JP3171411U - Lighting device control circuit module - Google Patents

Abstract

A user can directly replace a conventional fluorescent lamp with an LED fluorescent lamp in which a control circuit module of a lighting device is matched, and specify two contact points of a power input terminal of the LED fluorescent lamp in advance. There is provided a control circuit module of a lighting device that is not necessary. A first bridge rectification unit 11, a second bridge rectification unit 12, a power factor correction circuit unit 13, a control unit 14, a feedback unit 15, at least one switch unit 16, and at least one step-up / step-down unit 17 are provided. Is provided. In order to easily match the interior of the LED fluorescent lamp, the control circuit module of this lighting device is built on an electronic chip, so that the user does not need to specify the two contacts of the power input terminal in advance. It is possible to directly replace the fluorescent lamp with the LED fluorescent lamp in which the control circuit module of the lighting device is matched. [Selection] Figure 5

Description

  The present invention relates to a control circuit module, and more particularly to a control circuit module of a lighting device that can be adapted to a fluorescent lamp.

  Fluorescent lamps are bright and eye-friendly light sources that require lighting in houses, shops, offices, schools, supermarkets, hospitals or commercial showcases, advertising light cases, subways, walking tunnels, night shops, etc. Everywhere you can see the use of fluorescent lights. Fluorescent lamps can usually be illuminated or extinguished under the control of an activation circuit.

  This will be described with reference to the structural diagram of a known fluorescent lamp starting circuit shown in FIG. As shown in FIG. 1, the structure of a known fluorescent lamp starting circuit includes a ballast 12 ', a power switch 13', a power source 14 ', and a starter 15'. Among them, the fluorescent lamp tube 11 ′ is coupled to the ballast 12 ′, the power source 14 ′, and the starter 15 ′, and the power switch 13 ′ is provided between the power source 14 ′ and the ballast 12 ′.

  As is well known, the electricity utilization efficiency of a known fluorescent lamp starting circuit is not very good. The main cause is the high pressure required to start. In addition, since the fluorescent lamp tube 11 ′ emits light due to electric discharge, the fluorescent lamp tube 11 ′ and the starter 15 ′ are consumables and need to be replaced periodically. In practice, it is not so difficult for a general person to replace the fluorescent lamp tube 11 ′ or the starter 15 ′. However, if the ballast 12 ′ breaks down, the general person may replace the new ballast 12 ′. It is impossible to do.

  Therefore, while there are many drawbacks in the structure of the known fluorescent lamp, the conventional fluorescent lamp is gradually replaced by the LED fluorescent lamp, and the fluorescent lamp manufacturer controls the LED fluorescent lamp. Electronic ballasts have been put on the market. A description will be given with reference to the structural diagram of the LED type fluorescent lamp of the electronic ballast shown in FIG. As shown in FIG. 2, to assemble the structure of the LED fluorescent lamp with the electronic ballast attached, after connecting the four contacts on both sides of the LED fluorescent lamp 11 ″ to the electronic ballast 16 ″, The assembly can be completed by connecting the power plug 161 '' of the electronic ballast 16 '' to the electrical socket.

  2 will be described with reference to the internal structure diagram of the electronic ballast shown in FIG. In the internal structure of the electronic ballast 16 ″ shown in FIG. 3, the electronic ballast 16 ″ includes an AC / DC conversion circuit 162 ′ and a DC / AC conversion circuit 163 ″. The AC / DC conversion circuit 162 ″ includes a bridge type rectifier circuit 1621 ″ and a filter capacitor Cf ″. The DC / AC conversion circuit 163 ″ includes a control unit 1631 ″, a first switch unit 1632 ″, a second switch unit 1633 ″, a harmonic vibration unit 1634 ″, a starting capacitor Cav ″, and a first output capacitor. Cout1 ″ and a second output capacitor Cout2 ″. By such an internal circuit structure of the electronic ballast 16 ″, the LED fluorescent lamp tube 11 ″ can be switched and provided to provide a light source for illumination.

  All electronic ballasts 16 '' at the present time are reduced in size to match the LED fluorescent lamp 11 '', and the user can replace the conventional fluorescent lamp tube with the LED fluorescent lamp 11 ''. However, as shown in FIGS. 2 and 3, the electronic ballast 16 ″ uses two contacts at one end of the LED fluorescent lamp 11 ″ at the power input end. Therefore, when the user cannot find two contact points at the 'power input end of the LED type fluorescent lamp 11' at the time of the replacement work, the fluorescent lamp cannot be replaced. For this reason, inconvenience is given to the attachment of the LED type fluorescent lamp.

  Therefore, the present inventor has noticed that the structure of the LED fluorescent lamp with the known fluorescent lamp tube start circuit and electronic ballast attached still has many drawbacks, and as a result of repeated research and development, The control circuit module of the lighting device was devised.

  The main purpose of the present invention is to align the inside of the LED fluorescent lamp, so that the user can directly replace the conventional fluorescent lamp with the LED fluorescent lamp in which the control circuit module of the lighting device is aligned. It is possible to provide a control circuit module of a lighting device that does not need to specify two contact points of an LED type fluorescent lamp power supply input terminal in advance.

  In order to achieve the object of the present invention, the present inventor proposes a control circuit module of a lighting device that is electrically connected to at least one lighting device and can switch and control light emission of the lighting device. The control circuit module of the lighting device is

  A first bridge rectifier coupled to a power source;

  A second bridge rectifier coupled to the power source;

  A power repulsion factor correction circuit that is coupled to the first bridge rectifier and the second bridge rectifier at the same time and corrects a power signal output from the second bridge rectifier or the second bridge rectifier; ,

  A control unit coupled to a power factor correction circuit unit, receiving the power signal corrected by the power factor correction circuit unit and outputting a control signal; and the control unit includes at least one single-stage oscillator And a comparator.

  A feedback unit coupled to the control unit and receiving a control signal output from the control unit;

  The feedback unit and at least one switch unit coupled to the control unit;

  And at least one step-up / step-down unit coupled to the switch unit and having at least one activation inductor.

  Among them, in order to control the light emission of the lighting device, a control signal is output from a single-stage oscillator provided in the control unit, and the control signal is coupled to the switch unit by the feedback unit and is conducted to the switch unit. Further, after the switch unit is turned on, a current signal is generated from a starting inductor provided in the step-up / step-down unit, and the starting current is output to the lighting device to drive light emission of the lighting device.

  Among them, when the lighting device emits light, a current signal is fed back to the feedback unit from the starting inductor. At this time, the current signal is converted into a feedback voltage signal by the feedback unit and then input to the control unit. The feedback voltage signal is monitored and compared by a comparator provided inside the control unit. When the peak value of the signal exceeds a predetermined voltage value, a control signal is output from the control unit, the switch unit is turned off, and the current signal value for driving the light emission of the lighting device is kept constant.

  The following description clearly discloses the electric circuit structure of the control circuit module of the lighting device of the present invention and its application. As described above, the control circuit module of the lighting device according to the present invention has the following advantages as compared with the known fluorescent lamp starting circuit and the structure of the LED fluorescent lamp equipped with the electronic ballast.

  I. By adapting the control circuit module of the lighting device of the present invention to the inside of the LED fluorescent lamp, the user can replace the LED fluorescent lamp, which directly matches the control circuit module of the lighting device with the conventional fluorescent lamp. It is not necessary to specify two contact points of the LED type fluorescent lamp power supply input terminal in advance.

  B. The control circuit module of the lighting device of the present invention can be finished as an electronic chip and replaced with a driver chip of a conventional LED lamp. In addition, when the electronic chip finished with the control circuit module of the lighting device of the present invention fails, the user can replace it by taking out the shade and the power input end of the LED lamp, There is no need to specify the power input end of the power supply, which is very convenient.

It is a structural diagram of the starting circuit of a well-known fluorescent lamp. It is a structural diagram of the LED type fluorescent lamp attached with the electronic ballast. It is an internal structure figure of an electronic ballast. It is a structural diagram of the control circuit module of the lighting device of the present invention. It is a structural diagram of the internal circuit of the control circuit module of the lighting device. It is a three-dimensional view of the LED type fluorescent lamp of a matching type illumination device control circuit module. It is an explosion diagram of the LED lamp of a matching type lighting device control circuit module.

  In order to describe the control circuit module of the lighting device of the present invention in more detail, a preferred embodiment of the present invention will be described in detail with reference to the drawings as follows.

  A description will be given with reference to the structural diagram of the control circuit module of the lighting device of the present invention shown in FIG. As shown in FIG. 4, the control circuit module 1 of the lighting device of the present invention includes a first bridge rectification unit 11, a second bridge rectification unit 12, a power factor correction circuit unit 13, a control unit 14, a feedback unit 15, The switch unit 16, the two step-up / step-down units 17, and one voltage adjustment capacitor CVR are provided.

  Next, with reference to FIG. 4, description will be made with reference to the structural diagram of the internal circuit of the control circuit module of the lighting device shown in FIG. As shown in FIGS. 4 and 5, the first bridge rectification unit 11 and the second bridge rectification unit 12 are coupled to the power source 3. The power factor correction circuit unit 13 includes a first diode D1, a second diode D2, a third diode D3, a first capacitor C1, a second capacitor C2, a third capacitor C3, and a fourth capacitor C4. It is coupled to the bridge rectification unit 11 and the second bridge rectification unit 12, and provides output signal correction from the first bridge rectification unit 11 or the second bridge rectification unit 12.

The control unit 14 is coupled to the power factor correction circuit unit 13 and receives the power signal corrected by the power factor correction circuit unit 13 and outputs a control signal. Among them, the control unit 14 includes at least one single-stage oscillator (not shown) and a comparator (not shown). The feedback unit 15 includes a low-pass filter capacitor CLP, a low-pass filter capacitor RLP, and at least one feedback resistor RFB. The feedback unit 15 is coupled to the control unit 14 and receives a control signal output from the control unit 14.
The feedback resistor RFB of the feedback unit 15 shown in FIG. 5 is obtained by connecting four resistors in parallel. The two switch units 16 are respectively coupled to the feedback unit 15 and the control unit 14. Further, in the structure of the electric circuit of the control circuit module 1 of the lighting device, the switch unit 16 may be a metal oxide semiconductor field effect transistor (MOSFET) or a bipolar junction transistor (BJT). Preferably, a MOSFET is used for the switch unit 16 as in this embodiment.

  The step-up / step-down unit 17 includes a Schottky diode Ds and a starting inductor LAC, and is coupled to the switch unit 16. When switching the electric circuit of the control circuit module 1 of the lighting device of the present invention to cause the lighting device 2 to emit light, a single stage oscillator provided in the control unit 14 outputs a control signal, and the feedback unit 15 controls the control signal. Are coupled to the switch unit 16 to make the switch unit 16 (MOSFET) conductive. Subsequently, the start-up inductor LAC included in the boost / buck unit 17 starts charging, and boosting is performed on the control signal. At this time, a current signal is output from the starting inductor LAC to the lighting device 2, and the lighting device 2 is driven to emit light.

  Subsequently, when the lighting device 2 emits light, the current signal is fed back to the feedback unit 15 by the activation inductor LAC. At this time, the feedback capacitor RFB of the feedback unit 15 converts the current signal into a feedback voltage signal, and the surge wave of the feedback voltage signal is filtered by the low-pass filter combined with the low-pass filter capacitor CLP and the low-pass filter register RLP. . Subsequently, the feedback voltage signal filtered by the low-pass filter is input to the feedback unit 14, and the feedback voltage signal is compared and compared by a comparator provided in the control unit 14, and the peak value of the feedback voltage signal is a predetermined voltage value. Is exceeded, the control unit 14 outputs a control signal, turns off the switch unit 16, and maintains a constant current signal value for driving the light emission of the lighting device 2.

  By the above description, the electric circuit structure of the control circuit module 1 of the illuminating device of this invention and its operation principle are disclosed. Here, it should be particularly explained that the lighting device 2 may be an LED fluorescent lamp, an LED lamp, or a conventional fluorescent lamp. In addition, the number of the switch units 16 and the step-up / step-down units 17 is not limited to two sets. When there are two or more sets of lighting devices 2 connected to the control circuit module 1 of the lighting device, the number of switch units 16 and step-up / step-down units 17 must be adjusted according to the number of lighting devices 2.

  If an LED fluorescent lamp is used in the lighting device 2, the control circuit module 1 of the lighting device of the present invention is implemented on one electric circuit board, and a plurality of LED chips are attached to the electric circuit board. An LED fluorescent lamp can also be used. A description will be given with reference to a three-dimensional view of the LED fluorescent lamp of the matching illumination device control circuit module shown in FIG. As shown in FIG. 6, the LED fluorescent lamp 4 in which the control circuit module 1 of one lighting device is matched includes a shade 40, an electric circuit board 41, a plurality of LED chips 42, four power input terminals 43, Is provided. As shown in FIG. 6, the control circuit module 1 of the lighting device of the present invention is implemented on the electric circuit board 41 and controls the light emission of the plurality of LED chips 42. Further, as shown in FIG. 6, the four power input contacts 43 provided in the control circuit module LED type fluorescent lamp 4 of the lighting device of the present invention include two sets of bridge rectifiers (each provided in the control circuit module 1 of the lighting device). 11, 12). Therefore, when the user replaces the conventional fluorescent lamp with the LED fluorescent lamp 4 in which the control circuit module of the lighting device of the present invention is matched, the user can directly replace the conventional fluorescent lamp with the control circuit of the lighting device of the present invention. The module can be replaced with a matched LED fluorescent lamp, and it is not necessary to specify two contact points from the power input end of the LED fluorescent lamp 4 in advance.

  In addition, the control circuit module 1 of the lighting device of the present invention can be finished into an electronic chip and soldered on an electric circuit board having a plurality of LED chips. A description will be given with reference to the explosion diagram of the LED lamp of the matching illumination device control circuit module shown in FIG. As shown in FIG. 7, the LED lamp 4a in which the control circuit module of the lighting device is matched includes a shade 40a, an electric circuit board 41a, a plurality of LED chips 42a, and a power input end 43a. Among them, the control circuit module 1 of the lighting device according to the present invention is finished as an electronic chip and is mounted on the electric circuit board 41a corresponding to the plurality of LED chips 42a. Similarly, as shown in FIG. 7, when using the LED lamp 4a in which the control circuit module of the lighting device is matched, the power input terminal 43a is connected to the power source. That is, it is very convenient that it only needs to be plugged into a predetermined power outlet. In addition, when the electronic chip finished in the control circuit module 1 of the lighting device fails, the user takes out the shade 40a and the power input terminal 43a of the LED lamp 4a in advance, so that the power input terminal on the electric circuit board in advance. There is no need to specify.

  The foregoing detailed description describes the preferred embodiment of the present invention. However, this embodiment does not add any limitation to the present invention. Any application or modification of an effect based on the technical spirit of the present invention should be included in the scope of the present invention.

DESCRIPTION OF SYMBOLS 1 Control circuit module of illuminating device 2 Illuminating device 3 Power supply 11 1st bridge rectification part 12 2nd bridge rectification part 13 Power factor correction circuit part 14 Control part 15 Feedback part 16 Switch part 17 Step-up / step-down part CVR Voltage adjustment capacitor D1 1st 1 diode D2 2nd diode D3 3rd diode C1 1st capacitor C2 2nd capacitor C3 3rd capacitor C4 4th capacitor CLP low pass filter capacitor RLP low pass filter resistor RFB feedback resistor Ds Schottky diode LAC starting inductor 12 'ballast 13' power supply Switch 14 'Power supply 15' Starter 11 "LED type fluorescent lamp 16" Electronic ballast 162 "AC / DC converter circuit 163" DC / AC converter circuit 1621 "Bridge rectification Path Cf ″ filter capacitor 1631 ″ control unit 1632 ″ first switch unit 1633 ″ second switch unit 1634 ″ harmonic oscillation unit Cav ″ starting capacitor Cout1 ″ first output capacitor Cout1 ″ second output Capacitor 4 LED fluorescent lamp 40 Shade 41 Electric circuit board 42 LED chip 43 Power input terminal 4a LED lamp 40a Shade 41a Electric circuit board 42a LED chip 43a Power input terminal

Claims (10)

A control circuit module of a lighting device that is electrically connected to the lighting device and controls light emission of the lighting device,
The control circuit module of the lighting device is
A first bridge rectifier connected to a power source;
A second bridge rectifier connected to the power source;
A power repulsion factor correction circuit that is coupled to the first bridge rectifier and the second bridge rectifier at the same time and corrects a power signal output from the second bridge rectifier or the second bridge rectifier; ,
A control unit that is coupled to the power factor correction circuit unit and receives the power signal corrected by the first bridge rectification unit and outputs a control signal,
Having at least one single-stage oscillator and a comparator;
A feedback unit coupled to the control unit and receiving a control signal output from the control unit;
The feedback unit and at least one switch unit coupled to the control unit;
At least one step-up / step-down unit coupled to the switch unit and having at least one activation inductor.
When the lighting device is switched to emit light, a control signal is output from a single stage oscillator provided in the control unit, and the control unit is coupled to the switch unit by the feedback unit, and the switch unit is made conductive. Subsequently, after the switch unit is turned on, a current signal is generated from the startup inductor provided in the step-up / step-down unit, the startup current is output to the lighting device, and the lighting device is driven to emit light.
When the lighting device emits light, the current signal is fed back to the feedback unit from the startup inductor, the current signal is converted into a feedback voltage signal by the feedback unit, and then input to the control unit. The feedback voltage signal is monitored and compared by a comparator provided in the unit. When the peak value of the signal exceeds a predetermined voltage value, the control unit outputs a control signal to turn off the switch unit. And a constant current signal value for driving light emission of the lighting device is maintained.   The lighting device control according to claim 1, further comprising a voltage adjustment capacitor coupled to the power factor correction circuit unit and the control unit, wherein the voltage of a power signal input to the control unit is stabilized. Circuit module.   The control circuit module of the lighting device according to claim 1, wherein the control circuit module can be matched to at least one of the lighting devices implemented on an electric circuit board.   The illumination according to claim 1, wherein the power factor correction circuit unit includes a first diode, a second diode, a third diode, a first capacitor, a second capacitor, a third capacitor, and a fourth capacitor. Device control circuit module.   The control circuit module according to claim 1, wherein the feedback unit includes a low-pass filter capacitor and a low-pass filter register.   The control circuit module of the lighting device according to claim 1, wherein the switch unit is one of a metal oxide semiconductor field effect transistor (MOSFET) or a bipolar junction transistor (BJT).   The control circuit module of the lighting device according to claim 1, wherein the step-up / step-down unit further includes a Schottky diode.   2. The control circuit module of the lighting device according to claim 1, wherein the lighting device is an LED fluorescent lamp, an LED lamp, or a conventional fluorescent lamp.   9. The control circuit module of the lighting device according to claim 8, wherein a plurality of LED chips implemented on the electric circuit board are soldered to the electric circuit board to finish the lighting device.   9. The control circuit module of the lighting device according to claim 8, wherein the control circuit module can be soldered onto the electric circuit board having a plurality of LED chips after being finished into an electronic chip.

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