電源端及一接地端;一第一無線信號收發模組,連接該機板的輸出端、輸入端、該電源端及接地端,且該第一無線信號收發模組經由該機板的輸出端接收該機板的一輸出信號,並根據該輸出信號以無線方式傳送一無線控制信號;複數風扇,係連接一第二無線信號收發模組,且每一風扇具有一風扇電源端及一風扇接地端連接該機板的電源端及接地端,該等風扇分別通過該第二無線信號收發模組以無線的方式接收該無線控制信號,且分別通過該第二無線信號收發模組以無線的方式回傳一風扇資訊;其中該第一無線信號收發模組以無線的方式接收該等風扇資訊,並通過該機板的輸入端回傳該等風扇資訊至該機板。 上述機板包含一機板控制單元產生該輸出信號。 上述第一無線信號收發模組具有一第一處理器及一第一無線收發元件,該第一無線收發元件係以無線方式輸出該無線控制信號,並以無線方式接收該風扇資訊。 上述風扇具有一風扇控制單元連接一風扇馬達,該第二無線信號收發模組連接該風扇控制單元。 上述第一無線信號收發模組及該風扇經由該機板電源端供電。 上述複數風扇中的每一風扇分別具有一風扇控制單元連接一風扇馬達,該第二無線信號模組連接該等風扇控制單元,且該第二無線信號收發模組包括一第二處理器連接一第二無線收發元件。 上述第一無線信號收發模組及該等風扇經由該機板電源端供電。 上述機板及該第一無線信號收發模組係為個別獨立的單體,且該機板具有一第一連接器,該第一無線信號收發模組具有一第二連接器連接該第一連接器。 上述第一無線信號收發模組係固定在該機板上。 上述該第一無線信號收發模組及該第二無線信號收發模組係為紅外線模組或射頻模組或藍牙模組或Zigbee模組或NFC模組或WiFi模組或超音波模組或RFID模組或5G模組。An object of the present invention is to provide a first wireless signal transceiver module and a fan disposed on a board via the board, and the signal of the board is wirelessly outputted through the first wireless signal transceiver module. The fan and a fan wireless signal transmission system that wirelessly receives a fan information of the fan. One of the aims of the present invention is to provide a fan wireless signal transmission system that reduces the amount of wire of a single fan and thereby reduces the interference of flowing gas in the system space. One of the purposes of this creation is to reduce the terminal hole of the connector of the fan connected to the board, so that the size of the connector is reduced to increase the fan wireless signal transmission system of the wiring area on the board. One of the purposes of the present invention is to provide a fan wireless signal transmission system in which a board wirelessly controls at least one fan on the board and wirelessly receives the fan information of the at least one fan back. One of the purposes of the present invention is to provide a fan wireless signal transmission system having a first wireless signal transmission module that can be plugged or fixed on a board to control at least one fan on the board. One of the purposes of this creation is to provide a fan wireless signal transmission system having a board that communicates with at least one fan wirelessly on the board using infrared or radio frequency or Bluetooth or Zigbee or NFC or WiF or 5G transmission protocols. In order to achieve the above purpose, the present invention provides a fan wireless signal transmission system, comprising: a board comprising a board output end, a board input end, a board power end and a board ground end; a wireless signal transceiver module, connected to the output end of the board, the input end of the board, the power end of the board, and the ground end of the board, and the output end of the board receives an output signal of the board, and according to The output signal generates a wireless control signal; at least one fan is connected to the power end of the board and the ground end, and has a second wireless signal transceiver module receiving the wireless control signal, and the fan passes the second wireless The signal transceiver module wirelessly transmits a fan information; wherein the first wireless signal transceiver module wirelessly receives the fan information, and returns the fan information to the board through the input end of the board. The present invention further provides a fan wireless signal transmission system, comprising: a board comprising an output end, an input end, a power end and a ground end; a first wireless signal transceiving module connected to the output end of the board The input end, the power end and the ground end, and the first wireless signal transceiver module receives an output signal of the board through an output end of the board, and wirelessly transmits a wireless control signal according to the output signal; The plurality of fans are connected to a second wireless signal transceiver module, and each fan has a fan power terminal and a fan ground terminal connected to the power terminal and the ground terminal of the board, and the fans respectively transmit and receive through the second wireless signal The module wirelessly receives the wireless control signal, and wirelessly transmits a fan information through the second wireless signal transceiver module, wherein the first wireless signal transceiver module wirelessly receives the fans Information and return the fan information to the board through the input of the board. The board includes a board control unit to generate the output signal. The first wireless signal transceiver module has a first processor and a first wireless transceiver component. The first wireless transceiver component wirelessly outputs the wireless control signal and wirelessly receives the fan information. The fan has a fan control unit connected to a fan motor, and the second wireless signal transceiver module is connected to the fan control unit. The first wireless signal transceiver module and the fan are powered by the power supply end of the board. Each of the plurality of fans has a fan control unit connected to a fan motor, the second wireless signal module is connected to the fan control unit, and the second wireless signal transceiver module includes a second processor. The second wireless transceiver component. The first wireless signal transceiver module and the fans are powered by the power supply end of the board. The first wireless signal transceiver module has a first connector, and the first wireless signal transceiver module has a second connector connected to the first connection. The first wireless signal transceiver module has a first connector. Device. The first wireless signal transceiver module is fixed on the board. The first wireless signal transceiver module and the second wireless signal transceiver module are an infrared module or a radio frequency module or a bluetooth module or a Zigbee module or an NFC module or a WiFi module or an ultrasonic module or an RFID. Module or 5G module.
本創作之上述目的及其結構與功能上的特性,將依據所附圖式之較佳實施例予以說明。以下在不同的實施有相同的元件符號表示相同的元件,不同的元件符號則以不同的元件。 請參第1圖係為本創作機板示意圖;第2圖係為本創作方塊示意圖;第3圖係為本創作第二無線信號收發模組方塊示意圖。如圖所示,本創作包括一機板11其上設置一第一無線信號收發模組12及至少一風扇13。該機板11包含一輸出端111、一輸入端112、一電源端113及一接地端114。該第一無線信號收發模組12連接該機板11的輸出端111、輸入端112、該電源端113及接地端114。該風扇13連接該機板11的電源端113及接地端114。且該第一無線信號收發模組12及該風扇13通過該機板11的電源端113供電。 該機板11包括一機板控制單元115產生一輸出信號從該輸出端111輸出至該第一無線信號收發模組12,該輸出信號例如一PWM驅動信號或一轉速調整信號。 該第一無線信號收發模組12具有一第一處理器121及一第一無線收發元件122,該第一無線信號收發模組12從該機板11輸出端111接收到該輸出信號後,該第一處理器121接收到該輸出信號後通過該第一無線信號收發元件122以無線的方式輸出一無線控制信號,該無線控制信號係為該PWM驅動信號或該轉速調整信號。 該風扇13具有一風扇電源端1301及一風扇接地端1302分別連接該機板11的電源端113及接地端114以獲取電源,且具有一風扇控制單元131分別連接一第二無線信號收發模組132及一風扇馬達133。該風扇控制單元131通過該第二無線信號收發模組132接收該無線控制信號,並根據該無線控制信號控制該風扇13運作。例如該無線控制信號為PWM驅動信號,則該風扇控制單元131控制該風扇馬達133運轉。另外若該無線控制信號為轉速調整信號則該風扇控制單元131調整該風扇馬達133的轉速。 再者,該風扇13也能通過該第二無線信號收發模組132以無線的方式回傳一風扇資訊,該風扇資訊例如一風扇轉速信號(FG)或一風扇故障信號,且該風扇資訊由該風扇控制單元131產生然後通過該第二無線信號收發模組132傳送給該第一無線信號收發模組12。該第二無線信號收發模組132包括一第二處理器1321連接一第二無線收發元件1322,該第二無線收發元件1322接收到該無線控制信號後傳送至該第二處理器1321。再者,該第二處理器1321產生該風扇資訊通過該第二無線收發元件1322以無線方式傳送出去。 前述的第一無線信號收發模組12的第一無線收發元件122以無線的方式接收到該風扇資訊後,該第一無線信號收發模組12的第一處理器121將該風扇資訊傳送給該機板11,然後該機板11的機板控制單元115通過該輸入端112接收到該風扇資訊,進而得知風扇13的狀態。 為了使更清楚瞭解機板11與第一無線信號收發模組12及該風扇13之間的運作關係,以下舉例說明: 當該機板11要驅動該風扇13運轉時,機板11通過該第一無線信號收發模組12以無線的方式傳送一PWM驅動信號,該風扇13的第二無線信號收發模組132以無線的方式接收到該PWM驅動信號後,該風扇控制單元131通過該第二無線信號收發模組132接收到該PWM驅動信號,然後驅動該風扇馬達133運轉。再者,該風扇馬達133運轉後,該風扇控制單元131會根據該風扇馬達133的轉速產生一風扇轉速信號(FG),且該風扇控制單元131通過該第二無線信號收發模組132以無線方式回傳該風扇轉速信號(FG)至該第一無線信號收發模組12。該第一無線信號收發模組12的第一處理器121通過該第一無線收發元件122接收到該風扇轉速信號(FG)後,將該風扇轉速信號(FG)傳回給機板11,該機板11的機板控制單元115通過該輸入端112接收該風扇轉速信號(FG)藉此得知風扇13的運轉狀態。 請繼續參考第4A圖係為機板設有第一連接器之方塊示意圖;第4B圖係為第一無線信號收發模組設有第二連接器之方塊示意圖。如圖所示,前述的機板11及該第一無線信號收發模組12係為個別獨立的單體,該機板11具有一第一連接器116(例如公端子)(如第4A圖),該第一無線信號收發模組具有一第二連接器123(例如母端子)(如第4B圖)對應連接該第一連接器116。因此,該第一無線信號收發模組12以可以活動的插接在該機板11上或者從該機板11上拔除。在一替代實施,該第一無線信號收發模組12也可以直接固定在該機板11上,例如以焊錫接著在該機板11上。 請繼續參考第5圖係為本創作機板設有複數風扇之方塊示意圖。如圖所示,機板11上也可以設置複數風扇13,每一風扇13具有一風扇電源端1301及一風扇接地端1302分別連接該機板11的電源端113及接地端114以獲取電源,該機板11透過該第一無線信號收發模組12傳送無線控制信號至每一風扇13,而該等風扇13通過自己的第二無線信號收發模組132分別回傳一風扇資訊至該機板11,該機板11則通過該第一無線信號收發模組12接收每一風扇13回傳的風扇資訊,得知每一風扇13的運轉狀態。 請再參考第6A圖係為本創作另一實施之方塊示意圖。本實施跟前面實施的差異在於機板11上設置複數風扇23a、23b、23c,每一風扇23a、23b、23c具有一風扇電源端2301a、2301b、2301c及一風扇接地端2302a、2302b、2302c分別連接該機板11的電源端113及接地端114,且該複數風扇23a、23b、23c連接單一個第二無線信號收發模組132以分別通過該第二無線信號收發模組132以無線的方式接收該無線控制信號,且分別通過該第二無線信號收發模組132以無線的方式回傳一風扇資訊。而該第一無線信號收發模組12以無線的方式接收該等風扇23a、23b、23c的風扇資訊,並通過該機板11的輸入端112回傳該等風扇資訊至該機板11。 再者,如第6B圖所示,以風扇23a的作為說明,其他的風扇23b、23c的方塊圖跟風扇23a相同。該風扇23a包括風扇控制單元231及風扇馬達233,該單一個第二無線信號收發模組132則電性連接到每一風扇23a、23b、23c的風扇控制單元231。 要說明的是,前述各實施的第一無線信號收發模組12及第二無線信號收發模組132係同時為紅外線模組或射頻模組或藍牙模組或Zigbee模組或NFC模組或WiFi模組或5G模組或超音波模組或RFID模組。例如當該第一無線信號收發模組12及第二無線信號收發模組132為紅外線模組時,則匹此傳送或接收紅外線信號。以此類推,若為射頻模組時則傳送或接收射頻信號;若為藍牙模組時則傳送或接收藍牙信號;若為Zigbee模組時則傳送或接收Zigbee信號;若為NFC模組則傳送或接收NFC信號;若為WiFi模組則傳送或接收WiFi信號;若為5G模組則傳送或接收5G信號;若為或超音波模組則傳送或接收超音波信號;若為RFID模組則傳送或接收RFID信號。 藉由以上的實施,本創作的第一無線信號收發模組12及至少一風扇13、23a、23b、23c設置在一機板11上經由該機板11供電,且該機板11通過該第一無線信號收發模組12以無線的方式輸出控制信號給該風扇13、23a、23b、23c,且通過該第一無線信號收發模組12以無線的方式接收該風扇13、23a、23b、23c回傳的一風扇資訊。此外,藉由個別風扇13、23a、23b、23c僅通過風扇電源端1301、2301a、2301b、2301c及風扇接地端1302、2302a、2302b、2302c連接該機板11的電源端113及接地端114,因此本創作減少習知風扇還有風扇驅動線及風扇轉速回傳線連接機板的特徵,進而減少風扇13、23a、23b、23c的排線的線量,並降低系統空間內(例如主機的機箱內)流動氣體受到干擾,還能減少機板11上的連接風扇的連接器的端子孔,以使該連接器的體積變小進而增加機板11上的電路佈線區域。 以上已將本創作做一詳細說明,惟以上所述者,僅為本創作之一較佳實施例而已,當不能限定本創作實施之範圍。即凡依本創作申請範圍所作之均等變化與修飾等,皆應仍屬本創作之專利涵蓋範圍。The above object of the present invention, as well as its structural and functional features, will be described in accordance with the preferred embodiments of the drawings. In the following embodiments, the same component symbols denote the same components, and different component symbols have different components. Please refer to the first figure for the schematic diagram of the creation machine board; the second picture is the schematic diagram of the creation block; the third picture is the block diagram of the second wireless signal transceiver module. As shown in the figure, the present invention includes a board 11 on which a first wireless signal transceiver module 12 and at least one fan 13 are disposed. The board 11 includes an output end 111, an input end 112, a power end 113, and a ground end 114. The first wireless signal transceiver module 12 is connected to the output end 111 of the board 11 , the input end 112 , the power end 113 , and the ground end 114 . The fan 13 is connected to the power end 113 and the ground end 114 of the board 11. The first wireless signal transceiver module 12 and the fan 13 are powered by the power terminal 113 of the board 11 . The board 11 includes a board control unit 115 for generating an output signal from the output terminal 111 to the first wireless signal transceiver module 12, and the output signal is, for example, a PWM drive signal or a speed adjustment signal. The first wireless signal transceiver module 12 has a first processor 121 and a first wireless transceiver component 122. After the first wireless signal transceiver module 12 receives the output signal from the output terminal 111 of the board 11, the After receiving the output signal, the first processor 121 wirelessly outputs a wireless control signal through the first wireless signal transceiving component 122, and the wireless control signal is the PWM driving signal or the rotational speed adjustment signal. The fan 13 has a fan power supply end 1301 and a fan ground end 1302 respectively connected to the power end 113 and the ground end 114 of the board 11 for power supply, and has a fan control unit 131 connected to a second wireless signal transceiver module. 132 and a fan motor 133. The fan control unit 131 receives the wireless control signal through the second wireless signal transceiver module 132, and controls the operation of the fan 13 according to the wireless control signal. For example, if the wireless control signal is a PWM drive signal, the fan control unit 131 controls the fan motor 133 to operate. In addition, the fan control unit 131 adjusts the rotational speed of the fan motor 133 if the wireless control signal is a rotational speed adjustment signal. In addition, the fan 13 can also transmit a fan information in a wireless manner through the second wireless signal transceiver module 132. The fan information is, for example, a fan speed signal (FG) or a fan fault signal, and the fan information is The fan control unit 131 is generated and then transmitted to the first wireless signal transceiver module 12 through the second wireless signal transceiver module 132. The second wireless signal transceiver module 132 includes a second processor 1321 coupled to a second wireless transceiver component 1322. The second wireless transceiver component 1322 receives the wireless control signal and transmits the wireless control signal to the second processor 1321. Moreover, the second processor 1321 generates the fan information to be wirelessly transmitted through the second wireless transceiver component 1322. After the first wireless transceiver component 122 of the first wireless signal transceiver module 12 receives the fan information in a wireless manner, the first processor 121 of the first wireless signal transceiver module 12 transmits the fan information to the The board 11 and then the board control unit 115 of the board 11 receives the fan information through the input terminal 112, thereby knowing the state of the fan 13. In order to better understand the operational relationship between the board 11 and the first wireless signal transceiver module 12 and the fan 13, the following example is illustrated: When the board 11 is to drive the fan 13 to operate, the board 11 passes the first A wireless signal transceiver module 12 wirelessly transmits a PWM driving signal. After the second wireless signal transceiver module 132 of the fan 13 receives the PWM driving signal in a wireless manner, the fan control unit 131 passes the second The wireless signal transceiver module 132 receives the PWM drive signal and then drives the fan motor 133 to operate. After the fan motor 133 is operated, the fan control unit 131 generates a fan speed signal (FG) according to the rotation speed of the fan motor 133, and the fan control unit 131 wirelessly passes the second wireless signal transceiver module 132. The method returns the fan speed signal (FG) to the first wireless signal transceiver module 12. The first processor 121 of the first wireless signal transceiver module 12 receives the fan speed signal (FG) through the first wireless transceiver component 122, and transmits the fan speed signal (FG) to the board 11, which The board control unit 115 of the board 11 receives the fan speed signal (FG) through the input terminal 112 to thereby know the operating state of the fan 13. Please refer to FIG. 4A for a block diagram of the first connector of the board. FIG. 4B is a block diagram of the second connector for the first wireless signal transceiver module. As shown in the figure, the aforementioned board 11 and the first wireless signal transceiver module 12 are individually independent units, and the board 11 has a first connector 116 (for example, a male terminal) (as shown in FIG. 4A). The first wireless signal transceiver module has a second connector 123 (eg, a female terminal) (such as FIG. 4B) correspondingly connected to the first connector 116. Therefore, the first wireless signal transceiver module 12 is movably inserted on the board 11 or removed from the board 11. In an alternative implementation, the first wireless signal transceiver module 12 can also be directly fixed to the board 11, for example, soldered on the board 11. Please continue to refer to Figure 5 for a block diagram of a complex fan with a plurality of fans. As shown in the figure, a plurality of fans 13 may be disposed on the board 11, and each of the fans 13 has a fan power terminal 1301 and a fan ground terminal 1302 connected to the power terminal 113 and the ground terminal 114 of the board 11 to obtain power. The fan board 11 transmits a wireless control signal to each fan 13 through the first wireless signal transceiver module 12, and the fans 13 respectively transmit a fan information to the board through the second wireless signal transceiver module 132. 11. The board 11 receives the fan information returned by each fan 13 through the first wireless signal transceiver module 12, and knows the operating status of each fan 13. Please refer to FIG. 6A again for a block diagram of another implementation of the present invention. The difference between this embodiment and the previous implementation is that the plurality of fans 23a, 23b, and 23c are disposed on the board 11, and each of the fans 23a, 23b, and 23c has a fan power terminal 2301a, 2301b, and 2301c and a fan ground terminal 2302a, 2302b, and 2302c, respectively. The power terminal 113 and the ground terminal 114 of the board 11 are connected, and the plurality of fans 23a, 23b, and 23c are connected to the single second wireless signal transceiver module 132 to pass through the second wireless signal transceiver module 132 in a wireless manner. Receiving the wireless control signal, and transmitting a fan information in a wireless manner through the second wireless signal transceiver module 132. The first wireless signal transceiver module 12 wirelessly receives the fan information of the fans 23a, 23b, and 23c, and returns the fan information to the board 11 through the input end 112 of the board 11. Further, as shown in Fig. 6B, the block diagram of the other fans 23b and 23c is the same as that of the fan 23a by the description of the fan 23a. The fan 23a includes a fan control unit 231 and a fan motor 233. The single second wireless signal transceiver module 132 is electrically connected to the fan control unit 231 of each of the fans 23a, 23b, and 23c. It should be noted that the first wireless signal transceiver module 12 and the second wireless signal transceiver module 132 of the foregoing embodiments are both an infrared module or a radio frequency module or a Bluetooth module or a Zigbee module or an NFC module or a WiFi. Module or 5G module or ultrasonic module or RFID module. For example, when the first wireless signal transceiver module 12 and the second wireless signal transceiver module 132 are infrared modules, the infrared signals are transmitted or received. By analogy, if the RF module is used, it transmits or receives RF signals; if it is a Bluetooth module, it transmits or receives Bluetooth signals; if it is a Zigbee module, it transmits or receives Zigbee signals; if it is an NFC module, it transmits Or receive NFC signal; if it is a WiFi module, it transmits or receives a WiFi signal; if it is a 5G module, it transmits or receives a 5G signal; if it is an ultrasonic module, it transmits or receives an ultrasonic signal; if it is an RFID module, Transmit or receive RFID signals. With the above implementation, the first wireless signal transceiver module 12 and the at least one fan 13, 23a, 23b, 23c of the present invention are disposed on a board 11 and powered by the board 11, and the board 11 passes the first A wireless signal transceiver module 12 wirelessly outputs control signals to the fans 13, 23a, 23b, 23c, and wirelessly receives the fans 13, 23a, 23b, 23c through the first wireless signal transceiver module 12 A fan information returned. In addition, the power supply end 113 and the ground end 114 of the board 11 are connected by the fan power supply terminals 1301, 2301a, 2301b, and 2301c and the fan ground terminals 1302, 2302a, 2302b, and 2302c, respectively, by the individual fans 13, 23a, 23b, and 23c. Therefore, the present invention reduces the characteristics of the conventional fan and the fan drive line and the fan speed return line connecting board, thereby reducing the amount of wires of the fans 13, 23a, 23b, 23c and reducing the system space (for example, the chassis of the host) The flowing gas is disturbed, and the terminal hole of the connector connecting the fan on the board 11 can be reduced to make the size of the connector small to increase the circuit wiring area on the board 11. The present invention has been described in detail above, but the above description is only a preferred embodiment of the present invention, and the scope of the present invention cannot be limited. That is, all changes and modifications made in accordance with the scope of this creation application shall remain covered by the patents of this creation.
11‧‧‧機板
111‧‧‧輸出端
112‧‧‧輸入端
113‧‧‧電源端
114‧‧‧接地端
115‧‧‧機板控制單元
116‧‧‧第一連接器
12‧‧‧第一無線信號收發模組
121‧‧‧第一處理器
122‧‧‧第一無線收發元件
123‧‧‧第二連接器
13、23a、23b、23c‧‧‧風扇
1301、2301a、2301b、2301c‧‧‧風扇電源端
1302、2302a、2302b、2302c‧‧‧風扇接地端
131、231‧‧‧風扇控制單元
132‧‧‧第二無線信號收發模組
1321‧‧‧第二處理器
1322‧‧‧第二無線收發元件
133、233‧‧‧風扇馬達11‧‧‧ machine board
111‧‧‧ Output
112‧‧‧ input
113‧‧‧Power terminal
114‧‧‧ Grounding terminal
115‧‧‧Machine Control Unit
116‧‧‧First connector
12‧‧‧First wireless signal transceiver module
121‧‧‧First processor
122‧‧‧First wireless transceiver component
123‧‧‧Second connector
13, 23a, 23b, 23c‧‧‧ fans
1301, 2301a, 2301b, 2301c‧‧‧ fan power supply end
1302, 2302a, 2302b, 2302c‧‧‧ fan ground
131, 231‧‧‧Fan control unit
132‧‧‧Second wireless signal transceiver module
1321‧‧‧second processor
1322‧‧‧Second wireless transceiver components
133, 233‧‧‧fan motor
下列圖式之目的在於使本創作能更容易被理解,於本文中會詳加描述該些圖式,並使其構成具體實施例的一部份。透過本文中之具體實施例並參考相對應的圖式,俾以詳細解說本創作之具體實施例,並用以闡述創作之作用原理。 第1圖係為本創作機板示意圖; 第2圖係為本創作方塊示意圖; 第3圖係為本創作第二無線信號收發模組方塊示意圖; 第4A圖係為機板設有第一連接器之方塊示意圖; 第4B圖係為第一無線信號收發模組設有第二連接器之方塊示意圖; 第5圖係為本創作機板設有複數風扇之方塊示意圖; 第6A圖係為本創作另一實施之方塊示意圖; 第6B圖係為本創作另一實施的風扇方塊示意圖。The following figures are intended to make the present invention easier to understand, and the drawings are described in detail herein and form part of the specific embodiments. Through the specific embodiments herein and with reference to the corresponding drawings, the specific embodiments of the present invention are explained in detail, and the function principle of the creation is explained. The first picture is a schematic diagram of the creation machine board; the second picture is a schematic diagram of the creation block; the third picture is a block diagram of the second wireless signal transceiver module of the creation; the fourth picture is the first connection of the machine board Block diagram of the device; Figure 4B is a block diagram of the second connector for the first wireless signal transceiver module; Figure 5 is a block diagram of the plurality of fans of the creation machine board; A block diagram of another implementation is created; Figure 6B is a schematic diagram of a fan block of another implementation of the present invention.