JP3177245U - LED lamp drive system for use in series-connected double tube rapid start ballast - Google Patents

Abstract

The present invention eliminates the need to change or replace the conventional lamp wiring and applies the principle of equivalent resistance to control the input current in direct proportion to the input voltage, thereby maintaining the light emission luminance of each lamp equal. An LED lamp driving system for use in a connected double tube rapid start ballast is provided.
An LED lamp driving system used in a series-connected double tube type rapid start ballast is applied to an LED lamp, and the LED lamp is attached to a lamp holder having a quick start ballast, and quick start stable. The device is electrically connected to an AC power source, and has at least two sets of input terminals, a rectifier / filter module 11, a DC / DC converter module 12, an LED lamp train 13, a start-up module 14, a current reference module 15, and a current feedback. A module 16 and a control module 17 are provided.
[Selection] Figure 2

Description

  The present invention relates to an LED lamp driving system for type-double tube rapid start ballast used in a series-connected double tube type rapid start ballast, and in particular, is applied in an LED lamp. Since a conventional fluorescent lamp can be directly replaced with an LED lamp, it is not necessary to change or replace the wiring of the conventional fluorescent lamp, and the principle of equivalent resistance is applied, and the input current is compared with the input voltage. It is related with the LED lamp drive system used for the rapid connection ballast of the serial connection type | mold double tube | pipe type which can control LED directly in proportion and can maintain the light emission brightness | luminance of each lamp | ramp equally.

  Please refer to FIG. As shown in FIG. 4, in a series-connected double tube type starter circuit combined with a conventional rapid start ballast, a first pin 41 and a second pin are connected to both ends of each lamp 4. Each of the pins 42 is provided. The 1st pin 41 and the 2nd pin 42 are each inserted in the insertion hole (not shown) of a socket, and fix a lamp | ramp. The two lamps 4 are connected to each other in series by a first pin 41 and a second pin 42. The first pin 41 and the second pin 42 are electrically connected to the quick start ballast 5 and then electrically connected to the AC power source 6, thereby forming a complete fluorescent lamp starting circuit. . In the lamp 4, a filament (not shown) is connected between the first pin 41 and the second pin 42 corresponding to each other, and the quick start ballast 5 supplies electricity to the filament in the lamp 4. When the electron is emitted upon receiving heat, the fluorescent lamp 4 emits light.

Please refer to FIG. As shown in FIG. 5, an internal detailed circuit diagram of a conventional LED lamp is shown, and the AC power supply of the _two input terminals AC ₁ and AC ₂ is changed from a rectifier / filter module 7 to a DC / DC converter module. (DC-to-DC converter module) 8 DC power is supplied, current is fed back from the current sampling resistor R _S to the PWM control chip 9 and compared with the internal reference level 250 mV, and the pulse width (pulse width) is set. Determine and control by flowing diode current.

However, when the conventional LED lamp is actually used, it has the following drawbacks. The LED lamp power input actually has only what is equivalent to the _two end points (AC ₁ and AC ₂ ) shown in FIG. When replacing a conventional fluorescent lamp with an LED lamp, it is necessary to change the conventional lamp. This change is mainly to remove the ballast and the tangent of the starting circuit connected in parallel to the lamp, so that the user's willingness to use the LED lamp is reduced and the utilization rate may be lowered. . In addition, in order to save the cost of the ballast, the conventional lamp uses two lamps connected in series and shares the design method of the so-called quick start ballast 5 (see FIG. 4). In the constant current drive design method, when the lamps are used in series connection, the voltage distribution between the two lamps becomes non-uniform and the constant current is limited.

  The purpose of the present invention is to provide two sets of input terminals on both sides of the lamp, thereby eliminating the need for the user to change the conventional fluorescent lamp to an LED lamp, change or replace the conventional lamp wiring, and equivalent resistance. An LED lamp driving system for use in a series-connected double tube rapid starting ballast that applies the above principle to control the input current in direct proportion to the input voltage and keeps the luminous brightness of each lamp equal. There is.

  In order to solve the above problems, according to a first embodiment of the present invention, the LED lamp is applied to a lamp holder having a quick start ballast, and the quick start ballast is an alternating current. Series connection with at least two sets of input terminals, rectifier / filter module, DC / DC converter module, LED lamp train, start-up module, current reference module, current feedback module and control module while being electrically connected to the power source LED tube driving system for use in a rapid start ballast of a double tube type, wherein the input terminals are a set of two and are provided at both ends of the LED lamp, respectively, and the quick start ballast The rectifier / filter module is electrically connected to the input terminal, respectively. The DC / DC converter module is electrically connected to the rectifier / filter module using the current rectifier filter of the AC power source as a DC power source and including two commutators electrically connected to the input terminals. The connected DC power source is converted into a DC power source having a predetermined voltage value, and the LED lamp row is electrically connected to the DC / DC converter module, and a plurality of diode light emitting elements connected in series with each other are connected. And the start-up module is connected to the rectifier / filter module and the DC / DC converter module that stabilize the pressure of the fluctuating input DC power source and outputs a safe operating voltage, respectively, and the current reference module includes the rectifier / Filter module and the DC / DC converter module The rectifier / filter module and the DC / DC converter module output a reference current signal that is directly proportional to an input voltage, and the current feedback module is electrically connected to the DC / DC converter module; The DC / DC converter module captures an output current flowing through the LED lamp train, and the control module is electrically connected to the start-up module, the current reference module, the current feedback module, and the DC / DC converter module, respectively. The PWM signal is generated by comparing the output current of the LED lamp array output from the current feedback module with the reference current signal output from the current reference module, and the DC / DC converter module is turned on. Characterized by controlling the time of state An LED lamp driving system is provided for use in a rapid start ballast with a series-connected double tube type.

  The LED lamp drive system used in the series-connected double tube rapid start ballast of the present invention has two sets of input terminals on both sides of the lamp so that the user can change the conventional fluorescent lamp to an LED lamp, It eliminates the need to change or replace the conventional lamp wiring and applies the principle of equivalent resistance to control the input current in direct proportion to the input voltage, thereby maintaining the light emission luminance of each lamp equal.

It is a schematic diagram which shows the series connection type diode double tube type starting circuit which combined the conventional rapid starting ballast. 1 is a circuit block diagram showing an LED lamp driving system used in a series-connected double tube rapid start ballast according to an embodiment of the present invention. 1 is a circuit diagram showing an LED lamp driving system used in a series-connected double tube rapid start ballast according to an embodiment of the present invention; It is an architecture figure which shows the serial connection type | mold double tube type starting circuit which combined the conventional quick start ballast. It is a circuit diagram which shows the inside of the conventional LED lamp in detail.

Please refer to FIG. 1 and FIG. As shown in FIGS. 1 and 2, the LED lamp driving system used in the series connected double tube type rapid start ballast according to an embodiment of the present invention is applied in the LED lamp 1. This LED lamp 1 is mounted on a lamp holder having a quick start ballast 2. The quick start ballast 2 is electrically connected to the AC power source 3. The driving system of the LED lamp 1 includes two sets of input terminals AC ₁ and AC ₂ and input terminals BC ₁ and BC ₂ , a rectifier / filter module 11, a DC / DC converter module 12, an LED lamp string 13, FIG. 3 shows a detailed circuit and connection method including a start-up module 14, a current reference module 15, a current feedback module 16, and a control module 17.

Two sets of input terminals AC ₁ , AC ₂ and input terminals BC ₁ , BC ₂ are one set, and are provided on both ends of the LED lamp 1 and electrically connected to the quick start ballast 2. ing.

The rectifier / filter module 11 is electrically connected to the two sets of input terminals AC ₁ and AC ₂ and the input terminals BC ₁ and BC _2, and uses the current rectification filter of the AC power source 3 as a DC power source. Includes _two commutators DB ₁ and DB ₂ electrically connected to two sets of input terminals AC ₁ and AC ₂ and input terminals BC ₁ and BC ₂ , respectively. Each of the two commutators DB ₁ and DB ₂ is a bridge rectifier. These two commutators DB ₁ and DB ₂ are electrically connected to a π-type filter circuit, respectively. This π-type filter circuit includes an inductor L _X1 and two capacitors C _x1 and C ₁ connected to the inductor L _X1 and connected in parallel.

The DC / DC converter module 12 is electrically connected to the rectifier / filter module 11. The received DC power is converted into a DC power having a predetermined voltage value. In the present embodiment, the step-down DC / DC converter module 12 will be described as an example. One end of the switching element S ₁ of the step-down DC / DC converter module 12 of the present embodiment is connected to the input terminal, and the switching element S ₁ May be a transistor switch. In this embodiment, a MOSFET is used as the switching element S _1, causes the drain terminal of the switching element S ₁ diode D ₀ and electrically connected. The other end of the diode D ₀ is the inductor L ₀ and is electrically connected to the other end of the inductor L _0, the diode D ₀ and a is electrically connected in parallel connected capacitors C _0. The source end of the switching element S ₁ is electrically connected to the current feedback module 16.

  The LED lamp row 13 is electrically connected to the DC / DC converter module 12. The LED lamp row 13 includes a plurality of diode light emitting elements 131 connected in series. The LED lamp row 13 of this embodiment is connected in parallel with the capacitor of the DC / DC converter module 12.

The startup module 14 is connected to a rectifier / filter module 11 and a DC / DC converter module 12 that stabilize the pressure of the fluctuating input DC power supply and output a safe operating voltage. Activation module 14 of the present embodiment is a resistor R _3.

The current reference module 15 is connected to the rectifier / filter module 11 and the DC / DC converter module 12 respectively. The rectifier / filter module 11 and the DC / DC converter module 12 are used to output a reference current signal that is directly proportional to the input voltage to the control module 17. Current reference module 15 includes a rectifier / ground end of the filter module 11 and electrically connected to the Schottky barrier diode (Schottky barrier diode) D _S, the negative electrode of the Schottky barrier diode D _S and the rectifier / filter module 11 It includes a first resistor R ₁ which is electrically connected between a second resistor R ₂ connected in parallel with the Schottky barrier diode D _S, a.

The current feedback module 16 is electrically connected to the DC / DC converter module 12. The DC / DC converter module 12 takes in the output current flowing through the LED lamp row 13 and outputs it to the control module 17. The current feedback module 16 of this embodiment is a current sampling resistor R _S.

The control module 17 is electrically connected to the activation module 14, the current reference module 15, the current feedback module 16, and the DC / DC converter module 12. The control module 17 compares the output current of the LED lamp train 13 output from the current feedback module 16 with the reference current signal output from the current reference module 15, and then generates a PWM signal to generate a DC / DC converter module. Controls the time of 12 on states. The control module 17 includes is connected to a source terminal electrically switching element S _1, a pulse width modulator which controls the on-off switching element S ₁ a (pulse width modulator). The pulse width modulator controls the ON (On) / off the switching element S ₁ (Off).

  The LED lamp drive system used in the series-connected double tube type rapid start ballast of the present invention provides two sets of input terminals on both sides of the LED lamp, so that the user can change the conventional fluorescent lamp to the LED lamp. At the same time, there is no need to change or replace the conventional lamp wiring, and accordingly, the user's willingness to use the LED lamp is increased and the utilization rate is increased, and the input voltage and input current of the current reference module are Applying the principle that the ratio is equivalent resistance, the LED lamp current is controlled, and when using the LED lamps connected in series, the input voltage is evenly distributed to keep the luminous brightness of each lamp equal. It becomes possible.

  The preferred embodiments of the present invention have been disclosed as described above, so that those skilled in the art can understand them. However, these descriptions do not limit the present invention. Various changes and modifications can be made without departing from the spirit and scope of the present invention. Accordingly, the scope of the utility model registration claim of the present invention should be broadly interpreted including such changes and modifications.

DESCRIPTION OF SYMBOLS 1 LED lamp 2 Quick start ballast 3 AC power supply 4 Lamp 5 Quick start ballast 6 AC power supply 7 Rectifier / filter module 8 DC / DC converter module 9 PWM control chip 11 Rectifier / filter module 12 DC / DC converter module 13 LED lamp Column 14 Start-up module 15 Current reference module 16 Current feedback module 17 Control module 41 First pin 42 Second pin 131 Light emitting element AC ₁ input terminal AC ₂ input terminal BC ₁ input terminal BC ₂ input terminal C ₀ capacitor C ₁ capacitor C _X1 capacitor D ₀ diode D _S Schottky barrier diode DB ₁ commutator DB ₂ commutator L _X1 inductor L ₀ inductor R ₁ first resistor R ₂ second resistor R ₃ resistor R _OSC resistor R _S current sampling resistor R _S current sampling resistor S ₁ Switching element

Claims (1)

Applied to LED lamp, the LED lamp is mounted on a lamp holder having a quick start ballast, the quick start ballast is electrically connected to an AC power source and at least two sets of input terminals, a rectifier / An LED lamp driving system for use in a series-connected double tube rapid starting ballast, comprising a filter module, a DC / DC converter module, an LED lamp row, a starting module, a current reference module, a current feedback module and a control module. And
The input terminal is a set of two, provided on both ends of the LED lamp, and electrically connected to the quick start ballast,
The rectifier / filter module includes two commutators that are electrically connected to the input terminals, use a current rectifying filter of the AC power supply as a DC power supply, and are electrically connected to the input terminals, respectively.
The DC / DC converter module is electrically connected to the rectifier / filter module, and converts the received DC power to a DC power having a predetermined voltage value.
The LED lamp row includes a plurality of diode light emitting elements electrically connected to the DC / DC converter module and connected in series to each other,
The start-up module is connected to the rectifier / filter module and the DC / DC converter module that stabilize the pressure of the fluctuating input DC power supply and output a safe operating voltage, respectively.
The current reference module is connected to the rectifier / filter module and the DC / DC converter module, respectively, and the rectifier / filter module and the DC / DC converter module output a reference current signal that is directly proportional to an input voltage. ,
The current feedback module is electrically connected to the DC / DC converter module, and the DC / DC converter module captures an output current flowing through the LED lamp train,
The control module is electrically connected to the start-up module, the current reference module, the current feedback module, and the DC / DC converter module, respectively, and an output current of the LED lamp array output from the current feedback module; A series connected double tube type characterized in that the reference current signal output from the current reference module is compared to generate a PWM signal, and the on-state time of the DC / DC converter module is controlled. LED lamp drive system used for rapid start ballast.

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