JP3213524U - High efficiency LED lamp tube - Google Patents

Abstract

A high-efficiency LED capable of solving the flicker problem by connecting high voltage and low current in series, making the current uniform, matching lamp operation and improving efficiency, reducing and effectively removing ripples Provide a light tube. The LED lamp tube includes a radiator lamp base 10, a board 11 on which the lamp lamp 14 is installed, and is electrically connected to the board. And a constant current drive module that turns on each LED lamp by a high voltage input and a low current output of 400 V or higher. The heatsink base is provided with a shade 13 covering the substrate, which can improve efficiency and reduce the generation of heat. [Selection] Figure 3

Description

  The present invention relates to an LED lamp tube, and more particularly to a highly efficient LED lamp tube.

In recent years, light emitting diode (hereinafter referred to as LED) illumination technology has been developed. For example, it is widely used in daily life, such as messages, communications, indicators and display equipment for general consumer electronic products. In particular, when white light LEDs appear, they are used as light sources or lighting products, opening a new era. Light sources or lighting products are the largest potential market for LEDs. LEDs are environmentally friendly and have advantages such as energy saving, high efficiency, long service life, small volume and fast response, avoiding the disadvantages of traditional fluorescent lamps, environmentally friendly and CO ₂ emissions Reduction and energy saving effect can be achieved.

  As a document disclosing the conventional LED illumination technique, there is Patent Document 1 below. The lighting system disclosed in Patent Document 1 includes two or more LED groups each including one or more individual LEDs and current distribution means, and an LED system having two input terminals and two inputs of the LED system. A single controllable driver for supplying operating power to the LED system, and a controller for controlling the driver, each having two output terminals coupled to the terminals. With the illumination system disclosed in Patent Document 1, the amount and color of light emitted from the LED can be adjusted.

  However, in the illumination system disclosed in Patent Document 1, when any one of the plurality of LED lamps is not turned on, all the LED lamps may not be turned on at the same time.

Special table 2014-502411 gazette

  Since the conventional LED lamp provides a low voltage and a high current to the LED lamp of the LED lamp tube, if one LED lamp cannot be turned on, all the LED lamps may not be turned on. In addition, when trying to install LED lamp tubes corresponding to long-distance irradiation, the number of LED lamps in the LED lamp tubes is limited due to low voltage and high current, and cannot be installed infinitely. The average number is only 15-20. Combining multiple LED lamp tubes together, for example, provides five LED lamp tubes with a voltage of 90V and a current of 150mA, one is 28mA, the other is 32mA, the other is 27mA, etc. , Efficiency will be reduced. Therefore, in the conventional LED lamp tube, the cost of the electronic member is high. When the current is increased at the output end, the current change is increased, and the cost of the capacitor is increased.

  Therefore, in order to improve the problems of the above-described conventional configuration and to improve the industrial implementation, it is necessary for the deviser to develop a new LED lamp tube.

  In order to achieve the above object, according to the technical means employed in the present invention, there are at least 50 LED lamps installed on the radiator lamp base and connected to the radiator lamp base in electrical series. An LED lamp tube that includes an installed board and a constant current drive module that is electrically connected to the board and lights each LED lamp with a high voltage input and a low current output. The LED lamp tube is characterized in that a shade covering the substrate is provided.

  Preferably, a fixing tank for fixing the substrate is installed inside the radiator lamp base.

  Preferably, an attachment tub for attaching the shade is installed outside the radiator lamp base.

  Preferably, the radiator lamp base further includes an external radiator base in which a housing space for housing the radiator lamp base is installed.

Preferably, the constant current driving module includes an AC filter module, a rectifying filter module, an activation module, an auxiliary driving module, a control module, an energy storage module, an output voltage module, and an output current module,
The AC filter module and the rectifying filter module receive and rectify and filter the power from the external AC power source, generate a pulsed DC voltage,
The pulse DC voltage generates an operating voltage by connecting the starting module to the output terminal of the rectifying filter module,
When the operating voltage by the activation module is greater than the control module threshold, the control module is activated to drive the energy storage module and control the LED lamp voltage;
The control module outputs a voltage signal to the start module, stabilizes the voltage through the auxiliary drive module, charges the start module,
The output voltage module is filtered to obtain the sampling voltage, transmits the sampling voltage to the control module, and when the sampling voltage is greater than the control module's internal reference voltage, the control module conduction time is reduced,
When the voltage drop from the output current module is filtered and transmitted to the control module, and the voltage drop is greater than the control module's internal reference voltage, the control module conduction time is reduced, and a low current is output to the board, each LED Turn on the lamp.

  Preferably, the constant current drive module generates a DC voltage of 400 V or more with a high voltage input and a low current output.

  In the present invention, at least 50 LED lamps that are directly connected in series to the board are installed directly on the substrate, and each LED lamp that is lit by a high voltage input and low current output in a constant current drive module is colored. Match the temperature and lifetime, achieve the highest level of luminous efficiency, reduce the change of current, reduce the cost of the capacitor. In addition, since this invention is a high voltage | pressure output more than 400V, it can improve efficiency and can reduce | generate the production | generation of a heat capacity. By connecting the high voltage and low current in series, the current can be made uniform, the operation of the lamp is matched and its efficiency is improved, the ripple is reduced and effectively eliminated, and the flicker problem can be solved.

  In order to clarify the above objects, technical features, and advantages after implementation, preferred embodiments according to the present invention will be described in detail below with reference to the drawings. It should be noted that those skilled in the art can easily understand the objects and advantages of the present invention based on the contents disclosed in the present invention, the scope of claims for registration, and the diagrams.

It is a perspective view which shows the three-dimensional structure of the highly efficient LED lamp tube of this invention. It is sectional drawing which shows the highly efficient LED lamp tube of this invention. It is sectional drawing which shows the other highly efficient LED lamp tube of this invention. It is a block diagram which shows the constant current drive module of this invention.

  1, 2, and 4, which are a perspective view, a cross-sectional view, and a block diagram showing a constant current driving module of the present invention, respectively, showing a three-dimensional configuration of the highly efficient LED lamp tube of the present invention. . A high-efficiency LED lamp tube 1 of the present invention is installed on a radiator lamp base 10 and a radiator lamp base 10, and a substrate 11 on which at least 50 LED lamps 14 connected in series with each other are installed. A constant current drive module 12 that is electrically connected to the substrate 11 and lights up the respective LED lamps 14 with a high voltage input and a low current output, and a shade 13 that is installed on the radiator lamp base 10 and covers the substrate 11. With.

  1 and 2 show an LED lamp tube 1 according to the first embodiment, in which a fixing tank 100 for fixing a substrate 11 is mainly installed inside a radiator lamp base 10 and outside the radiator lamp base 10. A mounting tank 102 for mounting the shade 13 is installed. If the LED lamps 14 installed on the substrate 11 are 150 LED lamps as an example, the constant current drive module 12 includes an AC filter module 120, a rectifying filter module 121, an activation module 122, an auxiliary drive module 123, , Control module 124, energy storage module 125, output voltage module 126, and output current module 127. The rectifying filter module 121 includes a plurality of diodes, a plurality of capacitors, and an inductor. The startup module 122 includes a plurality of resistors, a plurality of MOSFETs, a diode, and a plurality of capacitors. The auxiliary drive module 123 includes a diode, a low voltage discharge tube, a capacitor, and a transformer. The control module 124 includes a plurality of resistors, a plurality of capacitors, and a diode. The energy storage module 125 includes a transformer, a MOSFET, and a plurality of resistors. The output voltage module 126 includes a plurality of resistors. The output current module 127 includes a plurality of resistors, a diode, and a capacitor.

  When the LED lamp tube 1 is activated by receiving power from an AC power source, the power forms a DC voltage by the AC filter module 120 and the rectifying filter module 121. The DC voltage is divided into the MOSFET of the starting module 122 by one resistor connected to the output terminal of the rectifying filter module 121 of the starting module 122 and the other resistor of the starting module 122, and the operating voltage. Is generated.

  When the gate voltage of the MOSFET of the start-up module 122 is greater than the minimum operating voltage, the MOSFET charges the capacitor of the start-up module 122 by limiting one resistor of the start-up module 122. When the voltage across one capacitor of the activation module 122 is larger than the threshold voltage of the control module 124, the control module 124 is activated, and the MOSFET of the energy storage module 125 is driven as a switch by the one resistor, and the duty ratio is increased. It changes and controls the transformer of the energy storage module 125, stores the energy storage time of the inductor, and controls the voltage of the LED lamp at the output end.

  When the power is stably supplied, the control module 124 starts and outputs a voltage signal, passes through one resistor of the start module 122, current-limits the MOSFET of the start module 122, and drives it to saturation. The voltage level of the other MOSFETs in the start-up module 122 drops and cuts off, and stops charging the capacitor of the start-up module 122. The control module 124 is supplied with power by limiting the current through the resistor and capacitor of the auxiliary driving module 123, and charges the capacitor of the start-up module 122 through rectification by a diode and stabilization by a low voltage discharge tube.

  When entering a constant voltage state, power is divided by each resistor of the output voltage module 126 to other resistors and filtered to generate a sampling voltage, which is transmitted into the control module 124. When the sampling voltage is greater than the internal reference voltage of the control module 124, the conduction time of the MOSFET of the control module 124 is controlled and reduced. When the sampling voltage is smaller than the internal reference voltage of the control module 124, the conduction time of the MOSFET of the control module 124 is controlled and increased.

  In the constant current state, the voltage drop due to the current flowing through the resistor of the output current module 127 is sensed, and the voltage drop is transmitted to the control module 124 through filtering by the resistor and the capacitor. If the voltage is greater than the internal reference voltage of the control module 124, the control module 124 controls and reduces the conduction time of the MOSFET. When the voltage is smaller than the internal reference voltage of the control module 124, the control module 124 controls and increases the conduction time of the MOSFET.

  In the present invention, 150 LED lamps that are directly connected in series to the substrate 11 are installed, and the LED lamps that are lit by the high voltage input and low current output by the constant current drive module 12 are respectively Match the color temperature and lifetime, achieve the highest level of luminous efficiency, reduce the current change, and reduce the capacitor cost. In addition, since this invention is a high voltage | pressure output more than 400V, it can improve efficiency and can reduce | generate the production | generation of a heat capacity. By connecting the high voltage and low current in series, the current can be made uniform, the operation of the lamp is matched and its efficiency is improved, the ripple is reduced and effectively eliminated, and the flicker problem can be solved.

  Among them, in a preferred embodiment, the constant current drive module 12 increases the DC voltage to 400 V or higher by high voltage input and low current output, and makes the current uniform by a booster circuit to improve the output voltage. The voltage drops and is filtered, and finally the current becomes low and is output to the substrate 11 to light each LED lamp. Each lit LED lamp, color temperature and lifetime are matched, the highest level of luminous efficiency, reduced current change, and reduced capacitor cost.

  Referring to FIG. 3, they are perspective views showing a three-dimensional configuration of another highly efficient LED lamp tube of the present invention. The LED lamp tube 1 is installed on the radiator lamp base 10, the radiator lamp base 10, the board 11 on which at least 50 LED lamps 14 connected in series with each other are installed, and the board 11 is electrically connected. Connected to each other, and includes a constant current driving module 12 that lights each LED lamp 14 by a high voltage input and a low current output, and a shade 13 that is installed on the radiator lamp base 10 and covers the substrate 11.

  FIG. 3 shows the LED lamp tube 1 of the second embodiment and refers to FIG. In the LED lamp tube 1, a fixing tank 100 for fixing the substrate 11 is mainly installed inside the radiator lamp base 10, and an external radiator base 15 is installed outside the radiator lamp base 10. A housing space 150 for housing the heat-radiating lamp base 10 is installed inside the housing. If the LED lamps 14 installed on the substrate 11 are 150 LED lamps as an example, the constant current drive module 12 includes an AC filter module 120, a rectifying filter module 121, an activation module 122, an auxiliary drive module 123, , Control module 124, energy storage module 125, output voltage module 126, and output current module 127. The rectifying filter module 121 includes a plurality of diodes, a plurality of capacitors, and an inductor. The startup module 122 includes a plurality of resistors, a plurality of MOSFETs, a diode, and a plurality of capacitors. The auxiliary drive module 123 includes a diode, a low voltage discharge tube, a capacitor, and a transformer. The control module 124 includes a plurality of resistors, a plurality of capacitors, and a diode. The energy storage module 125 includes a transformer, a MOSFET, and a plurality of resistors. The output voltage module 126 includes a plurality of resistors. The output current module 127 includes a plurality of resistors, a diode, and a capacitor.

  When the LED lamp tube 1 is activated by receiving power from an AC power source, the power forms a DC voltage by the AC filter module 120 and the rectifying filter module 121. The DC voltage is divided into the MOSFET of the starting module 122 by one resistor connected to the output terminal of the rectifying filter module 121 of the starting module 122 and the other resistor of the starting module 122, and the operating voltage. Is generated.

  When the gate voltage of the MOSFET of the start-up module 122 is greater than the minimum operating voltage, the MOSFET charges the capacitor of the start-up module 122 by limiting one resistor of the start-up module 122. When the voltage across one capacitor of the activation module 122 is larger than the threshold voltage of the control module 124, the control module 124 is activated, and the MOSFET of the energy storage module 125 is driven as a switch by the one resistor, and the duty ratio is increased. It changes and controls the transformer of the energy storage module 125, stores the energy storage time of the inductor, and controls the voltage of the LED lamp at the output end.

  When the power is stably supplied, the control module 124 starts and outputs a voltage signal, passes through one resistor of the start module 122, current-limits the MOSFET of the start module 122, and drives it to saturation. The voltage level of the other MOSFETs in the start-up module 122 drops and cuts off, and stops charging the capacitor of the start-up module 122. The control module 124 is supplied with power by limiting the current through the resistor and capacitor of the auxiliary driving module 123, and charges the capacitor of the start-up module 122 through rectification by a diode and stabilization by a low voltage discharge tube.

  When entering a constant voltage state, power is divided by each resistor of the output voltage module 126 to other resistors and filtered to generate a sampling voltage, which is transmitted into the control module 124. When the sampling voltage is greater than the internal reference voltage of the control module 124, the conduction time of the MOSFET of the control module 124 is controlled and reduced. When the sampling voltage is smaller than the internal reference voltage of the control module 124, the conduction time of the MOSFET of the control module 124 is controlled and increased.

  In the constant current state, the voltage drop due to the current flowing through the resistor of the output current module 127 is sensed, and the voltage drop is transmitted to the control module 124 through filtering by the resistor and the capacitor. If the voltage is greater than the internal reference voltage of the control module 124, the control module 124 controls and reduces the conduction time of the MOSFET. When the voltage is smaller than the internal reference voltage of the control module 124, the control module 124 controls and increases the conduction time of the MOSFET.

  In the present invention, 150 LED lamps that are directly connected in series to the substrate 11 are installed, and the LED lamps that are lit by the high voltage input and low current output by the constant current drive module 12 are respectively Match the color temperature and lifetime, achieve the highest level of luminous efficiency, reduce the current change, and reduce the capacitor cost. In addition, since this invention is a high voltage | pressure output more than 400V, it can improve efficiency and can reduce | generate the production | generation of a heat capacity. By connecting the high voltage and low current in series, the current can be made uniform, the operation of the lamp is matched and its efficiency is improved, the ripple is reduced and effectively eliminated, and the flicker problem can be solved.

  Although the invention made by the inventor has been specifically described based on the embodiment, the invention is not limited to the embodiment described above, and various modifications can be made without departing from the scope of the invention. Needless to say.

  From the above results, the present invention breaks through the conventional technology, reliably achieves the effect to be promoted, and the requirements such as the inventive step and practicality that it provides can be easily conceived by those skilled in the art. is not.

DESCRIPTION OF SYMBOLS 1 LED lamp tube 10 Radiant lamp base 100 Fixed tank 102 Mounting tank 11 Board | substrate 12 Constant current drive module 120 AC filter module 121 Commutation filter module 122 Startup module 123 Auxiliary drive module 124 Control module 125 Energy storage module 126 Output voltage module 127 Output current Module 13 Shade 14 LED lamp 15 External heat dissipation base 150 Storage space

Claims (6)

A radiator lamp base,
A board on which at least 50 LED lamps are installed on the radiator lamp base and connected in electrical series with each other;
A constant current drive module that is electrically connected to the substrate and illuminates each of the LED lamps with a high voltage input and a low current output, and an LED lamp tube comprising:
An LED lamp tube characterized in that a shade covering the substrate is installed on the radiator lamp base.   The LED lamp tube according to claim 1, wherein a fixing tank for fixing the substrate is installed inside the radiator lamp base.   The LED lamp tube according to claim 2, wherein an attachment tub for attaching the shade is installed outside the radiator lamp base.   The LED lamp tube according to claim 1, wherein the heat-radiating lamp base further includes an external heat-radiating base in which an accommodation space for accommodating the heat-radiating lamp base is installed. The constant current drive module includes an AC filter module, a rectification filter module, a start-up module, an auxiliary drive module, a control module, an energy storage module, an output voltage module, and an output current module,
The AC filter module and the rectifying filter module receive and rectify and filter power from an external AC power source to generate a pulsed DC voltage,
The pulse direct current voltage generates an operating voltage by connecting the start-up module to the output terminal of the rectifying filter module,
If the operating voltage by the activation module is greater than the control module threshold, the control module is activated to drive the energy storage module to control the voltage of the LED lamp;
The control module outputs a voltage signal to the activation module, stabilizes the voltage through the auxiliary drive module, charges the activation module,
The output voltage module is filtered to obtain a sampling voltage, transmits the sampling voltage to the control module, and when the sampling voltage is greater than the internal reference voltage of the control module, the conduction time of the control module is reduced,
When the voltage drop from the output current module is filtered and transmitted to the control module, and the voltage drop is greater than the internal reference voltage of the control module, the conduction time of the control module is reduced and a low current is transferred to the substrate. The LED lamp tube according to claim 1, wherein each of the LED lamps is turned on.   2. The LED lamp tube according to claim 1, wherein the constant current driving module generates a DC voltage of 400 V or more by a high voltage input and a low current output.