TWM463466U - Power supplying device - Google Patents
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- TWM463466U TWM463466U TW102209860U TW102209860U TWM463466U TW M463466 U TWM463466 U TW M463466U TW 102209860 U TW102209860 U TW 102209860U TW 102209860 U TW102209860 U TW 102209860U TW M463466 U TWM463466 U TW M463466U
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Abstract
Description
本發明係有關於一種電源供應裝置,尤指一種具有低待機功耗的電源供應裝置。 The present invention relates to a power supply device, and more particularly to a power supply device having low standby power consumption.
配合參閱第一圖,為習知之電源供應裝置之電路方塊圖。電源供應裝置1連接於一交流電源供應器ACP及一電子系統PS,電源供應裝置1接收交流電源供應器ACP輸出的交流電力,並將交流電力進行電能轉換後傳遞至電子系統PS。電源供應裝置1可供操作在正常模式或待機模式(standby mode),其中正常模式操作是指電源供應裝置1必須提供電子系統PS操作時所需的電力,意即在正常模式時,連接於電源供應裝置1的電子系統PS處於開機狀態;反之,待機狀態是指電子系統PS處於關機狀態。 Referring to the first figure, it is a circuit block diagram of a conventional power supply device. The power supply device 1 is connected to an AC power supply ACP and an electronic system PS. The power supply device 1 receives the AC power output by the AC power supply ACP, and converts the AC power to the electronic system PS. The power supply device 1 is operable to operate in a normal mode or a standby mode, wherein the normal mode operation means that the power supply device 1 must provide power required for the operation of the electronic system PS, that is, in the normal mode, connected to the power source. The electronic system PS of the supply device 1 is in a power-on state; otherwise, the standby state means that the electronic system PS is in a power-off state.
電源供應裝置1包含一電磁干擾濾波器10、一整流器11、一主電源轉換器12、一附屬電源轉換器13、一第一控制器14、一第二控制器15、一電源管理器16、一第一光隔離器OC1、一第二光隔離器OC2、一第三光隔離器OC3及一第四光隔離器OC4。 The power supply device 1 includes an electromagnetic interference filter 10, a rectifier 11, a main power converter 12, an auxiliary power converter 13, a first controller 14, a second controller 15, a power manager 16, A first optical isolator OC1, a second optical isolator OC2, a third optical isolator OC3 and a fourth optical isolator OC4.
電磁干擾濾波器10電連接於整流器11,整流器11電連接於主電源轉換器12及附屬電源轉換器13,第一控制器14電連接於整流器11 及主電源轉換器12,第二控制器15電連接於附屬電源轉換器13,電源管理器16電連接於主電源轉換器12及附屬電源轉換器13。 The electromagnetic interference filter 10 is electrically connected to the rectifier 11 , and the rectifier 11 is electrically connected to the main power converter 12 and the auxiliary power converter 13 , and the first controller 14 is electrically connected to the rectifier 11 . And the main power converter 12, the second controller 15 is electrically connected to the auxiliary power converter 13, and the power manager 16 is electrically connected to the main power converter 12 and the auxiliary power converter 13.
第一光隔離器OC1電連接於主電源轉換器12之一第一電源輸出端VA及第一控制器14,第二光隔離器OC2電連接於附屬電源轉換器13之一待機電源輸出端Vsb及第二控制器15,第三光隔離器OC3及第四光隔離器OC4分別電連接於電源管理器16及第一控制器14。第一光隔離器OC1、第二光隔離器OC2、第三光隔離器OC3及第四光隔離器OC4可分別例如為光耦合器。 The first optical isolator OC1 is electrically connected to one of the first power output terminals VA of the main power converter 12 and the first controller 14, and the second optical isolator OC2 is electrically connected to one of the auxiliary power converters 13 for standby power output Vsb. The second controller 15, the third optical isolator OC3 and the fourth optical isolator OC4 are electrically connected to the power manager 16 and the first controller 14, respectively. The first optical isolator OC1, the second optical isolator OC2, the third optical isolator OC3, and the fourth optical isolator OC4 may be, for example, optical couplers.
電源供應裝置1接收交流電源供應器ACP輸出的交流電力。在交流電力輸入電源供應裝置1後,電磁干擾濾波器10先濾除交流電力中的電磁干擾,整流器11用以將電磁干擾濾波器10所輸出的交流電力轉換為直流電力輸出。在整流器11中可以加入功率因素校正(Power Factor Correction)電路110,以降低輸入電流量。 The power supply device 1 receives the AC power output from the AC power supply ACP. After the AC power is input to the power supply device 1, the electromagnetic interference filter 10 first filters out electromagnetic interference in the AC power, and the rectifier 11 converts the AC power output from the electromagnetic interference filter 10 into a DC power output. A Power Factor Correction circuit 110 can be added to the rectifier 11 to reduce the amount of input current.
主電源轉換器12接收整流器11輸出的直流電力,主電源轉換器12接受第一控制器14控制,以改變第一電源輸出端VA及一第二電源輸出端VB輸出之電力。主電源轉換器12為直流/直流轉換器(DC to DC converter),並可例如為LLC諧振式電源轉換器、雙重順向式電源轉換器(Dual Forward Converter)或單一順向式電源轉換器(Single Forward Converter)。附屬電源轉換器13接收整流器11輸出的直流電力,附屬電源轉換器13接受第二控制器15控制,以改變輸出之電力。附屬電源轉換器13可例如為返馳式轉換器(flyback converter)。 The main power converter 12 receives the DC power output from the rectifier 11, and the main power converter 12 is controlled by the first controller 14 to change the power outputted by the first power output VA and a second power output VB. The main power converter 12 is a DC to DC converter and can be, for example, an LLC resonant power converter, a dual forward power converter, or a single forward power converter ( Single Forward Converter). The auxiliary power converter 13 receives the DC power output from the rectifier 11, and the auxiliary power converter 13 is controlled by the second controller 15 to change the output power. The accessory power converter 13 can be, for example, a flyback converter.
主電源轉換器12在正常模式時進行電能轉換以使直流電力轉換為主電力並由第一電源輸出端VA及第二電源輸出端VB輸出,並在待機模式時停止電能轉換並不輸出主電力(意即第一電源輸出端VA及第二電源輸出端VB不輸出電力)。附屬電源轉換器13不論在正常模式或待機模式時均進行電能轉換以使直流電壓轉換為待機電力並由待機電源輸出端Vsb輸出。電源供應裝置1藉由在待機模式時,停止主電源轉換器12輸出電力,可以有效地降低電源轉換裝置1在待機模式的能源消耗,以達到省電的目的。 The main power converter 12 performs power conversion in the normal mode to convert the direct current power into the main power and is output by the first power output terminal VA and the second power output terminal VB, and stops the power conversion in the standby mode and does not output the main power. (meaning that the first power output terminal VA and the second power output terminal VB do not output power). The auxiliary power converter 13 performs electric energy conversion in the normal mode or the standby mode to convert the direct current voltage into standby power and is outputted from the standby power output terminal Vsb. When the power supply device 1 stops the output power of the main power converter 12 in the standby mode, the power consumption of the power conversion device 1 in the standby mode can be effectively reduced to achieve power saving.
然而,電源供應裝置1必須同時包含主電源轉換器12及附屬電源轉換器13,這使得電源供應裝置1的體積大,並且,在正常模式操作下,主電源轉換器12及附屬電源轉換器13必須同時進行電能轉換,導致電源供應裝置1在正常模式操作下的能源消耗增加。 However, the power supply device 1 must include both the main power converter 12 and the auxiliary power converter 13, which makes the power supply device 1 bulky, and, in the normal mode operation, the main power converter 12 and the auxiliary power converter 13 The power conversion must be performed at the same time, resulting in an increase in energy consumption of the power supply device 1 under normal mode operation.
鑒於先前技術所述,本揭示內容之一技術態樣,在於提供一種電源供應裝置,電源供應裝置具有待機低功耗及小型化之特點。 In view of the prior art, one aspect of the present disclosure is to provide a power supply device that has the characteristics of standby low power consumption and miniaturization.
本技術態樣之一實施方式提供一種電源供應裝置,電源供應裝置電連接於一交流電源供應器及一電子系統,電源供應裝置接收交流電源供應器輸出之交流電力,並將交流電力進行電能轉換後輸出至電子系統,電源供應裝置包含一整流器、一電源轉換器、一控制器、一電源管理器及一開關元件。電源轉換器電連接於整流器,電源轉換器包含一第一電源輸出端及一待機電源輸出端,待機電源輸出端電連接於電子系統。控制器電連接於電源轉換器;電源管理器電連接於控制器及電子系統。開關元件電連接於第一 電源輸出端、電源管理器及電子系統,開關元件係依據電源管理器的控制以導通或切斷由第一電源輸出端輸出並傳遞至的電力。 One embodiment of the present technology provides a power supply device electrically connected to an AC power supply and an electronic system. The power supply device receives AC power output by the AC power supply and converts the AC power into the power. After being output to the electronic system, the power supply device comprises a rectifier, a power converter, a controller, a power manager and a switching component. The power converter is electrically connected to the rectifier, and the power converter comprises a first power output and a standby power output, and the standby power output is electrically connected to the electronic system. The controller is electrically connected to the power converter; the power manager is electrically connected to the controller and the electronic system. The switching element is electrically connected to the first The power output, the power manager and the electronic system, the switching element is controlled according to the power manager to turn on or off the power outputted and transmitted by the first power output.
在本技術態樣其他實施方式中,電源轉換器更包含一第二電源輸出端,電連接於開關元件,開關元件係依據電源管理器的控制以導通或切斷由第一電源輸出端及第二電源輸出端輸出並傳遞至電子系統的電力。 In other embodiments of the present technology, the power converter further includes a second power output terminal electrically connected to the switching component, and the switching component is turned on or off according to the control of the power manager by the first power output terminal and the first The power output of the two power outputs is output to the electronic system.
在本技術態樣其他實施方式中,電源供應裝置更包含一第一隔離開關,電連接於第二電源輸出端、待機電源輸出端及控制器,第二電源輸出端、待機電源輸出端輸出的電力通過第一隔離開關傳遞至控制器。 In another embodiment of the technical aspect, the power supply device further includes a first isolation switch electrically connected to the second power output terminal, the standby power output terminal, and the controller, and the second power output terminal and the standby power output terminal output. Power is passed to the controller through the first isolation switch.
在本技術態樣其他實施方式中,電源供應裝置更包含一待機電源轉換器及一直流-直流電源轉換器,待機電源轉換器電連接於待機電源輸出端。直流-直流電源轉換器電連接於第一電源輸出端,直流-直流電源轉換器包含一第二電源輸出端及一第三電源輸出端,第二電源輸出端及第三電源輸出端電連接於開關元件,開關元件依據電源管理器的控制以導通或切換第一電源輸出端、第二電源輸出端及第三電源輸出端輸出的電力。 In other embodiments of the present technology, the power supply device further includes a standby power converter and a DC-DC power converter, and the standby power converter is electrically connected to the standby power output. The DC-DC power converter is electrically connected to the first power output end, the DC-DC power converter includes a second power output end and a third power output end, and the second power output end and the third power output end are electrically connected And a switching element that turns on or switches power outputted by the first power output, the second power output, and the third power output according to a control of the power manager.
在本技術態樣其他實施方式中,電源供應裝置更包含一第一隔離開關,電連接於第一電源輸出端及控制器,第一電源輸出端輸出之電力通過第一隔離開關傳遞至控制器。 In another embodiment of the technical aspect, the power supply device further includes a first isolation switch electrically connected to the first power output terminal and the controller, and the power outputted by the first power output terminal is transmitted to the controller through the first isolation switch. .
在本技術態樣其他實施方式中,電源供應裝置更包含一第二隔離開關及一第三隔離開關,第二隔離開關電連接於電源管理器及控 制器,第二隔離開關將電源管理器發出的保護信號傳遞至控制器。第三隔離開關電連接於電源管理器及控制器,第三隔離開關將控制器發出的控制信號傳遞至電源管理器。 In other embodiments of the present technical aspect, the power supply device further includes a second isolation switch and a third isolation switch, and the second isolation switch is electrically connected to the power manager and the control The second isolation switch transmits a protection signal from the power manager to the controller. The third isolating switch is electrically connected to the power manager and the controller, and the third isolating switch transmits a control signal sent by the controller to the power manager.
在本技術態樣其他實施方式中,電源供應裝置更包含一電磁干擾濾波器,電連接於交流電源供應器及整流器。 In other embodiments of the present technology, the power supply device further includes an electromagnetic interference filter electrically connected to the AC power supply and the rectifier.
在本技術態樣其他實施方式中,其中電源轉換器為直流-直流電源轉換器。 In other embodiments of the present technology, the power converter is a DC-DC power converter.
在本技術態樣其他實施方式中,電源轉換器為LLC諧振式電源轉換器、雙重順向式電源轉換器或單一順向式電源轉換器。 In other embodiments of the present technology, the power converter is an LLC resonant power converter, a dual forward power converter, or a single forward power converter.
在本實施態樣另一實施方式提供一種電源供應裝置,電源供應裝置電連接於一交流電源供應器及一電子系統,電源供應裝置接收交流電源供應器輸出之交流電力,並將交流電力進行電能轉換後輸出至電子系統,電源供應裝置包含一整流器、一電源轉換器、一直流-直流轉換器、一控制器、一電源管理器及一開關元件。電源轉換器電連接於整流器,電源轉換器包含一第一電源輸出端。直流-直流轉換器電連接於第一電源輸出端,直流-直流輸出端包含一第二電源輸出端、一第三電源輸出端及一待機電源輸出端,待機輸出端電連接於電子系統。控制器電連接於電源轉換器。電源管理器電連接於控制器及直流-直流電源轉換器。開關元件電連接於第一電源輸出端、第二電源輸出端、第三電源輸出端、電源管理器及電子系統,開關元件係依據電源管理器的控制以導通或切斷由第一電源輸出端、第二電源輸出端及第三電源輸出端 輸出並傳遞至的電力。 In another embodiment, a power supply device is electrically connected to an AC power supply and an electronic system, and the power supply device receives AC power output by the AC power supply and performs AC power. After being converted, the power supply device includes a rectifier, a power converter, a DC-DC converter, a controller, a power manager, and a switching component. The power converter is electrically connected to the rectifier, and the power converter includes a first power output. The DC-DC converter is electrically connected to the first power output end, and the DC-DC output terminal comprises a second power output end, a third power output end and a standby power output end, and the standby output end is electrically connected to the electronic system. The controller is electrically connected to the power converter. The power manager is electrically connected to the controller and the DC-DC power converter. The switching element is electrically connected to the first power output end, the second power output end, the third power output end, the power manager and the electronic system, and the switching element is turned on or off according to the control of the power manager by the first power output end Second power output and third power output The power that is output and delivered to.
在本技術態樣其他實施方式中,電源供應裝置更包含一第一隔離開關、一第二隔離開關及一第三隔離開關,第一隔離開關電連接於第一電源輸出端及控制器,第一電源輸出端輸出之電力通過第一隔離開關傳遞至控制器。第二隔離開關電連接於電源管理器及控制器,第二隔離開關將電源管理器發出的保護信號傳遞至控制器。第三隔離開關電連接於電源管理器及控制器,第三隔離開關將控制器發出的控制信號傳遞至電源管理器。 In another embodiment of the technical aspect, the power supply device further includes a first isolation switch, a second isolation switch, and a third isolation switch, wherein the first isolation switch is electrically connected to the first power output end and the controller, The power output from a power output is transmitted to the controller through the first isolation switch. The second isolation switch is electrically connected to the power manager and the controller, and the second isolation switch transmits a protection signal from the power manager to the controller. The third isolating switch is electrically connected to the power manager and the controller, and the third isolating switch transmits a control signal sent by the controller to the power manager.
在本技術態樣其他實施方式中,電源供應裝置更包含一電磁干擾濾波器,電連接於交流電源供應器及整流器。 In other embodiments of the present technology, the power supply device further includes an electromagnetic interference filter electrically connected to the AC power supply and the rectifier.
在本技術態樣其他實施方式中,其中電源轉換器為直流-直流電源轉換器。 In other embodiments of the present technology, the power converter is a DC-DC power converter.
在本技術態樣其他實施方式中,電源轉換器為LLC諧振式電源轉換器、雙重順向式電源轉換器或單一順向式電源轉換器。 In other embodiments of the present technology, the power converter is an LLC resonant power converter, a dual forward power converter, or a single forward power converter.
1、2‧‧‧電源供應裝置 1, 2‧‧‧Power supply unit
10、20‧‧‧電磁干擾濾波器 10, 20‧‧ ‧ electromagnetic interference filter
11、22‧‧‧整流器 11, 22‧‧‧Rectifier
12‧‧‧主電源轉換器 12‧‧‧Main power converter
13‧‧‧附屬電源轉換器 13‧‧‧Attach power converter
14‧‧‧第一控制器 14‧‧‧First controller
15‧‧‧第二控制器 15‧‧‧Second controller
16、28‧‧‧電源管理器 16, 28‧‧‧ Power Manager
220‧‧‧功率因素校正電路 220‧‧‧Power factor correction circuit
24‧‧‧電源轉換器 24‧‧‧Power Converter
240‧‧‧整流電路 240‧‧‧Rectifier circuit
242‧‧‧濾波電路 242‧‧‧Filter circuit
26‧‧‧控制器 26‧‧‧ Controller
30‧‧‧開關元件 30‧‧‧Switching elements
32‧‧‧第一隔離開關 32‧‧‧First isolation switch
34‧‧‧第二隔離開關 34‧‧‧Second isolation switch
36‧‧‧第三隔離開關 36‧‧‧The third isolating switch
38‧‧‧直流-直流電源轉換器 38‧‧‧DC-DC Power Converter
40‧‧‧待機電源轉換器 40‧‧‧Standby Power Converter
ACP‧‧‧交流電源供應器 ACP‧‧‧AC power supply
Cr‧‧‧諧振電容器 Cr‧‧‧Resonance Capacitor
C1、C2‧‧‧濾波電容器 C1, C2‧‧‧ filter capacitor
DR、DR1、DR2‧‧‧被動切換元件 DR, DR1, DR2‧‧‧ passive switching components
D1、D2‧‧‧整流二極體 D1, D2‧‧‧ Rectifier
L‧‧‧濾波電感器 L‧‧‧Filter Inductors
Lr‧‧‧諧振電感器 Lr‧‧‧Resonant Inductors
Np‧‧‧一次側繞組 Np‧‧‧ primary winding
Ns‧‧‧二次側繞組 Ns‧‧‧ secondary winding
OC1‧‧‧第一光隔離器 OC1‧‧‧First Optical Isolator
OC2‧‧‧第二光隔離器 OC2‧‧‧Second optical isolator
OC3‧‧‧第三光隔離器 OC3‧‧‧third optical isolator
OC4‧‧‧第四光隔離器 OC4‧‧‧4th optical isolator
PG‧‧‧信號輸出端 PG‧‧‧ signal output
PS‧‧‧電子系統 PS‧‧‧Electronic System
PS-On‧‧‧信號輸入端 PS-On‧‧‧ signal input
Q1、Q2‧‧‧切換元件 Q1, Q2‧‧‧ switching components
S、S1、S2‧‧‧主動切換元件 S, S1, S2‧‧‧ active switching components
T‧‧‧變壓器 T‧‧‧Transformer
VA‧‧‧第一電源輸出端 VA‧‧‧first power output
VB‧‧‧第二電源輸出端 VB‧‧‧second power output
VC‧‧‧第三電源輸出端 VC‧‧‧ third power output
Vsb‧‧‧待機電源輸出端 Vsb‧‧‧Standby power output
第一圖為習知之電源供應裝置之電路方塊圖。 The first figure is a circuit block diagram of a conventional power supply device.
第二圖為本揭示內容第一實施方式之電源供應裝置之電路方塊圖。 The second figure is a circuit block diagram of a power supply device according to a first embodiment of the disclosure.
第三圖為本揭示內容第一實施方式之電源轉換器之電路圖。 The third figure is a circuit diagram of the power converter of the first embodiment of the disclosure.
第四圖為本揭示內容第二實施方式之電源轉換器之電路圖。 The fourth figure is a circuit diagram of a power converter according to a second embodiment of the disclosure.
第五圖為本揭示內容第三實施方示之電源轉換器之電路圖。 Figure 5 is a circuit diagram of a power converter shown in a third embodiment of the disclosure.
第六圖為對應第二圖所示之電源供應裝置運作之一時序圖。 The sixth figure is a timing chart corresponding to the operation of the power supply device shown in the second figure.
第七圖為對應第二圖所示之電源供應裝置運作之另一時序圖。 The seventh figure is another timing chart corresponding to the operation of the power supply device shown in the second figure.
第八圖為本揭示內容第二實施方式之電源供應裝置之電路方塊圖。 Figure 8 is a circuit block diagram of a power supply device according to a second embodiment of the disclosure.
第九圖為本揭示內容第三實施方式之電源供應裝置之電路方塊圖。 Figure 9 is a circuit block diagram of a power supply device according to a third embodiment of the present disclosure.
請參考隨附圖示,本揭示內容之以上及額外目的、特徵及優點將透過下列諸實施方式之以下闡釋性及非限制性詳細描敘予以更好地理解。 The above and other objects, features, and advantages of the present invention will be better understood from the following description and appended claims.
配合參閱第二圖,為本揭示內容第一實施方式之電源供應裝置之電路方塊圖。電源供應裝置2電連接於一交流電源供應器ACP及一電子系統PS,電源供應裝置2接收交流電源供應器ACP輸出的交流電力,並將交流電力進行電能轉換後傳遞至電子系統PS。 Referring to the second figure, a circuit block diagram of a power supply device according to a first embodiment of the disclosure is shown. The power supply device 2 is electrically connected to an AC power supply ACP and an electronic system PS. The power supply device 2 receives the AC power output by the AC power supply ACP, and converts the AC power into electrical energy and transmits the AC power to the electronic system PS.
電源供應裝置2包含一電磁干擾濾波器20、一整流器22、一電源轉換器24、一控制器26、一電源管理器28及一開關元件30。電磁干擾濾波器20電連接於交流電源供應器ACP,電磁干擾濾波器20接收交流電源供應器ACP提供的交流電力,並濾除交流電力中的電磁干擾。 The power supply device 2 includes an electromagnetic interference filter 20, a rectifier 22, a power converter 24, a controller 26, a power manager 28, and a switching element 30. The electromagnetic interference filter 20 is electrically connected to the AC power supply ACP, and the electromagnetic interference filter 20 receives the AC power provided by the AC power supply ACP and filters out electromagnetic interference in the AC power.
整流器22用以將電磁干擾濾波器20所輸出的交流電力轉換為直流電力輸出。在整流器22中可以加入功率因素校正(Power Factor Correction)電路220,以降低輸入電流量。 The rectifier 22 is configured to convert the AC power output by the electromagnetic interference filter 20 into a DC power output. A Power Factor Correction circuit 220 can be added to the rectifier 22 to reduce the amount of input current.
電源轉換器24電連接於整流器22及控制器26,並具有一待機電源 輸出端Vsb、一第一電源輸出端VA及一第二電源輸出端VB。電源轉換器24接收整流器22輸出的直流電力,並接受控制器26控制而改變待機電源輸出端Vsb、第一電源輸出端VA及第二電源輸出端VB輸出之電力的電壓值。 The power converter 24 is electrically connected to the rectifier 22 and the controller 26 and has a standby power supply The output terminal Vsb, a first power output terminal VA and a second power output terminal VB. The power converter 24 receives the DC power output from the rectifier 22 and is controlled by the controller 26 to change the voltage value of the power output from the standby power output terminal Vsb, the first power output terminal VA, and the second power output terminal VB.
電源管理器28電連接於電源轉換器24、控制器26及電子系統PS,電源管理器28通過一信號輸出端PG傳遞信號至電子系統PS,以及通過一信號輸入端PS_On接收電子系統PS發出的信號。 The power manager 28 is electrically connected to the power converter 24, the controller 26 and the electronic system PS. The power manager 28 transmits signals to the electronic system PS through a signal output terminal PG, and receives the electronic system PS through a signal input terminal PS_On. signal.
開關元件30電連接於電源管理器28、第一電源輸出端VA、第二電源輸出端VB及電子系統PS,開關元件30依據電源管理器28送出的開關控制信號以導通或切斷由第一電源輸出端VA及第二電源輸出端VB輸出並傳遞至電子系統PS的電力。 The switching element 30 is electrically connected to the power manager 28, the first power output terminal VA, the second power output terminal VB, and the electronic system PS. The switching component 30 is turned on or off according to the switch control signal sent by the power manager 28. The power output VA and the second power output VB output and transmit power to the electronic system PS.
在此要說明的是:電源轉換器24可例如(但不限定)為直流/直流轉換器(DC to DC converter),並可例如為LLC諧振式電源轉換器(如第三圖所示)、雙重順向式電源轉換器(Dual Forward Converter)(如第四圖所示)或單一順向式電源轉換器(Single Forward Converter)(如第五圖所示)。 It should be noted that the power converter 24 can be, for example but not limited to, a DC to DC converter, and can be, for example, an LLC resonant power converter (as shown in the third figure). A dual forward power converter (as shown in Figure 4) or a single forward power converter (as shown in Figure 5).
配合參閱第三圖,為本揭示內容第一實施方式之電源轉換器之電路圖。第三圖中所示之電源轉換器24為LLC諧振式轉換器,電源轉換器24包含二切換元件Q1及Q2、一諧振電感器Lr、一諧振電容器Cr、一變壓器T、一整流電路240及一濾波電路242。 Referring to the third figure, a circuit diagram of a power converter according to a first embodiment of the disclosure is shown. The power converter 24 shown in the third figure is an LLC resonant converter. The power converter 24 includes two switching elements Q1 and Q2, a resonant inductor Lr, a resonant capacitor Cr, a transformer T, a rectifier circuit 240, and A filter circuit 242.
切換元件Q1、Q2分別電連接於整流器22及控制器26,用以接收整流器22輸出的直流電力,並依據控制器26提供的信號以切換於導 通狀態或截止狀態,並輸出脈動直流信號。在本實施方式中,切換元件Q1、Q2為金屬氧化物半導體場效應電晶體(Metal-Oxide-Semiconductor Field-Effect Transistor,MOSFET),切換元件Q1、Q2的閘級分別電連接於控制器26,切換元件Q1、Q2的汲極與源極之間分別連接有一二極體D,二極體D也可以為切換元件Q1、Q2的寄生二極體。 The switching elements Q1 and Q2 are electrically connected to the rectifier 22 and the controller 26, respectively, for receiving the DC power output by the rectifier 22, and are switched according to the signal provided by the controller 26. The on state or the off state, and outputs a pulsating DC signal. In the present embodiment, the switching elements Q1 and Q2 are Metal-Oxide-Semiconductor Field-Effect Transistors (MOSFETs), and the gates of the switching elements Q1 and Q2 are electrically connected to the controller 26, respectively. A diode D is connected between the drain and the source of the switching elements Q1 and Q2, and the diode D may be a parasitic diode of the switching elements Q1 and Q2.
諧振電感器Lr電連接於切換元件Q1、Q2。於本實施方式中,諧振電感器Lr連接在切換元件Q1的源極及切換元件Q2的汲極之間,以在切換元件Q1、Q2交替導通和截止之時接收脈動直流信號。諧振電容器Cr電連接於諧振電感器Lr及電壓器T的一次側繞組Np,諧振電容器Cr除了用以阻隔脈動直流信號之直流分量外,並與諧振電感器Lr及一次側繞組Np的磁化電感形成諧振電路。於本實施方式中,變壓器T為中心抽頭式變壓器。 The resonant inductor Lr is electrically connected to the switching elements Q1, Q2. In the present embodiment, the resonant inductor Lr is connected between the source of the switching element Q1 and the drain of the switching element Q2 to receive the ripple DC signal when the switching elements Q1, Q2 are alternately turned on and off. The resonant capacitor Cr is electrically connected to the resonant inductor Lr and the primary winding Np of the voltage transformer T. The resonant capacitor Cr is formed to block the DC component of the pulsating DC signal and form a magnetizing inductance with the resonant inductor Lr and the primary winding Np. Resonant circuit. In the present embodiment, the transformer T is a center tap type transformer.
整流電路240包含二整流二極體D1及D2,整流二極體D1及D2分別電連接於變壓器T的二次側繞組Ns,用以將通過變壓器T的交流電力轉換為具高頻脈動成分的直流電力。濾波電路242電連接於整流電路240,濾波電路242可例如(但不限定)為CLC濾波電路,並包含一濾波電感器L及分別連接於濾波電感器L兩端的濾波電容器C1及C2,濾波電路242用以濾除整流二極體D1及D2輸出之直流電力的高頻脈動成分並輸出平穩的直流電。 The rectifier circuit 240 includes two rectifying diodes D1 and D2, and the rectifying diodes D1 and D2 are electrically connected to the secondary winding Ns of the transformer T, respectively, for converting the AC power passing through the transformer T into a component having a high frequency ripple component. DC power. The filter circuit 242 is electrically connected to the rectifier circuit 240. The filter circuit 242 can be, for example but not limited to, a CLC filter circuit, and includes a filter inductor L and filter capacitors C1 and C2 respectively connected to the two ends of the filter inductor L. The filter circuit The 242 is configured to filter out the high frequency ripple component of the DC power output from the rectifier diodes D1 and D2 and output a smooth direct current.
配合參閱第四圖,為本揭示內容第二實施方式之電源轉換器之電路圖。第四圖所示之電源轉換器24為雙重順向式電源轉換器,電源轉換器24包含二主動切換元件S1及S2、二被動切換元件DR1及 DR2、一整流電路240、一濾波電路242及一變壓器T,變壓器T包含一一次側繞組Np及一二次側繞組Ns。 Referring to the fourth figure, a circuit diagram of a power converter according to a second embodiment of the disclosure is shown. The power converter 24 shown in the fourth figure is a dual forward power converter, and the power converter 24 includes two active switching elements S1 and S2, two passive switching elements DR1 and The DR2, a rectifier circuit 240, a filter circuit 242, and a transformer T include a primary side winding Np and a secondary side winding Ns.
主動切換元件S1及S2分別電連接於整流器22及控制器26,用以接收整流器22輸出的直流電力,並依據控制器26提供的信號以切換於導通狀態或截止狀態,並輸出脈動直流信號。在本實施方式中,主動切換元件S1及S2為金屬氧化物半導體場效應電晶體,主動切換元件S1及S2的閘級分別電連接於控制器26,主動切換元件S1及S2的汲極與源極之間分別連接有一二極體D,二極體D也可以為各主動切換元件S1、S2的寄生二極體。 The active switching elements S1 and S2 are electrically connected to the rectifier 22 and the controller 26, respectively, for receiving the DC power output by the rectifier 22, and switching to the on state or the off state according to the signal provided by the controller 26, and outputting the pulsating DC signal. In the present embodiment, the active switching elements S1 and S2 are metal oxide semiconductor field effect transistors, and the gate stages of the active switching elements S1 and S2 are electrically connected to the controller 26, respectively, and actively switch the drains and sources of the elements S1 and S2. A diode D is connected between the poles, and the diode D can also be a parasitic diode of each of the active switching elements S1 and S2.
被動切換元件DR1跨接於主動切換元件S1與一次側繞組Np,被動切換元件DR2跨接於主動切換元件S2及一次側繞組Np。在本實施方式中,被動切換元件DR1及DR2分別為二極體。 The passive switching element DR1 is connected across the active switching element S1 and the primary side winding Np, and the passive switching element DR2 is connected across the active switching element S2 and the primary side winding Np. In the present embodiment, the passive switching elements DR1 and DR2 are diodes, respectively.
整流電路240由二極體D1及D2組成並電連接於二次側繞組Ns,用以將通過變壓器T的交流電力轉換為具高頻脈動成分的直流電力。濾波電路242電連接於整流電路240,濾波電路242可例如(但不限定)為CLC濾波電路,並包含一濾波電感器L及分別連接於濾波電感器L兩端的濾波電容器C1及C2,濾波電路242用以濾除整流二極體D1及D2輸出之直流電力的高頻脈動成分並輸出平穩的直流電。 The rectifier circuit 240 is composed of diodes D1 and D2 and is electrically connected to the secondary side winding Ns for converting AC power passing through the transformer T into DC power having a high frequency ripple component. The filter circuit 242 is electrically connected to the rectifier circuit 240. The filter circuit 242 can be, for example but not limited to, a CLC filter circuit, and includes a filter inductor L and filter capacitors C1 and C2 respectively connected to the two ends of the filter inductor L. The filter circuit The 242 is configured to filter out the high frequency ripple component of the DC power output from the rectifier diodes D1 and D2 and output a smooth direct current.
配合參閱第五圖,為本揭示內容第三實施方式之電源轉換器之電路圖。第五圖所示之電源轉換器24為單一順向式電源轉換器,電源轉換器24包含一主動切換元件S、一被動切換元件DR、一電容 器C、一電阻器R、一變壓器T、一整流電路240及一濾波電路242。 Referring to the fifth figure, a circuit diagram of a power converter according to a third embodiment of the disclosure is shown. The power converter 24 shown in FIG. 5 is a single forward power converter, and the power converter 24 includes an active switching element S, a passive switching element DR, and a capacitor. The device C, a resistor R, a transformer T, a rectifier circuit 240 and a filter circuit 242.
主動切換元件S電連接於整流器22及控制器26,用以接收整流器22輸出的直流電力,並依據控制器26提供的信號以切換於導通狀態或截止狀態,並輸出脈動直流信號。在本實施方式中,主動切換元件S為金屬氧化物半導體場效應電晶體,主動切換元件S的閘級電連接於控制器26。主動切換元件S的汲極與源極之間連接有一二極體D,二極體D也可以為主動切換元件S的寄生二極體。被動切換元件DR及電容器C串聯連接,並跨接於變壓器T的一次側繞組Np,電阻器R與電容器C並聯連接。於本實施方式中,被動切換元件DR為二極體。 The active switching element S is electrically connected to the rectifier 22 and the controller 26 for receiving the DC power output by the rectifier 22, and switching to the on state or the off state according to the signal provided by the controller 26, and outputting the pulsating DC signal. In the present embodiment, the active switching element S is a metal oxide semiconductor field effect transistor, and the gate of the active switching element S is electrically connected to the controller 26. A diode D is connected between the drain and the source of the active switching element S, and the diode D can also be a parasitic diode of the active switching element S. The passive switching element DR and the capacitor C are connected in series and connected across the primary side winding Np of the transformer T, and the resistor R is connected in parallel with the capacitor C. In the present embodiment, the passive switching element DR is a diode.
整流電路240由二極體D1及D2組成並電連接於二次側繞組Ns,用以將通過變壓器T的交流電力轉換為具高頻脈動成分的直流電力。濾波電路242電連接於整流電路240,濾波電路242可例如(但不限定)為CLC濾波電路,並包含一濾波電感器L及分別連接於濾波電感器L兩端的濾波電容器C1及C2,濾波電路242用以濾除整流二極體D1及D2輸出之直流電力的高頻脈動成分並輸出平穩的直流電。 The rectifier circuit 240 is composed of diodes D1 and D2 and is electrically connected to the secondary side winding Ns for converting AC power passing through the transformer T into DC power having a high frequency ripple component. The filter circuit 242 is electrically connected to the rectifier circuit 240. The filter circuit 242 can be, for example but not limited to, a CLC filter circuit, and includes a filter inductor L and filter capacitors C1 and C2 respectively connected to the two ends of the filter inductor L. The filter circuit The 242 is configured to filter out the high frequency ripple component of the DC power output from the rectifier diodes D1 and D2 and output a smooth direct current.
復參閱第二圖,電源供應裝置2更包含一第一隔離開關32、一第二隔離開關34及一第三隔離開關36。第一隔離開關32、第二隔離開關34及第三隔離開關36可例如(但不限制)為光耦合器。 Referring to the second figure, the power supply device 2 further includes a first isolation switch 32, a second isolation switch 34 and a third isolation switch 36. The first isolation switch 32, the second isolation switch 34, and the third isolation switch 36 can be, for example but not limited to, an optical coupler.
第一隔離開關32之一端(信號發射端)電連接於待機電源輸出端 Vsb及第二電源輸出端VB,第一隔離開關32之另一端(信號接收端)電連接於控制器26,用以偵測由待機電源輸出端Vsb及第二電源輸出端VB輸出之電力,並將對應前述輸出電力之信號隔離地傳遞至該控制器26。 One end of the first isolation switch 32 (signal transmitting end) is electrically connected to the standby power output end The Vsb and the second power output terminal VB, the other end of the first isolation switch 32 (signal receiving end) is electrically connected to the controller 26 for detecting the power outputted by the standby power output terminal Vsb and the second power output terminal VB. A signal corresponding to the aforementioned output power is transmitted to the controller 26 in isolation.
第二隔離開關34之一端(信號發射端)電連接於電源管理器28,第二隔離開關34之另一端(信號接收端)電連接於控制器26。當電子系統PS或電源供應裝置2操作在工作電壓過高、工作電流過高或短路狀態下,電源管理器28發送之關於過電壓、過電流或短路之保護信號係通過第二隔離開關34傳遞至控制器26,控制器26可驅使電源轉換器24停止電能轉換。 One end (signal transmitting end) of the second isolation switch 34 is electrically connected to the power manager 28, and the other end (signal receiving end) of the second isolating switch 34 is electrically connected to the controller 26. When the electronic system PS or the power supply device 2 is operated at an operating voltage that is too high, the operating current is too high, or the short circuit condition, the protection signal sent by the power manager 28 about overvoltage, overcurrent, or short circuit is transmitted through the second isolation switch 34. To controller 26, controller 26 can drive power converter 24 to stop power conversion.
第三隔離開關36之一端(信號發射端)電連接於控制器26,第三隔離開關36之另一端(信號接收端)電連接於電源管理器28。電源管理器28通過第三隔離開關36接收由控制器26在電源轉換器24電能轉換後之電力正常無誤時發出一控制信號,並經由信號輸出端PG通知電子系統PS電源供應裝置2的電源啟動正常。 One end (signal transmitting end) of the third isolating switch 36 is electrically connected to the controller 26, and the other end (signal receiving end) of the third isolating switch 36 is electrically connected to the power manager 28. The power manager 28 receives the control signal from the controller 26 when the power of the power converter 24 after the power conversion is normal, and sends a control signal to the electronic system PS power supply device 2 via the signal output terminal PG. normal.
配合參閱第六圖,為對應第二圖所示之電源供應裝置運作之一時序圖。在第一狀態時,即時間為t1至t7,在此區段內,交流電源供應器ACP啟動(即AC_On為高電位),電子系統PS啟動(即PS_On為低電位)。開關元件30關閉,電源供應裝置2之待機電源輸出端Vsb、第一電源輸出端VA及第二電源輸出端VB輸出之電力皆傳遞電子系統PS。 Referring to the sixth figure, it is a timing chart corresponding to the operation of the power supply device shown in the second figure. In the first state, i.e., the time is t1 to t7, in which the AC power supply ACP is activated (i.e., AC_On is high) and the electronic system PS is started (i.e., PS_On is low). The switching element 30 is turned off, and the power output from the standby power output terminal Vsb of the power supply device 2, the first power output terminal VA, and the second power output terminal VB are all transmitted to the electronic system PS.
在第二狀態時,即時間為t7至t9,交流電源供應器ACP啟動(即 AC_On為高電位),電子系統PS未啟動(即PS_On為高電位)。開關元件30開啟,電源供應裝置2之待機電源輸出端Vsb輸出之電力可傳遞至電子系統PS,而第一電源輸出端VA及第二電源輸出端VB輸出之電力係因開關元件30被開啟而無法傳遞至電子裝置PS。 In the second state, ie time t7 to t9, the AC power supply ACP is activated (ie AC_On is high), the electronic system PS is not activated (ie PS_On is high). When the switching element 30 is turned on, the power output from the standby power output terminal Vsb of the power supply device 2 can be transmitted to the electronic system PS, and the power output from the first power output terminal VA and the second power output terminal VB is turned on due to the switching element 30 being turned on. Cannot be passed to the electronic device PS.
在第三狀態時,即時間為t9至t11,交流電源供應器ACP啟動(即AC_On為高電位),電子系統ES由未啟動轉為啟動(即PS_On由高電位轉為低電位)。開關元件30關閉,電源供應裝置2之待機電源輸出端Vsb、第一電源輸出端VA及第二電源輸出端VB同時輸出電力至電子系統PS。 In the third state, that is, the time is t9 to t11, the AC power supply ACP is started (ie, AC_On is high), and the electronic system ES is turned from start to start (ie, PS_On is turned from high to low). The switching element 30 is turned off, and the standby power output terminal Vsb of the power supply device 2, the first power output terminal VA, and the second power output terminal VB simultaneously output power to the electronic system PS.
在第四狀態時,即時間在t11之後,交流電源供應器ACP未啟動(即AC_On為低電位),電子系統ES啟動(PS_On為低電位)。在電源轉換器24輸出之電壓小於第一預定值時(即時間為t11至t12),電源供應裝置2的信號輸出端PG送出信號予電子系統PS,以通知電子系統PS電源供應裝置2輸出的電力小於第一預定值。在電源轉換器24輸出後之電壓小於第二預定值時(即時間為t12至t13),開關元件30開啟,則第一電源輸出端VA及第二電源輸出端VB輸出的電力無法傳遞至電子系統PS。在電源轉換器24輸出之電壓小於第三預定值時,停止待機電源輸出端Vsb輸出電力至電子系統PS。 In the fourth state, that is, after time t11, the AC power supply ACP is not activated (ie, AC_On is low), and the electronic system ES is started (PS_On is low). When the voltage outputted by the power converter 24 is less than the first predetermined value (ie, the time is t11 to t12), the signal output terminal PG of the power supply device 2 sends a signal to the electronic system PS to notify the output of the electronic system PS power supply device 2 The power is less than the first predetermined value. When the voltage after the output of the power converter 24 is less than the second predetermined value (ie, the time is t12 to t13), the switching element 30 is turned on, and the power output from the first power output terminal VA and the second power output terminal VB cannot be transmitted to the electronic device. System PS. When the voltage output from the power converter 24 is less than the third predetermined value, the standby power output terminal Vsb is stopped to output power to the electronic system PS.
配合參閱第七圖,為對應第二圖所示之電源供應裝置運作之另一時序圖。在第一狀態時,即時間為t1至t2,交流電源供應器ACP啟動(即AC_On為高電位),電子系統PS啟動(PS_On為低電位)。在電源轉換器24輸出之電力大於一預定值時,待機電源輸出端Vsb輸出電力至電子裝置PS。 Referring to the seventh figure, another timing chart corresponding to the operation of the power supply device shown in the second figure is shown. In the first state, that is, the time is t1 to t2, the AC power supply ACP is started (ie, AC_On is high), and the electronic system PS is started (PS_On is low). When the power output from the power converter 24 is greater than a predetermined value, the standby power output terminal Vsb outputs power to the electronic device PS.
在第二狀態時,即時間為t2至t3,交流電源供應器ACP啟動(即AC_On為高電位),電子系統PS未啟動(即PS_On為高電位)。開關元件30開啟,電源供應裝置2之待機電源輸出端Vsb輸出電力至電子系統,而第一電源輸出端VA及第二電源輸出端VB輸出之電力係因開關元件30被開啟而無法傳遞至電子裝置PS,意即電源供應裝置2進入待機狀態。 In the second state, that is, the time is t2 to t3, the AC power supply ACP is started (ie, AC_On is high), and the electronic system PS is not activated (ie, PS_On is high). The switching element 30 is turned on, and the standby power output terminal Vsb of the power supply device 2 outputs power to the electronic system, and the power output from the first power output terminal VA and the second power output terminal VB is not transmitted to the electronic device because the switching element 30 is turned on. The device PS means that the power supply device 2 enters a standby state.
第七圖所示之時間t3至t5的操作相同於第六圖所示之時間t9至t11,且第七圖所示之時間t5至t8的操作相同於第六圖所示之時間t11至t14,在此則不予贅述。 The operations of the times t3 to t5 shown in the seventh figure are the same as the times t9 to t11 shown in the sixth figure, and the operations of the times t5 to t8 shown in the seventh figure are the same as the times t11 to t14 shown in the sixth figure. I will not repeat them here.
綜合以上所述,本揭示內容之電源供應裝置2較習知技術之電源供應裝置1減少了附屬電源轉換器,如此一來,不但可以有效地縮小電源供應裝置2的體積,並可以降低能源消耗,同時可以達到待機低功耗之特點。 In summary, the power supply device 2 of the present disclosure reduces the auxiliary power converter compared to the power supply device 1 of the prior art, so that the volume of the power supply device 2 can be effectively reduced, and energy consumption can be reduced. At the same time, it can achieve the characteristics of standby low power consumption.
配合參閱第八圖,為本揭示內容第二實施例之電源供應裝置之電路方塊圖。第八圖所示之電源供應裝置2A與第一實施方式的電源供應裝置2類似,且相同的元件標示以相同的符號。值得注意的是,兩者的差異在於:第八圖所示之電源供應裝置2A更包含一直流-直流轉換器38,且電源轉換器24僅包含一第一電源輸出端VA。 Referring to the eighth figure, a circuit block diagram of a power supply device according to a second embodiment of the present disclosure is shown. The power supply device 2A shown in the eighth embodiment is similar to the power supply device 2 of the first embodiment, and the same elements are denoted by the same reference numerals. It should be noted that the difference between the two is that the power supply device 2A shown in FIG. 8 further includes a DC-DC converter 38, and the power converter 24 includes only a first power output terminal VA.
直流-直流轉換器38電連接於電源轉換器24之第一電源輸出端VA及電源管理器28,直流-直流轉換器38具有一第二電源輸出端VB、一第三電源輸出端VC及一待機電源輸出端Vsb。直流-直流轉換 器38接收電源轉換器24由第一電源輸出端VA輸出的直流電力,並將直流電力進行電能轉換後由第二電源輸出端VB、第三電源輸出端VC及待機電源輸出端Vsb輸出。開關元件30電連接於第一電源輸出端VA、第二電源輸出端VB及第三電源輸出端VC,開關元件30接收電源管理器28送出的開關控制信號以導通或切斷由第一電源輸出端VA、第二電源輸出端VB及第三電源輸出端VC輸出並傳遞至電子系統PS的電源。待機電源輸出端Vsb電連接於電子系統PS。 The DC-DC converter 38 is electrically connected to the first power output terminal VA of the power converter 24 and the power manager 28. The DC-DC converter 38 has a second power output terminal VB, a third power output terminal VC and a Standby power output Vsb. DC-DC conversion The device 38 receives the DC power output by the power converter 24 from the first power output terminal VA, and converts the DC power into electrical energy, and then outputs the second power output terminal VB, the third power output terminal VC, and the standby power output terminal Vsb. The switching element 30 is electrically connected to the first power output terminal VA, the second power output terminal VB and the third power output terminal VC, and the switching component 30 receives the switch control signal sent by the power manager 28 to turn on or off the output by the first power source. The terminal VA, the second power output terminal VB, and the third power output terminal VC output and transmit power to the electronic system PS. The standby power output terminal Vsb is electrically connected to the electronic system PS.
其次,第一隔離元件32電連接於第一電源輸出端VA,以將第一電源輸出端VA輸出之電力傳遞至控制器26。電源供應裝置2A的各元件的功用與相關說明,實際上與第一實施方式的電源供應裝置2相同,在此不予贅述。電源供應裝置2A至少可達到與電源供應裝置2相同的功能。 Next, the first isolation element 32 is electrically connected to the first power output terminal VA to transfer the power output by the first power output terminal VA to the controller 26. The functions and related descriptions of the respective elements of the power supply device 2A are substantially the same as those of the power supply device 2 of the first embodiment, and will not be described herein. The power supply device 2A can at least achieve the same function as the power supply device 2.
配合參閱第九圖,為本揭示內容第三實施例之電源供應裝置之電路方塊圖。第九圖所示之電源供應裝置2B與第一實施方式的電源供應裝置2類似,且相同的元件標示以相同的符號。值得注意的是,兩者的差異在於:第九圖所示之電源供應裝置2B更包含一直流-直流轉換器38及一待機電源轉換器40,且電源轉換器24包含一第一電源輸出端VA及一待機電源輸出端Vsb。 Referring to FIG. 9, a circuit block diagram of a power supply device according to a third embodiment of the present disclosure is shown. The power supply device 2B shown in the ninth diagram is similar to the power supply device 2 of the first embodiment, and the same elements are denoted by the same reference numerals. It should be noted that the difference between the two is that the power supply device 2B shown in FIG. 9 further includes a DC-DC converter 38 and a standby power converter 40, and the power converter 24 includes a first power output. VA and a standby power output Vsb.
直流-直流轉換器38電連接於電源轉換器24之第一電源輸出端VA及電源管理器28,直流-直流轉換器38具有一第二電源輸出端VB及一第三電源輸出端VC。直流-直流轉換器38接收電源轉換器24由第一電源輸出端VA輸出的直流電力,並將直流電力進行電能轉換後由第二電源輸出端VB及第三電源輸出端VC輸出。開關元件30 電連接於第一電源輸出端VA、第二電源輸出端VB及第三電源輸出端VC,開關元件30接收電源管理器28送出的開關控制信號以導通或切斷由第一電源輸出端VA、第二電源輸出端VB及第三電源輸出端VC輸出並傳遞至電子系統PS的電源。 The DC-DC converter 38 is electrically connected to the first power output VA of the power converter 24 and the power manager 28. The DC-DC converter 38 has a second power output VB and a third power output VC. The DC-DC converter 38 receives the DC power output by the power converter 24 from the first power output terminal VA, and converts the DC power to the second power output terminal VB and the third power output terminal VC. Switching element 30 Electrically connected to the first power output terminal VA, the second power output terminal VB and the third power output terminal VC, the switching component 30 receives the switch control signal sent by the power manager 28 to turn on or off the first power output terminal VA, The second power output terminal VB and the third power output terminal VC output and transmit power to the electronic system PS.
待機電源轉換器40電連接於電源轉換器24、電源管理器28及電子系統PS。待機電源轉換器40接收電源轉換器24之待機電源輸出端Vsb輸出的直流電力,並將直流電力進行電能轉換後輸出至電子系統PS。其次,第一隔離元件32電連接於第一電源輸出端VA,以將第一電源輸出端VA輸出之電力傳遞至控制器26。電源供應裝置2B的各元件的功用與相關說明,實際上與第一實施方式的電源供應裝置2相同,在此不予贅述。電源供應裝置2B至少可達到與電源供應裝置2相同的功能。 The standby power converter 40 is electrically connected to the power converter 24, the power manager 28, and the electronic system PS. The standby power converter 40 receives the DC power outputted from the standby power output terminal Vsb of the power converter 24, and converts the DC power into electrical energy and outputs the DC power to the electronic system PS. Next, the first isolation element 32 is electrically connected to the first power output terminal VA to transfer the power output by the first power output terminal VA to the controller 26. The functions and related descriptions of the respective elements of the power supply device 2B are substantially the same as those of the power supply device 2 of the first embodiment, and will not be described herein. The power supply device 2B can at least achieve the same function as the power supply device 2.
然以上所述者,僅為本揭示內容之較佳實施方式,當不能限定本創作實施之範圍,即凡依本創作申請專利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意圖保護之範疇。 However, the above description is only a preferred embodiment of the present disclosure, and the scope of the present invention cannot be limited, that is, the equal variation and modification of the patent application scope of the present invention should remain the patent of the present invention. Covers the scope of intent to protect.
2‧‧‧電源供應裝置 2‧‧‧Power supply unit
20‧‧‧電磁干擾濾波器 20‧‧‧Electromagnetic interference filter
22‧‧‧整流器 22‧‧‧Rectifier
220‧‧‧功率因素校正電路 220‧‧‧Power factor correction circuit
24‧‧‧電源轉換器 24‧‧‧Power Converter
26‧‧‧控制器 26‧‧‧ Controller
28‧‧‧電源管理器 28‧‧‧Power Manager
30‧‧‧開關元件 30‧‧‧Switching elements
32‧‧‧第一隔離開關 32‧‧‧First isolation switch
34‧‧‧第二隔離開關 34‧‧‧Second isolation switch
36‧‧‧第三隔離開關 36‧‧‧The third isolating switch
ACP‧‧‧交流電源供應器 ACP‧‧‧AC power supply
PG‧‧‧信號輸出端 PG‧‧‧ signal output
PS‧‧‧電子系統 PS‧‧‧Electronic System
PS-On‧‧‧信號輸入端 PS-On‧‧‧ signal input
VA‧‧‧第一電源輸出端 VA‧‧‧first power output
VB‧‧‧第二電源輸出端 VB‧‧‧second power output
Vsb‧‧‧待機電源輸出端 Vsb‧‧‧Standby power output
Claims (14)
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CN201320615437.7U CN203608098U (en) | 2013-05-27 | 2013-09-30 | Power supply device |
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TW102209860U TWM463466U (en) | 2013-05-27 | 2013-05-27 | Power supplying device |
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Cited By (5)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN104953804A (en) * | 2014-03-27 | 2015-09-30 | 群光电能科技股份有限公司 | Power supply device having overvoltage protection function |
US9432019B2 (en) | 2014-10-17 | 2016-08-30 | Realtek Semiconductor Corp. | Control chip and system using the same for power saving |
US9735692B1 (en) | 2016-08-01 | 2017-08-15 | Chicony Power Technology Co., Ltd. | Adapter with low standby loss and electronic system with low standby loss |
TWI601369B (en) * | 2016-06-16 | 2017-10-01 | 群光電能科技股份有限公司 | Adapter with low standby loss and electronic system with low standby loss |
US10171074B2 (en) | 2015-10-01 | 2019-01-01 | Chicony Power Technology Co., Ltd. | Electronic system |
-
2013
- 2013-05-27 TW TW102209860U patent/TWM463466U/en unknown
- 2013-09-30 CN CN201320615437.7U patent/CN203608098U/en not_active Expired - Lifetime
Cited By (5)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN104953804A (en) * | 2014-03-27 | 2015-09-30 | 群光电能科技股份有限公司 | Power supply device having overvoltage protection function |
US9432019B2 (en) | 2014-10-17 | 2016-08-30 | Realtek Semiconductor Corp. | Control chip and system using the same for power saving |
US10171074B2 (en) | 2015-10-01 | 2019-01-01 | Chicony Power Technology Co., Ltd. | Electronic system |
TWI601369B (en) * | 2016-06-16 | 2017-10-01 | 群光電能科技股份有限公司 | Adapter with low standby loss and electronic system with low standby loss |
US9735692B1 (en) | 2016-08-01 | 2017-08-15 | Chicony Power Technology Co., Ltd. | Adapter with low standby loss and electronic system with low standby loss |
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