TWM464596U - Switching apparatus for energy saving lamps and switchable power supply apparatus for energy saving lamps - Google Patents

Abstract

The present invention relates to an energy-saving light switchover device, which is composed by an alternating-current power supply unit, a switch, a rectifier, a first energy-saving light, a second energy-saving light, a first energy-saving light power supply module, and a second energy-saving light power supply module. The energy-saving light switchover device comprises a first electric energy storage unit, a bistable multivibrator, and a switchover signal input end. The electric energy storage unit is electrically connected to the rectifier. The bistable multivibrator is electrically connected to the electric energy storage unit, to the first energy-saving light power supply module, and to the second energy-saving light power supply module. The switchover signal input end is electrically connected to the electrical energy storage unit and to the bistable multivibrator. The energy-saving light switchover device and the switchover-type energy-saving light power supply device provided in the present invention implement the goals of reduced costs, reduced electricity consumption, and increased reliability via the switch and the bistable multivibrator.

Description

Energy-saving lamp switching device and switching energy-saving lamp power supply device

The present invention relates to a switching device and a switching power supply device, in particular to an energy-saving lamp switching device and a switching energy-saving lamp power supply device.

Due to the increasing global awareness of environmental protection, it is expected that in the near future, energy saving lamps, such as fluorescent lamps or light-emitting diode lamps, will replace incandescent lamps and become the mainstream of lighting. . Among the above-mentioned energy-saving lamps, the power supply device of the fluorescent lamp is generally called a ballast, and the power supply device of the light-emitting diode lamp is generally called a driver.

Fluorescent lamps and LED lamps have their own advantages; fluorescent lamps have the advantage of high brightness, suitable for reading, and LED lamps are suitable for use without sufficient light (such as sleep). There is a device that can be used for switching control after combining the two to meet the needs of different situations; that is, switching to a fluorescent lamp when it is suitable to use a fluorescent lamp, when it is suitable to use a light-emitting diode lamp Switch to a light-emitting diode lamp.

However, most of the above-mentioned switching control devices use relays and related circuits as switching control, and therefore generally have high cost and high power consumption (about 5 to 10 mA), but the reliability is low.

In order to improve the above disadvantages of the prior art, the purpose of the present invention is to provide an energy saving lamp switching device.

In order to improve the above disadvantages of the prior art, another object of the present invention is to provide a switching type energy-saving lamp power supply device.

In order to achieve the above object of the present invention, the energy-saving lamp switching device of the present invention is applied to an AC power supply device, a switch, a rectifier, an energy-saving lamp unit, a first energy-saving lamp power supply module, and a second energy-saving lamp power supply. a power supply module, the energy-saving lamp unit includes a first energy-saving lamp and a second energy-saving lamp, the switch is electrically connected to the AC power supply device and the rectifier, and the first energy-saving lamp power supply module is electrically connected to the first An energy-saving lamp and the rectifier, the second energy-saving lamp power supply module is electrically connected to the second energy-saving lamp and the rectifier, the energy-saving lamp switching device comprises: an electric energy storage unit, the electric energy storage unit is electrically connected to the a bistable multivibrator electrically connected to the electrical energy storage unit, the first energy-saving lamp power supply module, and the second energy-saving lamp power supply module; The switching signal input end is electrically connected to the electrical energy storage unit and the bistable multivibrator.

In order to achieve the above-mentioned other object of the present invention, the switching energy-saving lamp power supply device of the present invention is applied to an AC power supply device, a switch and an energy-saving lamp unit, and the energy-saving lamp unit comprises a first energy-saving lamp and a second An energy-saving lamp, the switch is electrically connected to the AC power supply device, the switchable energy-saving lamp power supply device comprises: a rectifier electrically connected to the switch; a first energy-saving lamp power supply module, the first energy-saving The lamp power supply module is electrically connected to the first energy-saving lamp and the rectifier; a second energy-saving lamp power supply module, the second energy-saving lamp power supply module is electrically connected to the second energy-saving lamp and the rectifier; An electrical energy storage unit electrically connected to the rectifier; a bistable multivibrator electrically connected to the electrical energy storage unit, the first energy saving lamp power supply mode And the second energy-saving lamp power supply module; and a switching signal input end, the switching signal input end is electrically connected to the electrical energy storage unit and the bistable multivibrator.

The function of the present invention is to provide a low-cost, low-power, high-reliability energy-saving lamp switching device and a switching energy-saving lamp power supply device.

10‧‧‧ energy-saving lamp switching device
20‧‧‧AC power supply unit
30‧‧‧ switch
40‧‧‧Rectifier
50‧‧‧First energy saving lamp
52‧‧‧ energy saving lamp unit
60‧‧‧second energy-saving lamps
70‧‧‧First energy-saving lamp power supply module
80‧‧‧Second energy-saving lamp power supply module
90‧‧‧Switching energy-saving lamp power supply device
102‧‧‧Electric energy storage unit
104‧‧‧Bistable Multivibrator
106‧‧‧Initial state selector
108‧‧‧Switch signal input
702‧‧‧ diode
704‧‧‧Input filter capacitor
706‧‧‧Power Conversion Unit
708‧‧‧Starting unit
710‧‧‧Starting input
712‧‧‧Separate control interface
718‧‧‧Electronic switch
720‧‧‧bias unit
722‧‧‧Switch control input
724‧‧‧Overvoltage protection input
726‧‧‧Overcurrent protection input
728‧‧‧Power Factor Corrector
730‧‧‧Undervoltage Lock Detection Unit
732‧‧‧Undervoltage lock input
734‧‧‧Boost Active Power Factor Corrector
736‧‧‧Control Module
738‧‧‧Boost diode
740‧‧‧ storage capacitor
10202‧‧‧ seventh resistor
10204‧‧‧8th resistor
10206‧‧‧ third capacitor
10208‧‧‧ Third Dipole
10210‧‧‧fourth capacitor
10212‧‧‧Zina diode
10402‧‧‧First resistance
10404‧‧‧second resistance
10406‧‧‧First transistor
10408‧‧‧Second transistor
10410‧‧‧ Third resistor
10412‧‧‧fourth resistor
10414‧‧‧First Diode
10416‧‧‧Secondary diode
10418‧‧‧ fifth resistor
10420‧‧‧6th resistor
10422‧‧‧first capacitor
10424‧‧‧second capacitor
10602‧‧‧Initial state capacitance

The first picture is a block diagram of the energy-saving lamp switching device of the creation.
The second picture is a block diagram of the bistable multivibrator and initial state selector of the creation and the surrounding peripheral circuit.
The third figure is a block diagram of the circuit of the electrical energy storage unit of the present invention.
The fourth figure is a block diagram of a first embodiment of the switching power supply lamp power supply device of the present invention.
The fifth figure is a block diagram of a second embodiment of the switching energy-saving lamp power supply device of the present invention.
The sixth figure is a block diagram of a third embodiment of the switching power supply lamp power supply device of the present invention.
The seventh figure is a block diagram of a fourth embodiment of the switching power-saving lamp power supply device of the present invention.
The eighth figure is a block diagram of a fifth embodiment of the switching energy-saving lamp power supply device of the present invention.
The ninth drawing is a block diagram of a sixth embodiment of the switching energy-saving lamp power supply device of the present invention.
The tenth block is a block diagram of a seventh embodiment of the switching energy-saving lamp power supply device of the present invention.
Figure 11 is a block diagram showing an eighth embodiment of the switching power-saving lamp power supply device of the present invention.
Fig. 12 is a block diagram showing a ninth embodiment of the switching power supply lamp power supply device of the present invention.
Figure 13 is a block diagram showing a tenth embodiment of the switching type energy-saving lamp power supply device of the present invention.
Fig. 14 is a block diagram showing the eleventh embodiment of the switching type energy-saving lamp power supply device of the present invention.
The fifteenth figure is a block diagram of a twelfth embodiment of the switching power-saving lamp power supply device of the present invention.
Figure 16 is a block diagram showing a thirteenth embodiment of the switching power supply lamp power supply device of the present invention.
Figure 17 is a block diagram showing a fourteenth embodiment of the switching type energy-saving lamp power supply device of the present invention.
Figure 18 is a circuit diagram of the rectifier.
The nineteenth figure shows the connection mode of the initial state selector.
The twenty-fifth figure shows the connection mode 2 of the initial state selector.
The twenty-first figure shows the connection mode 3 of the initial state selector.
The twenty-second figure is the connection mode four of the initial state selector.
The twenty-third figure is a first embodiment of the circuit diagram of the fourth figure.
The twenty-fourth embodiment is a second embodiment of the circuit diagram of the fourth figure.
The twenty-fifth figure is a third embodiment of the circuit diagram of the fourth figure.
The twenty-sixth embodiment is a fourth embodiment of the circuit diagram of the fourth figure.
The twenty-seventh drawing is a circuit diagram embodiment of the fifth figure.
The twenty-eighthth embodiment is a circuit diagram embodiment of the sixth figure.
The twenty-ninth figure is a circuit diagram embodiment of the seventh figure.
Figure 30 is a circuit diagram embodiment of the ninth diagram.
The thirty-first figure is an embodiment of the circuit diagram of the eleventh figure.
Figure 32 is a first embodiment of the circuit diagram of the twelfth figure.
The thirty-third figure is a second embodiment of the circuit diagram of the twelfth figure.
The thirty-fourth embodiment is a circuit diagram embodiment of the thirteenth diagram.
Figure 35 is a circuit diagram embodiment of the fourteenth diagram.
Figure 36 is a circuit diagram embodiment of the fifteenth diagram.
Figure 37 is a circuit diagram embodiment of the sixteenth diagram.
Figure 38 is a circuit diagram embodiment of the seventeenth diagram.

Please refer to the first figure, which is a block diagram of the energy-saving lamp switching device of the present invention. The energy-saving lamp switching device 10 of the present invention is applied to an AC power supply device 20, a switch 30, a rectifier 40, an energy-saving lamp unit 52, a first energy-saving lamp power supply module 70, and a second energy-saving lamp power supply mode. The energy-saving lamp unit 52 includes a first energy-saving lamp 50 and a second energy-saving lamp 60; the switch 30 is electrically connected to the AC power supply device 20 and the rectifier 40; the first energy-saving lamp power supply module 70 The second energy-saving lamp power supply module 80 is electrically connected to the second energy-saving lamp 60 and the rectifier 40.

The energy-saving lamp switching device 10 includes an electrical energy storage unit 102, a bistable multivibrator 104, an initial state selector 106, and a switching signal input terminal 108.

The electrical energy storage unit 102 is electrically connected to the rectifier 40. The bistable multivibrator 104 is electrically connected to the electrical energy storage unit 102, the first energy-saving lamp power supply module 70, and the second energy-saving lamp power supply. The switching signal input terminal 108 is electrically connected to the electrical energy storage unit 102 and the bistable multivibrator 104; the initial state selector 106 is electrically connected to the bistable multivibrator 104.

In one embodiment of the present invention, for example, when the switch 30 is turned on for the first time, the first energy saving lamp 50 is illuminated and the second energy saving lamp 60 is not illuminated; then at a predetermined time (for example, three seconds), when the switch 30 is turned on again (ie, the second time), the first energy saving lamp 50 is not illuminated and the second energy saving lamp 60 is illuminated; Switch between the two energy-saving lamps.

Please refer to the second figure, which is a block diagram of the bistable multivibrator and the initial state selector and the nearby peripheral circuits. The initial state capacitor 106 includes an initial state capacitor 10602. One end of the initial state capacitor 10602 is electrically coupled to the flip-flop 104. The other end of the initial state capacitor 10602 is electrically connected to ground (electrical Ground or the common connection of circuits in the eighteenth to thirty-eighth diagrams B1).

The bistable multivibrator 104 includes a first resistor 10402, a second resistor 10404, a first transistor 10406, a second transistor 10408, a third resistor 10410, a fourth resistor 10412, and a first resistor. A diode 10414, a second diode 10416, a fifth resistor 10418, a sixth resistor 10420, a first capacitor 10422 and a second capacitor 10424.

One end of the first resistor 10402 is electrically connected to the electrical energy storage unit 102. The other end of the first resistor 10402 is electrically connected to the first energy-saving lamp power supply module 70. One end of the second resistor 10404 is electrically connected. The other end of the second resistor 10404 is electrically connected to the second energy-saving lamp power supply module 80; the first end of the first transistor 10406 is electrically connected to the first end of the first resistor 10402. Connected to the other end of the first resistor 10402 and the first energy-saving lamp power supply module 70, the third end of the first transistor 10406 is grounded (the ground of the circuit or as shown in the eighteenth to thirty-eighthth a common connection of the circuit B1); the first end of the second transistor 10408 is electrically connected to the other end of the second resistor 10404 and the second energy-saving lamp power supply module 80, the second transistor 10408 Three-terminal grounding (the ground of the circuit or the common connection B1 of the circuits in the eighteenth to thirty-eighthth drawings).

One end of the third resistor 10410 is electrically connected to the first end of the first transistor 10406, the other end of the first resistor 10402, and the first energy-saving lamp power supply module 70, and the other end of the third resistor 10410 Electrically connected to the second end of the second transistor 10408; one end of the fourth resistor 10412 is electrically connected to the second end of the first transistor 10406, and the other end of the fourth resistor 10412 is electrically connected to the a first end of the second transistor 10408, the other end of the second resistor 10404, and the second energy-saving lamp power supply module 80; the anode of the first diode 1014 is electrically connected to the first transistor 10406 The second end and the fourth resistor 10412 are electrically connected to the second end of the second transistor 10408 and the other end of the third resistor 10410.

One end of the fifth resistor 10418 is electrically connected to the first end of the first transistor 10406, the other end of the first resistor 10402, one end of the third resistor 10410, and the first energy-saving lamp power supply module 70, The other end of the fifth resistor 10418 is electrically connected to the cathode of the first diode 1014; one end of the sixth resistor 10420 is electrically connected to the cathode of the second diode 10416, and the sixth resistor 10420 is further One end is electrically connected to the first end of the second transistor 10408, the other end of the second resistor 10404, the other end of the fourth resistor 10412, and the second energy-saving lamp power supply module 80.

One end of the first capacitor 10422 is electrically connected to the cathode of the first diode 1014 and the other end of the fifth resistor 10418. The other end of the first capacitor 10422 is electrically connected to the switching signal input terminal 108. One end of the second capacitor 10424 is electrically connected to the cathode of the second diode 10416 and one end of the sixth resistor 10420. The other end of the second capacitor 10424 is electrically connected to the switching signal input terminal 108 and the first The other end of the capacitor 10422.

When the initial state capacitor 10602 is connected to one side of the first energy-saving lamp power supply module 70 (ie, as shown in the second figure) or to the second end of the second transistor 10408: when the switch 30 When first turned on, the first energy-saving lamp power supply module 70 receives a low potential (or zero potential) control signal and the second energy-saving lamp power supply module 80 receives a high-potential control signal. When the initial state capacitor 10602 is connected to one side of the second energy-saving lamp power supply module 80 or to the second end of the first transistor 10406: when the switch 30 is turned on for the first time, the first An energy-saving lamp power supply module 70 receives a high-potential control signal and the second energy-saving lamp power supply module 80 receives a low-potential (or zero-potential) control signal. Thereby, the function of the initial state selection is achieved, and the switching reliability is improved.

In the second figure, the second energy-saving lamp power supply module 80 may not be electrically connected to the second resistor 10404, the fourth resistor 10412, the second transistor 10408, and the sixth resistor 10420, but The first resistor 10402, the third resistor 10410, the first transistor 10406, the fifth resistor 10418, and the initial state selector 106 are electrically connected to the same side of the first energy-saving lamp power supply module 70; At this time, the condition that the first energy-saving lamp 50 is illuminated is that the first energy-saving lamp power supply module 70 needs to receive a high-potential control signal, and the condition that the second energy-saving lamp 60 is illuminated is the second energy-saving. The lamp power supply module 80 needs to receive a low potential (or zero potential) control signal; or the first energy saving lamp 50 is illuminated under the condition that the first energy saving lamp power supply module 70 needs to receive a low potential (or zero). The potential is controlled by the signal, and the second energy-saving lamp 60 is illuminated. The second energy-saving lamp power supply module 80 needs to receive a high-potential control signal.

Please refer to the third figure, which is a block diagram of the electrical energy storage unit circuit of the present invention. The electrical energy storage unit 102 includes a seventh resistor 10202, an eighth resistor 10204, a third capacitor 10206, a third diode 10208, a fourth capacitor 10210, and a Zener diode 10212.

One end of the seventh resistor 10202 is electrically connected to the rectifier 40, and the other end of the seventh resistor 10202 is electrically connected to the switching signal input terminal 108. One end of the eighth resistor 10204 is electrically connected to the seventh resistor 10202. The other end of the eighth resistor 10204 is electrically connected to the ground (the ground of the circuit or the common connection B1 of the circuits in the eighteenth to thirty-eighth diagrams); One end of the third capacitor 10206 is electrically connected to the other end of the seventh resistor 10202, one end of the eighth resistor 10204 and the switching signal input terminal 108, and the other end of the third capacitor 10206 is electrically connected to the ground (circuit Ground or the common connection of circuits in the eighteenth to thirty-eighth diagrams B1).

The anode of the third diode 10208 is electrically connected to the other end of the seventh resistor 10202, one end of the eighth resistor 10204, one end of the third capacitor 10206, and the switching signal input terminal 108. The third diode The cathode of the body 10208 is electrically connected to the bistable multivibrator 104. One end of the fourth capacitor 10210 is electrically connected to the cathode of the third diode 10208 and the bistable multivibrator 104. The other end of the fourth capacitor 10210 is electrically connected to the ground (the ground of the circuit or the common connection B1 of the circuit in the eighteenth to thirty-eighthth drawings); the cathode of the Zener diode 10212 is electrically connected to The anode of the third diode 10208, the bistable multivibrator 104, and one end of the fourth capacitor 10210, the anode of the Zener diode 10212 is electrically connected to ground (circuit ground or as the tenth The common connection of the circuits in Figures 8 to 38 is B1).

Please refer to the fourth figure, which is a block diagram of a first embodiment of the switching power supply lamp power supply device of the present invention. The switching energy-saving lamp power supply device 90 is applied to an AC power supply device 20, a switch 30 and an energy-saving lamp unit 52; the energy-saving lamp unit 52 includes a first energy-saving lamp 50 and a second energy-saving lamp 60; 30 is electrically connected to the AC power supply device 20.

The switching energy-saving lamp power supply device 90 includes a rectifier 40, a first energy-saving lamp power supply module 70, a second energy-saving lamp power supply module 80, an electrical energy storage unit 102, and a bistable multivibrator. 104. An initial state selector 106 and a switching signal input terminal 108.

The rectifier 40 is electrically connected to the switch 30; the first energy-saving lamp power supply module 70 is electrically connected to the first energy-saving lamp 50 and the rectifier 40; the second energy-saving lamp power supply module 80 is electrically connected to The second energy-saving lamp 60 and the rectifier 40; the electrical energy storage unit 102 is electrically connected to the rectifier 40; the bistable multivibrator 104 is electrically connected to the electrical energy storage unit 102, the first energy-saving lamp power supply The module 70 and the second energy-saving lamp power supply module 80; the switching signal input terminal 108 is electrically connected to the electrical energy storage unit 102 and the bistable multivibrator 104; the initial state selector 106 is electrically connected To the flip-flop 104.

The first energy-saving lamp power supply module 70 or the second energy-saving lamp power supply module 80 (the first energy-saving lamp power supply module 70 is shown) includes a diode 702 and an input end. The filter capacitor 704, a power conversion unit 706, a unit 708, a mobile input terminal 710, and a separate control interface 712.

The anode of the diode 702 is electrically connected to the rectifier 40; the input filter capacitor 704 is electrically connected to the cathode of the diode 702; the power conversion unit 706 is electrically connected to the input filter capacitor 704 and the The energy-saving lamp unit 52 (shown in the figure is electrically connected to the first energy-saving lamp 50); the starting unit 708 is electrically connected to the rectifier 40 and the anode of the diode 702; the starting input terminal 710 is electrically connected The starter unit 708 and the power conversion unit 706 are electrically connected to the start input 710 and the bistable multivibrator 104.

Furthermore, the description of the electrical connection and electrical flow function of the same components as the above-described energy-saving lamp switching device 10 will not be repeated here.

Please refer to the fifth figure, which is a block diagram of a second embodiment of the switching energy-saving lamp power supply device of the present invention. The fifth and fourth figures and the above-mentioned energy-saving lamp switching device 10 have the same electrical connection and electrical flow function description, and will not be further described herein.

The first energy-saving lamp power supply module 70 or the second energy-saving lamp power supply module 80 (the first energy-saving lamp power supply module 70 is shown) includes a diode 702 and an input end. The filter capacitor 704, a power conversion unit 706, an under voltage lock detection unit 730, an under voltage lock input terminal 732 and a separate control interface 712.

The anode of the diode 702 is electrically connected to the rectifier 40; the input filter capacitor 704 is electrically connected to the cathode of the diode 702; the power conversion unit 706 is electrically connected to the input filter capacitor 704 and the The energy-saving lamp unit 52 (shown in the figure is electrically connected to the first energy-saving lamp 50); the under-voltage lock detecting unit 730 is electrically connected to the rectifier 40 and the anode of the diode 702; the undervoltage lock The input terminal 732 is electrically connected to the undervoltage lock detecting unit 730 and the power conversion unit 706. The split control interface 712 is electrically connected to the undervoltage lock input terminal 732 and the bistable multivibrator 104.

Please refer to the sixth figure, which is a block diagram of a third embodiment of the switching power supply lamp power supply device of the present invention. 6 and 4 and the foregoing description of the electrical connection and electrical flow function of the same components of the energy-saving lamp switching device 10 will not be repeated here.

The first energy-saving lamp power supply module 70 or the second energy-saving lamp power supply module 80 (the first energy-saving lamp power supply module 70 is shown) includes a diode 702 and an input end. Filter capacitor 704, an electronic switch 718, a biasing unit 720, a switch control input 722 and a separate control interface 712.

The anode of the diode 702 is electrically connected to the rectifier 40; the input filter capacitor 704 is electrically connected to the cathode of the diode 702 and the energy-saving lamp unit 52 (shown in the figure is electrically connected to the first An energy-saving lamp 50); the electronic switch 718 is electrically connected to the energy-saving lamp unit 52 (shown in the figure is electrically connected to the first energy-saving lamp 50); the biasing unit 720 is electrically connected to the rectifier 40 And the anode of the diode 702; the switch control input 722 is electrically connected to the bias unit 720 and the electronic switch 718; the split control interface 712 is electrically connected to the switch control input 722 and the pair The steady state multivibrator 104; as shown in the twenty-eighth figure, the electronic switch 718 may further include a current limiting resistor R37.

Please refer to the seventh figure, which is a block diagram of a fourth embodiment of the switching energy-saving lamp power supply device of the present invention. 7 and 4 and the foregoing description of the electrical connection and electrical flow function of the same components of the energy-saving lamp switching device 10 will not be repeated here.

The first energy-saving lamp power supply module 70 or the second energy-saving lamp power supply module 80 (the first energy-saving lamp power supply module 70 is shown) includes a power conversion unit 706 and a dynamic input. End 710 and a separate control interface 712.

The power conversion unit 706 is electrically connected to the rectifier 40 and the energy saving lamp unit 52 (shown electrically connected to the first energy saving lamp 50); the starting input 710 is electrically connected to the power conversion unit 706. The split control interface 712 is electrically coupled to the start input 710 and the bistable multivibrator 104.

Please refer to the eighth figure, which is a block diagram of a fifth embodiment of the switching energy-saving lamp power supply device of the present invention. 8 and 4 and the foregoing description of the electrical connection and electrical flow function of the same components of the energy-saving lamp switching device 10 will not be repeated here.

The first energy-saving lamp power supply module 70 or the second energy-saving lamp power supply module 80 (the first energy-saving lamp power supply module 70 is shown) includes a power conversion unit 706 and an undervoltage. The input 732 is locked and a separate control interface 712 is provided.

The power conversion unit 706 is electrically connected to the rectifier 40 and the energy-saving lamp unit 52 (shown electrically connected to the first energy-saving lamp 50); the under-voltage lock input 732 is electrically connected to the power conversion The split control interface 712 is electrically connected to the undervoltage lock input 732 and the flip-flop 104.

Please refer to the ninth figure, which is a block diagram of a sixth embodiment of the switching energy-saving lamp power supply device of the present invention. The description of the electrical connection and the electrical flow function of the same components of the ninth and fourth figures and the energy-saving lamp switching device 10 will not be repeated here.

The first energy-saving lamp power supply module 70 or the second energy-saving lamp power supply module 80 (the first energy-saving lamp power supply module 70 is shown) includes a power conversion unit 706 and an over-voltage. The input 724 is protected and a separate control interface 712 is provided.

The power conversion unit 706 is electrically connected to the rectifier 40 and the energy saving lamp unit 52 (shown electrically connected to the first energy saving lamp 50); the overvoltage protection input 724 is electrically connected to the power conversion The unit 706 is electrically connected to the overvoltage protection input 724 and the bistable multivibrator 104.

Please refer to the tenth figure, which is a block diagram of a seventh embodiment of the switching energy-saving lamp power supply device of the present invention. The electrical connection and the electrical flow function of the same components of the energy saving lamp switching device 10 in the tenth and fourth embodiments are not described herein.

The first energy-saving lamp power supply module 70 or the second energy-saving lamp power supply module 80 (the first energy-saving lamp power supply module 70 is shown) includes a power conversion unit 706 and an overcurrent. Protection input 726 and a separate control interface 712.

The power conversion unit 706 is electrically connected to the rectifier 40 and the energy saving lamp unit 52 (shown electrically connected to the first energy saving lamp 50); the overcurrent protection input 726 is electrically connected to the power conversion The unit 706 is electrically connected to the overcurrent protection input 726 and the bistable multivibrator 104.

Please refer to FIG. 11 , which is a block diagram of an eighth embodiment of the switching power supply lamp power supply device of the present invention. 11 and 4 and the foregoing description of the electrical connection and electrical flow function of the same components of the energy-saving lamp switching device 10 will not be repeated herein.

The first energy-saving lamp power supply module 70 or the second energy-saving lamp power supply module 80 (shown as the first energy-saving lamp power supply module 70) includes an electronic switch 718 and a switch control. Input 722.

The electronic switch 718 is electrically connected to the rectifier 40 and the energy saving lamp unit 52 (shown electrically connected to the first energy saving lamp 50); the switch control input 722 is electrically connected to the electronic switch 718 and the bistable multivibrator 104; as shown in FIG. 31, the electronic switch 718 further includes a current limiting resistor R6.

Please refer to the twelfth figure, which is a block diagram of a ninth embodiment of the switching power supply lamp power supply device of the present invention. The electrical connection and the electrical flow function of the same components in the twelfth and fourth embodiments and the above-mentioned energy-saving lamp switching device 10 will not be described herein.

The first energy-saving lamp power supply module 70 or the second energy-saving lamp power supply module 80 (the first energy-saving lamp power supply module 70 is shown) includes a diode 702 and a power factor. The corrector 728, a power conversion unit 706, a unit 708, a mobile input 710, and a separate control interface 712.

The anode of the diode 702 is electrically connected to the rectifier 40; the power factor corrector 728 is electrically connected to the cathode of the diode 702; the power conversion unit 706 is electrically connected to the power factor corrector 728 and the The energy-saving lamp unit 52 (shown in the figure is electrically connected to the first energy-saving lamp 50); the starting unit 708 is electrically connected to the rectifier 40 and the anode of the diode 702; the starting input terminal 710 is electrically connected The starter unit 708 and the power conversion unit 706 are electrically connected to the start input 710 and the bistable multivibrator 104.

Please refer to the thirteenth figure, which is a block diagram of a tenth embodiment of the switching energy-saving lamp power supply device of the present invention. The electrical connection and the electrical flow function of the same components of the thirteenth and fourth figures and the aforementioned energy-saving lamp switching device 10 will not be described herein.

The first energy-saving lamp power supply module 70 or the second energy-saving lamp power supply module 80 (the first energy-saving lamp power supply module 70 is shown) includes a diode 702 and a power factor. The corrector 728, a power conversion unit 706, an under voltage lock detection unit 730, an under voltage lock input 732 and a separate control interface 712.

The anode of the diode 702 is electrically connected to the rectifier 40; the power factor corrector 728 is electrically connected to the cathode of the diode 702; the power conversion unit 706 is electrically connected to the power factor corrector 728 and the The energy-saving lamp unit 52 (shown in the figure is electrically connected to the first energy-saving lamp 50); the under-voltage lock detecting unit 730 is electrically connected to the rectifier 40 and the anode of the diode 702; the undervoltage lock The input terminal 732 is electrically connected to the undervoltage lock detecting unit 730 and the power conversion unit 706. The split control interface 712 is electrically connected to the undervoltage lock input terminal 732 and the bistable multivibrator 104.

Please refer to FIG. 14 , which is a block diagram of an eleventh embodiment of the switching power supply lamp power supply device of the present invention. The electrical connection and the electrical flow function of the same components of the fourteenth and fourth embodiments and the aforementioned energy-saving lamp switching device 10 will not be described herein.

The first energy-saving lamp power supply module 70 or the second energy-saving lamp power supply module 80 (the first energy-saving lamp power supply module 70 is shown) includes a power factor corrector 728 and a power source. The conversion unit 706, the unit 708, the input terminal 710 and a separate control interface 712.

The power factor corrector 728 is electrically connected to the rectifier 40; the power conversion unit 706 is electrically connected to the power factor corrector 728 and the energy saving lamp unit 52 (shown in the figure is electrically connected to the first energy saving lamp The starter unit 708 is electrically connected to the rectifier 40 and the power factor corrector 728; the start input 710 is electrically connected to the starter unit 708 and the power conversion unit 706; the split control interface 712 is electrically Connected to the start input 710 and the flip-flop 104.

Please refer to the fifteenth figure, which is a block diagram of a twelfth embodiment of the switching power supply lamp power supply device of the present invention. The fifteenth and fourth figures and the electrical connection and electrical flow function of the same components of the above-mentioned energy-saving lamp switching device 10 will not be described herein.

The first energy-saving lamp power supply module 70 or the second energy-saving lamp power supply module 80 (the first energy-saving lamp power supply module 70 is shown) includes a power factor corrector 728 and a power source. The conversion unit 706, an undervoltage lockout detection unit 730, an undervoltage lockout input terminal 732, and a separate control interface 712.

The power factor corrector 728 is electrically connected to the rectifier 40; the power conversion unit 706 is electrically connected to the power factor corrector 728 and the energy saving lamp unit 52 (shown in the figure is electrically connected to the first energy saving lamp The undervoltage lockout detecting unit 730 is electrically connected to the rectifier 40 and the power factor corrector 728; the undervoltage lockout input 732 is electrically connected to the undervoltage lockout detecting unit 730 and the power conversion unit The partitioned control interface 712 is electrically coupled to the undervoltage lockout input 732 and the flip-flop 104.

Please refer to the sixteenth figure, which is a block diagram of the thirteenth embodiment of the switching power supply lamp power supply device of the present invention. The electrical connection and the electrical flow function of the same components of the sixteenth and fourth embodiments and the aforementioned energy-saving lamp switching device 10 will not be described herein.

The first energy-saving lamp power supply module 70 or the second energy-saving lamp power supply module 80 (shown as the first energy-saving lamp power supply module 70) includes a boost-type active power factor correction. The device 734, a power conversion unit 706, a unit 708, a mobile input terminal 710, and a separate control interface 712. The boosting active power factor corrector 734 includes a control module 736, a boost diode 738, and a storage capacitor 740.

The boosting active power factor corrector 734 is electrically connected to the rectifier 40; the power conversion unit 706 is electrically connected to the boosting active power factor corrector 734 and the energy saving lamp unit 52 (shown in the figure) Electrically connected to the first energy-saving lamp 50); the starting unit 708 is electrically connected to the step-up active power factor corrector 734; the starting input 710 is electrically connected to the starting unit 708 and the power conversion The unit 706 is electrically connected to the start input 710 and the bistable multivibrator 104; the control module 736 is electrically connected to the rectifier 40 and the start unit 708; The anode of the diode 738 is electrically connected to the control module 736 and the starting unit 708. The storage capacitor 740 is electrically connected to the cathode of the boosting diode 738 and the power conversion unit 706.

Please refer to FIG. 17 , which is a block diagram of a fourteenth embodiment of the switching power supply lamp power supply device of the present invention. The electrical connection and the electrical flow function of the same components of the seventeenth and fourth embodiments and the aforementioned energy-saving lamp switching device 10 will not be described herein.

The first energy-saving lamp power supply module 70 or the second energy-saving lamp power supply module 80 (shown as the first energy-saving lamp power supply module 70) includes a boost-type active power factor correction. The device 734, a power conversion unit 706, an under voltage lock detecting unit 730, an under voltage lock input terminal 732 and a separate control interface 712. The boosting active power factor corrector 734 includes a control module 736, a boost diode 738, and a storage capacitor 740.

The boosting active power factor corrector 734 is electrically connected to the rectifier 40; the power conversion unit 706 is electrically connected to the boosting active power factor corrector 734 and the energy saving lamp unit 52 (shown in the figure) The undervoltage lock detecting unit 730 is electrically connected to the boosting active power factor corrector 734; the undervoltage lockout input 732 is electrically connected to the undervoltage The voltage lock detection unit 730 and the power conversion unit 706; the separate control interface 712 is electrically connected to the under voltage lock input 732 and the bistable multivibrator 104; the control module 736 is electrically connected to The rectifier 40 and the undervoltage lockout detection unit 730; the anode of the boost diode 738 is electrically connected to the control module 736 and the undervoltage lockout detection unit 730; the storage capacitor 740 is electrically connected to the riser The cathode of the diode 738 is pressed and the power conversion unit 706.

The function of the under-voltage lockout (UVLO) is that when the input voltage of the first energy-saving lamp power supply module 70 is too low, the first energy-saving lamp power supply module 70 generates a protective shutdown ( The first energy-saving lamp power supply module 70 stops outputting the power supply; the function of the over-voltage protection is that when the output voltage of the first energy-saving lamp power supply module 70 is too high, the first energy-saving lamp power supply The supply module 70 stops outputting the power; the function of the overcurrent protection is that when the output current of the first energy-saving lamp power supply module 70 is excessive, the first energy-saving lamp power supply module 70 stops outputting power; in other words, When the first energy-saving lamp power supply module 70 is in normal operation (or normal state), the starting potential or the detecting potential must be a preset normal potential value. The switching mode of the patent is that the energy-saving lamp switching device 10 provides a control signal, and the abnormal control device 712 outputs an abnormal potential value to the first energy-saving lamp power supply module 70 to enable the first energy-saving lamp power supply. The module 70 stops outputting power or provides a control signal by the energy-saving lamp switching device 10, and stops outputting an abnormal potential value to the first energy-saving lamp power supply module 70 via the separate control interface 712 to make the first energy-saving lamp The power supply module 70 normally outputs the power; thereby achieving the purpose of switching different energy-saving lamps.

The fourth to seventeenth diagrams show that the first energy-saving lamp power supply module 70 or the second energy-saving lamp power supply module 80 has various circuit structures, and can have different combinations with each other, which are all protected by the present invention. For example, the circuit structure of the first energy-saving lamp power supply module 70 can be shown in the fourth figure, and the circuit structure of the second energy-saving lamp power supply module 80 can be shown in the fifth figure; The circuit structure of the energy-saving lamp power supply module 70 can be shown in the seventh figure, and the circuit structure of the second energy-saving lamp power supply module 80 can be shown in the sixth figure; for example, the first energy-saving lamp power supply The circuit structure of the module 70 can be shown in the eighth figure, and the circuit structure of the second energy-saving lamp power supply module 80 can also be shown in the eighth figure. The divided control interface 712 of the fourth, fifth, sixth, seventh, eighth, twelfth, thirteenth, fourteenth, fifteenth, sixteenth and seventeenthth views may be of a transistor type or a diode type; the ninth and tenth The split control interface 712 of the figure requires a bias and a unidirectional circuit. The separate control interface 712 can include a transistor or a diode.

Please refer to the eighteenth to thirty-eighth figures, which are described below (where B1 is the common connection of the circuits):

Figure 18 is a circuit diagram of the rectifier.

The nineteenth figure shows the connection mode of the initial state selector.

The twenty-fifth figure shows the connection mode 2 of the initial state selector.

The twenty-first figure shows the connection mode 3 of the initial state selector.

The twenty-second figure is the connection mode four of the initial state selector.

The twenty-third figure is a circuit diagram of the fourth embodiment; wherein the energy-saving lamp unit 52 is a fluorescent lamp, and the power conversion unit 706 is composed of discrete elements.

Figure 24 is a second embodiment of the circuit diagram of the second embodiment; wherein the energy-saving lamp unit 52 is a fluorescent lamp, the power conversion unit 706 includes a control integrated circuit (IR), and the control integrated circuit is IR ( International Rectifier) IR2520D control integrated circuit.

Figure 25 is a third embodiment of the circuit diagram of the fourth embodiment; wherein the energy-saving lamp unit 52 is a light-emitting diode (LED), and the power conversion unit 706 is composed of discrete components.

Figure 26 is a fourth embodiment of the circuit diagram of the fourth embodiment; wherein the energy-saving lamp unit 52 is a light-emitting diode, the power conversion unit 706 includes a control integrated circuit, which is manufactured by iWatt Co., Ltd. The iW1692 controls the integrated circuit.

Figure 27 is a circuit diagram embodiment of the fifth figure; wherein the energy-saving lamp unit 52 is a light-emitting diode, the power conversion unit 706 includes a control integrated circuit, which is produced by Maxim. The MAX16801B controls the integrated circuit.

The twenty-eighthth embodiment is a circuit diagram embodiment of the sixth figure; wherein the energy saving lamp unit 52 is a light emitting diode.

The twenty-ninth embodiment is a circuit diagram embodiment of the seventh figure; wherein the energy-saving lamp unit 52 is a light-emitting diode, the power conversion unit 706 includes a control integrated circuit, and the control integrated circuit is Maximtech (Maxictech) ) MT7920 controlled integrated circuit produced by the company.

Figure 30 is a circuit diagram embodiment of the ninth diagram; wherein the energy-saving lamp unit 52 is a light-emitting diode, the power conversion unit 706 includes a control integrated circuit, and the control integrated circuit is Maxictech The MT7920 controlled integrated circuit produced by the company.

The thirty-first figure is a circuit diagram embodiment of the eleventh figure; wherein the energy saving lamp unit 52 is a light emitting diode.

Figure 32 is a circuit diagram of the twelfth embodiment; wherein the energy-saving lamp unit 52 is a fluorescent lamp, the power conversion unit 706 is composed of discrete components, and the power factor corrector 728 is a passive power factor. Correction.

Figure 33 is a second embodiment of the circuit diagram of the twelfth figure; wherein the energy-saving lamp unit 52 is a fluorescent lamp, the power conversion unit 706 is composed of discrete components, and the power factor corrector 728 is an active power factor. The corrector, the power factor corrector 728 includes a control integrated circuit which is a L6562 control integrated circuit manufactured by STMicroelectronics.

Figure 34 is a circuit diagram embodiment of the thirteenth diagram; wherein the energy-saving lamp unit 52 is a light-emitting diode, the power conversion unit 706 includes a control integrated circuit, and the control integrated circuit is Maxim. The MAX16801B is manufactured to control the integrated circuit, which is a passive power factor corrector.

Figure 35 is a circuit diagram embodiment of Fig. 14; wherein the energy saving lamp unit 52 is a fluorescent lamp, the power conversion unit 706 is composed of discrete components, and the power factor corrector 728 is a passive power factor. Correction.

Figure 36 is a circuit diagram embodiment of the fifteenth diagram; wherein the energy-saving lamp unit 52 is a light-emitting diode, the power conversion unit 706 includes a control integrated circuit, and the control integrated circuit is Maxim. The MAX16801B is manufactured to control an integrated circuit. The power factor corrector 728 is an active power factor corrector. The power factor corrector 728 includes a control integrated circuit that is manufactured by STMicroelectronics. The L6562 controls the integrated circuit.

Figure 37 is a circuit diagram embodiment of the sixteenth embodiment; wherein the energy-saving lamp unit 52 is a fluorescent lamp, the power conversion unit 706 is composed of discrete components, and the control module 736 includes a control integrated circuit. The control integrated circuit is a L6562 control integrated circuit manufactured by STMicroelectronics.

Figure 38 is a circuit diagram embodiment of the seventeenth embodiment; wherein the energy-saving lamp unit 52 is a light-emitting diode, the power conversion unit 706 includes a control integrated circuit, and the control integrated circuit is Maxim. The MAX16801B is manufactured to control an integrated circuit. The control module 736 includes a control integrated circuit which is a L6562 control integrated circuit manufactured by STMicroelectronics.

The Bipolar Junction Transistor (BJT) in the circuit diagrams of the nineteenth to twenty-secondth drawings can also be replaced with a Field-Effect Transistor (FET) to achieve the same function as described above.

The divided control interface 712 of the fourth, fifth, sixth, seventh, eighth, twelfth, thirteenth, fourteenth, fifteenth, sixteenth and seventeenthth embodiments may be of a transistor type or a diode type. Further, in the circuit diagrams of the twenty-third to twenty-ninth and thirty-second to thirty-eighth, the separate control interface 712 includes a bipolar junction transistor (or a divided bipolar junction transistor S1, The code numbers in the circuit diagram are Q12, Q21, Q22, Q14, Q19, Q17, Q20, Q26, Q8, Q36, Q33, Q38, Q29, Q41), and the divided bipolar junction transistor S1 has a base (base). The resistor S2 (the code numbers in the circuit diagram are R61, R71, R72, R62, R67, R65, R69, R99, R78, R141, R132, R149, R111, R166) are electrically connected thereto, and the divided bipolar connection The surface transistor S1 can be replaced by a diode (or a divided diode S3). The base resistor S2 can be removed and replaced directly by a wire. The cathode of the divided diode S3 is electrically connected. CTRL_A or CTRL_B of the bistable multivibrator 104, the anode of the divided diode S3 is electrically connected to the start input 710 or the ow An input terminal 732 or the locking pressure of the control input of switch 722; the partition type bipolar junction transistor switch S1 may be substituted with field effect transistor, the base resistance at this time can be removed to replace S2 directly to the wire.

The split control interface 712 of the above ninth and tenth embodiments requires a bias voltage and a unidirectional circuit. The split control interface 712 can include a transistor or a diode. It is further illustrated that the split control interface 712 in FIG. 30 includes a bipolar junction transistor (or a divided bipolar junction transistor S4, The code in the circuit diagram is Q10), and the divided bipolar junction transistor S4 has a base resistor S5 (code R49 in the circuit diagram) electrically connected thereto, and the divided bipolar junction transistor S4 is electrically connected. It can be replaced by a diode (or a divided diode S6). At this time, the base resistor S5 can be removed and directly replaced by a wire. The cathode of the divided diode S6 is electrically connected to the bistable state. IGBT_A or CTRL_B of the harmonic oscillator 104, the anode of the divided diode S6 is electrically connected to the anode of the unidirectional diode D40 of the divided control interface 712 in FIG. 30; the divided bipolar junction is electrically The crystal S4 can also be replaced by a field effect transistor, in which case the base resistor S4 can be removed and replaced directly by a wire.

The above circuit diagram embodiment is intended to further provide a manner of implementation of the present invention, and to illustrate that the power conversion unit 706 can be composed only of discrete components or the power conversion unit 706 can include a control integrated circuit; the power factor corrector 728 It can be an active or passive power factor corrector.

The effect of this creation is to use a switch and a bistable multivibrator to provide a low-cost, low-power (less than 1 mA), high-reliability energy-saving lamp switching device and a switching energy-saving lamp power supply device.

In summary, when Zhiben's creation has industrial applicability, novelty and progressiveness, and the structure of this creation has not been seen in similar products and public use, it fully complies with the requirements of new patent applications and applies for patent law.

10‧‧‧ energy-saving lamp switching device

20‧‧‧AC power supply unit

30‧‧‧ switch

40‧‧‧Rectifier

50‧‧‧First energy saving lamp

52‧‧‧ energy saving lamp unit

60‧‧‧second energy-saving lamps

70‧‧‧First energy-saving lamp power supply module

80‧‧‧Second energy-saving lamp power supply module

102‧‧‧Electric energy storage unit

104‧‧‧Bistable Multivibrator

106‧‧‧Initial state selector

108‧‧‧Switch signal input

Claims (18)

The utility model relates to an energy-saving lamp switching device, which is applied to an AC power supply device, a switch, a rectifier, an energy-saving lamp unit, a first energy-saving lamp power supply module and a second energy-saving lamp power supply module, and the energy-saving lamp unit comprises a first energy-saving lamp and a second energy-saving lamp, the switch is electrically connected to the AC power supply device and the rectifier, the first energy-saving lamp power supply module is electrically connected to the first energy-saving lamp and the rectifier, the first The second energy-saving lamp power supply module is electrically connected to the second energy-saving lamp and the rectifier, and the energy-saving lamp switching device comprises:
An electrical energy storage unit electrically connected to the rectifier;
a bistable multivibrator electrically connected to the electrical energy storage unit, the first energy saving lamp power supply module and the second energy saving lamp power supply module; and a switching signal The input signal is electrically connected to the electrical energy storage unit and the bistable multivibrator. The energy-saving lamp switching device according to claim 1, further comprising an initial state selector electrically connected to the bistable multivibrator; wherein the initial state selector includes an initial A state capacitor, one end of the initial state capacitor is electrically connected to the flip-flop. The utility model relates to a switching energy-saving lamp power supply device, which is applied to an AC power supply device, a switch and an energy-saving lamp unit. The energy-saving lamp unit comprises a first energy-saving lamp and a second energy-saving lamp, and the switch is electrically connected to the AC The power supply device, the switching energy-saving lamp power supply device comprises:
a rectifier electrically connected to the switch;
a first energy-saving lamp power supply module, the first energy-saving lamp power supply module is electrically connected to the first energy-saving lamp and the rectifier;
a second energy-saving lamp power supply module, the second energy-saving lamp power supply module is electrically connected to the second energy-saving lamp and the rectifier;
An electrical energy storage unit electrically connected to the rectifier;
a bistable multivibrator electrically connected to the electrical energy storage unit, the first energy saving lamp power supply module and the second energy saving lamp power supply module; and a switching signal The input signal is electrically connected to the electrical energy storage unit and the bistable multivibrator. The switching energy-saving lamp power supply device of claim 3, further comprising an initial state selector electrically connected to the flip-flop multi-vibrator; wherein the initial state selector An initial state capacitor is included, and one end of the initial state capacitor is electrically connected to the flip-flop. The switching energy-saving lamp power supply device according to the third or fourth aspect of the invention, wherein the first energy-saving lamp power supply module or the second energy-saving lamp power supply module comprises:
a diode, the anode of the diode is electrically connected to the rectifier;
An input filter capacitor, the input filter capacitor is electrically connected to the cathode of the diode;
a power conversion unit electrically connected to the input filter capacitor and the energy saving lamp unit;
a starting unit electrically connected to the rectifier and an anode of the diode;
a start input, the start input is electrically connected to the start unit and the power conversion unit; and a split control interface, the split control interface is electrically connected to the start input and the bistable multi-resonant Device. The switching energy-saving lamp power supply device according to the third or fourth aspect of the invention, wherein the first energy-saving lamp power supply module or the second energy-saving lamp power supply module comprises:
a diode, the anode of the diode is electrically connected to the rectifier;
An input filter capacitor, the input filter capacitor is electrically connected to the cathode of the diode;
a power conversion unit electrically connected to the input filter capacitor and the energy saving lamp unit;
An undervoltage lockout detecting unit electrically connected to the rectifier and the anode of the diode;
An undervoltage lockout input terminal electrically connected to the undervoltage lockout detection unit and the power conversion unit; and a separate control interface electrically connected to the undervoltage lockout The input terminal and the bistable multivibrator. The switching energy-saving lamp power supply device according to the third or fourth aspect of the invention, wherein the first energy-saving lamp power supply module or the second energy-saving lamp power supply module comprises:
a diode, the anode of the diode is electrically connected to the rectifier;
An input filter capacitor, the input filter capacitor is electrically connected to the cathode of the diode and the energy saving lamp unit;
An electronic switch electrically connected to the energy saving lamp unit;
a biasing unit electrically connected to the rectifier and an anode of the diode;
a switch control input, the switch control input is electrically connected to the bias unit and the electronic switch; and a separate control interface, the separate control interface is electrically connected to the switch control input and the bistable State multivibrator. The switching energy-saving lamp power supply device according to the third or fourth aspect of the invention, wherein the first energy-saving lamp power supply module or the second energy-saving lamp power supply module comprises:
a power conversion unit electrically connected to the rectifier and the energy saving lamp unit;
a start input, the start input is electrically connected to the power conversion unit; and a separate control interface electrically connected to the start input and the bistable multivibrator. The switching energy-saving lamp power supply device according to the third or fourth aspect of the invention, wherein the first energy-saving lamp power supply module or the second energy-saving lamp power supply module comprises:
a power conversion unit electrically connected to the rectifier and the energy saving lamp unit;
An undervoltage lockout input terminal electrically connected to the power conversion unit; and a separate control interface electrically connected to the undervoltage lockout input terminal and the bistable multi-state Harmonic oscillator. The switching energy-saving lamp power supply device according to the third or fourth aspect of the invention, wherein the first energy-saving lamp power supply module or the second energy-saving lamp power supply module comprises:
a power conversion unit electrically connected to the rectifier and the energy saving lamp unit;
An overvoltage protection input terminal electrically connected to the power conversion unit; and a separate control interface, the separate control interface electrically connected to the overvoltage protection input terminal and the bistable multi Harmonic oscillator. The switching energy-saving lamp power supply device according to the third or fourth aspect of the invention, wherein the first energy-saving lamp power supply module or the second energy-saving lamp power supply module comprises:
a power conversion unit electrically connected to the rectifier and the energy saving lamp unit;
An overcurrent protection input terminal electrically connected to the power conversion unit; and a separate control interface, the separate control interface electrically connected to the overcurrent protection input terminal and the bistable multi Harmonic oscillator. The switching energy-saving lamp power supply device according to the third or fourth aspect of the invention, wherein the first energy-saving lamp power supply module or the second energy-saving lamp power supply module comprises:
An electronic switch electrically connected to the rectifier and the energy saving lamp unit; and a switch control input electrically connected to the electronic switch and the bistable multivibrator . The switching energy-saving lamp power supply device according to the third or fourth aspect of the invention, wherein the first energy-saving lamp power supply module or the second energy-saving lamp power supply module comprises:
a diode, the anode of the diode is electrically connected to the rectifier;
a power factor corrector electrically connected to the cathode of the diode;
a power conversion unit electrically connected to the power factor corrector and the energy saving lamp unit;
a starting unit electrically connected to the rectifier and an anode of the diode;
a start input, the start input is electrically connected to the start unit and the power conversion unit; and a split control interface, the split control interface is electrically connected to the start input and the bistable multi-resonant Device. The switching energy-saving lamp power supply device according to the third or fourth aspect of the invention, wherein the first energy-saving lamp power supply module or the second energy-saving lamp power supply module comprises:
a diode, the anode of the diode is electrically connected to the rectifier;
a power factor corrector electrically connected to the cathode of the diode;
a power conversion unit electrically connected to the power factor corrector and the energy saving lamp unit;
An undervoltage lockout detecting unit electrically connected to the rectifier and the anode of the diode;
An undervoltage lockout input terminal electrically connected to the undervoltage lockout detection unit and the power conversion unit; and a separate control interface electrically connected to the undervoltage lockout The input terminal and the bistable multivibrator. The switching energy-saving lamp power supply device according to the third or fourth aspect of the invention, wherein the first energy-saving lamp power supply module or the second energy-saving lamp power supply module comprises:
a power factor corrector, the power factor corrector being electrically connected to the rectifier;
a power conversion unit electrically connected to the power factor corrector and the energy saving lamp unit;
a starting unit electrically connected to the rectifier and the power factor corrector;
a start input, the start input is electrically connected to the start unit and the power conversion unit; and a split control interface, the split control interface is electrically connected to the start input and the bistable multi-resonant Device. The switching energy-saving lamp power supply device according to the third or fourth aspect of the invention, wherein the first energy-saving lamp power supply module or the second energy-saving lamp power supply module comprises:
a power factor corrector, the power factor corrector being electrically connected to the rectifier;
a power conversion unit electrically connected to the power factor corrector and the energy saving lamp unit;
An undervoltage lock detecting unit electrically connected to the rectifier and the power factor corrector;
An undervoltage lockout input terminal electrically connected to the undervoltage lockout detection unit and the power conversion unit; and a separate control interface electrically connected to the undervoltage lockout The input terminal and the bistable multivibrator. The switching energy-saving lamp power supply device according to the third or fourth aspect of the invention, wherein the first energy-saving lamp power supply module or the second energy-saving lamp power supply module comprises:
a boost type active power factor corrector, the boost type active power factor corrector being electrically connected to the rectifier;
a power conversion unit electrically connected to the step-up active power factor corrector and the energy saving lamp unit;
a starting unit electrically connected to the boosting active power factor corrector;
a start input, the start input is electrically connected to the start unit and the power conversion unit; and a split control interface, the split control interface is electrically connected to the start input and the bistable multi-resonant ,
Wherein the boost active power factor corrector comprises:
a control module electrically connected to the rectifier and the starting unit;
a boost diode, the anode of the boost diode is electrically connected to the control module and the starting unit; and a storage capacitor electrically connected to the cathode of the boost diode and the power conversion unit. The switching energy-saving lamp power supply device according to the third or fourth aspect of the invention, wherein the first energy-saving lamp power supply module or the second energy-saving lamp power supply module comprises:
a boost type active power factor corrector, the boost type active power factor corrector being electrically connected to the rectifier;
a power conversion unit electrically connected to the step-up active power factor corrector and the energy saving lamp unit;
An undervoltage lock detecting unit electrically connected to the boosting active power factor corrector;
An undervoltage lockout input terminal electrically connected to the undervoltage lockout detection unit and the power conversion unit; and a separate control interface electrically connected to the undervoltage lockout Input and the bistable multivibrator,
Wherein the boost active power factor corrector comprises:
a control module electrically connected to the rectifier and the undervoltage lock detecting unit;
a boosting diode, the anode of the boosting diode is electrically connected to the control module and the undervoltage lock detecting unit; and a storage capacitor electrically connected to the cathode of the boosting diode and the cathode Power conversion unit.