KR20150140905A - Separate control LED lamp driving device, and the LED lamp comprising the driving device. - Google Patents

Abstract

In recent, importance of the green industry for saving energy has been highlighted. Accordingly, distribution of LED lamps is being activated, but it is not easy to design an LED converter (SMPS for an LED lamp) when alternating input voltage such as 380-440 V_AC is quite higher than 220 V_AC. An SMPS component part for an input voltage 220 V_AC has been commercialized as a general component, but an SMPS component for an input voltage of 380-440 V_AC should have internal pressure of two or more times compared to a component for 220 V_AC. According to a division control-type LED lamp driving device and LED lamp having the same of the present invention, an LED lamp is driven by dividing an input bridge rectifying current, so a component of an LED lamp driving device driven by high voltage input voltage exceeding 440 V_AC may be produced as a general component for SMPS used for 220 V_AC. Accordingly, costs competence and energy efficiency of an LED lamp driving device for a high input voltage and an LED lamp for a high input voltage are remarkably improved.

Description

[0001] The present invention relates to an LED lamp driving apparatus and a LED lamp using the LED lamp driving apparatus,

The present invention relates to a split-type LED lamp driving apparatus and an LED lamp equipped with the same. When the commercial AC input voltage is much higher than 220V _AC , the design of the converter [SMPS for LED lamp] that drives the LED lamp is not simple. This is because the internal voltage of components (capacitors, switching FETs, etc.) to be used here must be 2 to 3 times higher than that of existing [220V _AC ] components. The invention consists of LED lamps used for extremely high AC input voltage in excess of 440V _AC also relates to enabling a normal part of an existing [for 220V _AC].

In recent years, lighting lamps including fluorescent lamps have been in the trend of replacing them with LED lamps which are similar in appearance, can share sockets, and are efficient, in order to save energy. However, since the LED element embedded in the LED lamp is driven by DC, the LED converter that drives the LED lamp receives the commercial AC input power and converts it to the DC power which is optimal for the LED lamp and supplies it to the LED element embedded in the lamp Is a kind of SMPS [Switching Mode Power Supply]. SMPS parts for inputting AC power of 220V _AC and converting it into DC [DC] voltage are general parts, but in order to convert AC power of 380V _AC or 440V _AC into DC [DC] power, Specifications should be at least twice as high as the withstand voltage specifications of SMPS components with 220V _AC input conditions. However, SMPS components with a breakdown voltage more than twice that of parts for 220V _AC are hardly commercialized, and it is very difficult to configure a converter for LED lamps satisfying the input voltage of 380V _AC to 440V _AC . However, in factories such as oil refineries and steel factories, many of them use 380V _AC or 440V _AC lighting to reduce power loss in factories. In order to replace existing lighting lamps with efficient LED lamps in such factories, LED lamp driving devices with 380V _AC or 440V _AC input conditions are required. The present invention provides a split-controlled LED lamp capable of driving an LED lamp with only a conventional general-purpose component even under such a high-voltage input condition.

An object of the present invention is a LED lamp with a driving LED lamp driving device and a driving apparatus as possible to high input voltage exceeding 380V _AC ~ 440V _AC to provide.

이하로 낮추어 상용화 되어 있는 일반 스위칭소자를 사용하도록 하는 것이다.Because the LED, which is the light emitting element of the LED lamp, operates as a DC power source, the LED converter, which is an LED lamp driving device, is the Switching Mode Power Supply (SMPS) for LED lamps. When the input voltage is 220V _AC , the bridge rectification voltage is about 310V _{DC. For} the ripple filter capacitor used here, a capacitor with a 400V internal voltage is usually used considering the variation of the input voltage. Also, in the SMPS, a switching FET configured in series with a primary coil of a switching transformer is used. When the FET is switched off, the voltage induced by the counter electromotive force on the primary coil of the switching transformer is twice And the internal voltage of the FET used in the SMPS is generally 800 V or more. From this point of view, the internal pressure of the SMPS FET driven at the input voltage of 440V _AC should be more than 1600, and such FET is not commercialized. In the present invention, the LED array, which is a component of the LED lamp, is divided into an LED array driven at an upper voltage and an LED array driven at a lower voltage to control the breakdown voltage of the switching element [FET]

Or less, so as to use a general switching device that has been commercialized.

In the present invention, after bridge rectification of a high AC input voltage, the LED array is separated into approximately two LED arrays [11] which conduct in an upper voltage section and an LED array [21] conducts in a lower voltage section, By connecting the LED arrays through the diode [D ₂ ] and configuring them in series, the upper section LED array [11] does not control the current, and the lower section LED array [21] so, to the normal components are a high withstand voltage 380V _Ac ~ LED lamp configuration for a high input voltage of 440V is to be _Ac.

Split-controlled LED lamp and the LED lamp driving apparatus equipped with a driving device of the present invention because they drive the LED lamp in a manner that a control to divide the voltage for LED even if La and an input voltage of 380V _{Ac Ac} ~440V lamp LED It is possible to increase the price competitiveness of the lamp and to spread the spread of the LED lamp in an industrial field using a voltage higher than a general household voltage.

: 접지단자
RPB : 래피드방식 형광등 안정기
B : [전류 제어하지 않는] B 램프
B₁ : B 램프의 LED 램프 구동장치
A : [전류 제어하는]A 램프
A₁ : A 램프의 LED 램프 구동장치Figure 1 is an exemplary example using a bridge rectifier circuit block diagram of the invention 1 and the diode [D _2] the interval division by using a circuit showing a first embodiment the partition control block diagram and FIG.
Fig. 2 is a circuit diagram and block diagram showing one embodiment in which two bridge rectifier circuit blocks are used for division in a divided manner in another embodiment of the present invention; Fig.
3 is a circuit diagram and block diagram showing an embodiment in which the present invention is applied to a rapid start type fluorescent lamp substitution type LED lamp
Description of the Related Art
AC: Commercial AC power source
B ₁ : LED lamp driving device
B ₂ : LED matrix array
a: Lower [current-controlled] interval LED array driver
b: Upper [non-current-controlled] interval LED array driver
1: first bridge rectifier circuit block
2: second bridge rectifier circuit block
11: LED array for upper [no current control] section
21: LED array for low [current control] section
3: Overcurrent blocking circuit block
4: Current control circuit block
5: Energy charge / discharge circuit block
F: Hughes
LF1: Line filter
C: Condenser
D ₁ , D ₂ : first and second diodes
D ₁₁ to D ₁₄ : A bridge rectifier diode of the first bridge rectifier circuit block
D ₂₁ to D ₂₄ : bridge rectifier diode of the second bridge rectifier circuit block
C ₁ to C ₃ : First to third capacitors
C ₁₁ to C ₂₁ : Eleventh and twenty-first capacitors
R _CS : Current detection resistor
+: Bridge rectification + output terminal
-: Bridge rectification - Output terminal

: Ground terminal
RPB: Rapid type fluorescent ballast
B: [no current control] B lamp
B ₁ : LED lamp driving device of B lamp
A: [Current control] A lamp
A ₁ : LED Lamp Drive of A Lamp

In order to accomplish the above object, an operation principle of an LED lamp driving apparatus and a LED lamp equipped with the driving apparatus of the present invention will be described in detail with reference to the drawings. 1 is an embodiment showing an embodiment of the present invention. It is a general circuit configuration that an AC AC input electrical signal is applied to a bridge rectifier circuit block 1 through a fuse [F] and a noise filter circuit. Rectifying the AC input electrical signal of 380 V _{AC with} the bridge rectifier circuit block [1] consisting of four diodes [D ₁₁ , D ₁₂ , D ₁₃ , D ₁₄ ] and the capacitor [C ₁ ] Becomes about 537 V _DC . this

267 V _DC + 270 V _DC = 537 V _DC ... ... ... ... ... ... ... ... ... ... ... (One)

The upper array is divided into 267 V _DC and the lower section is divided into 270 V _DC, and the LED array [11] operating in the upper section has the forward voltage [V _F ]

V _F = 3.0V ... ... ... ... ... ... ... ... ... ... ... ... ... ... ... ... ... ... ... (2)

It is assumed that 89 LED elements are connected in series and the LED array [21] operating in the lower section is constituted by connecting 90 LED elements having the V _F voltage of the formula (2) in 30 series and 3 series. Since the upper LED array [11] does not control the current, it is always on [ON] and the lower LED array [21] controls the current while the current control circuit block [4] turns on and off at a frequency of about 50 kHz. 1, the upper section LED array 11 and the lower section LED array 21 are connected in series via the diode [D ₂ ], and the upper section LED array 11 is always in an ON condition Therefore, if the bridge rectification (+) voltage is 537 V _DC , the voltage across the anode of the LED array [2]

537 (V _DC ) - 267 (V _DC ) -0.7 (V _DC )? 270 (V _DC ) ... ... ... (3)

. The voltage drop [Drop] in the lower-stage LED array 21 will be 90 V _DC because the lower-stage LED array 21 is composed of 30 series and 3 parallel. As a result, the cathode voltage of the lower section LED array [21]

270 (V _DC ) - 90 (V _DC ) = 180V _DC ... ... ... ... ... ... ... ... ... ... ... (4)

. This 180 [V _DC ] voltage is applied to the first coil [L ₁ ] of the energy charge / discharge circuit block [5]. 1, the overcurrent shutoff circuit block [3] is always switched on unless an overcurrent flows through the LED lamp, and the switch incorporated in the current control circuit block [4] is on and off at a speed of about 50 kHz · OFF], control the constant current to flow through the LED arrays [11, 21] of the LED lamp. The LED array voltage for the upper section and the LED array voltage for the lower section are set to be substantially the same because the two LED arrays are connected in series so that the average current is the same so that the assigned voltages are the same so that the brightness of each LED is the same . The reason why the LED array of the lower section LED array is arranged in 30 series and 3 parallel is that the on / off time ratio of the current control circuit block [4]

1: 2 ... ... ... ... ... ... ... ... ... ... ... (5)

]로 쇼트되지만 오프타임에는 제 1 다이오드[D₁]에 의하여 하위 구간용 LED 어레이[21]의 애노드단자에 클램핑[Clamping] 되어 있으므로 상기 식(3)에서 270 V_DC 를 초과할 수 없다. 결과적으로 전류제어 회로블럭 내의 스위칭소자의 내압이

로 줄어든 셈이다. 뿐만 아니라 분할제어하지 않을 경우는 L₁ 의 인덕턴스[inductance]값을 2 배로 올려야하기 때문에 분할제어 시에 비하여 코일[L₁] 로스[loss]가 2 배로 증가한다. 하위 구간용 LED 어레이[21]의 LED 어레이는 오픈타임에도 전류가 흐르기 때문에 3 병렬 구성한 것이고 온·오프 타임비를 1:1 로 설계할 경우는 2 병렬로 구성한다. 도 2 는 본 발명의 또 다른 실시 예에 대한 회로구성도 및 블럭도로, 브릿지정류회로블럭을 상위 LED 어레이[11]구동용[1]과 하위 구간용 LED 어레이[21]구동용[2]으로 분리해서 사용한 경우로, 동작원리는 상기 도 1 의 실시 예에 있어서와 같다. 도 3 은 본 발명을 래피드스타트방식 형광등 안정기에 사용하는 형광램프 대체형 LED 램프에 사용한 1 실시 예에 대한 회로구성도 및 블럭도이다. 상기 도 2 의 실시 예에 있어서와 같은 회로구성으로 래피드스타트방식 형광등은 반드시 2 개의 램프가 페어[pair]로 직렬 연결되어 사용 되어야하므로, 램프마다 브릿지 정류회로블럭[1]을 1 개씩 구성해야 하고, 전류 제어하지 않는 LED 램프[B]와 전류제어를 하는 LED 램프[A]가 페어[pair]로 사용 되어야 한다. 전류제어를 하지 않는 LED 램프[B]의 LED 배열은 60 직렬 2 병렬로 구성하고, 전류제어를 하는 LED 램프[A]의 LED 배열은 20 직렬 6 병렬로 구성하여 2 램프의 LED 총 수는 동일하게 하되, 상기 B 램프의 직렬연결 LED 단수가, A 램프의 직렬연결 LED 단수의 3 배가 되게 구성하는 것이 가장 바람직하다.So that all the LED elements in one lamp emit light of the same brightness by making the currents flowing in all the LED elements of the LED lamp equal to each other. In addition the switching element is on-time, the ground terminal via the resistor [R _CS] for current detection current control circuit built into the block [4]

But it can not exceed 270 V _DC in the above equation (3) since it is clamped to the anode terminal of the lower-stage LED array [21] by the first diode [D ₁ ] in the off-time. As a result, the breakdown voltage of the switching element in the current control circuit block

. In addition, when the divided control is not performed, since the inductance value of L ₁ must be doubled, the coil [L ₁ ] loss is doubled as compared with the divided control. The LED arrays of the sub-section LED arrays [21] are configured in three parallel structures because current flows even in the open time. When the on / off time ratio is designed as 1: 1, the LED arrays are configured in two parallel structures. FIG. 2 is a circuit diagram and block diagram of another embodiment of the present invention, in which the bridge rectifier circuit block is driven to drive the upper LED array [11] and the lower section LED array [21] And the operation principle is the same as in the embodiment of FIG. Fig. 3 is a block diagram and block diagram of one embodiment in which the present invention is applied to a fluorescent lamp replacement type LED lamp used in a rapid start type fluorescent lamp ballast. In the circuit configuration as in the embodiment of FIG. 2, the rapid start type fluorescent lamp must be connected in series with two lamps. Therefore, one bridge rectifying circuit block [1] , A non-current controlled LED lamp [B] and a current controlled LED lamp [A] should be used as a pair. The LED array of the LED lamp [B] which does not control the current is constituted by 60 series 2 parallel, and the LED array of the LED lamp [A] which controls the current is constituted by 20 series and 6 parallel, , It is most preferable that the number of the series-connected LEDs of the B lamp is three times the number of the series-connected LEDs of the A lamp.

Claims (4)

An LED lamp driving device [B 2] including an LED matrix array [B ₂ ], a bridge rectifier circuit block [1], an overcurrent shutoff circuit block [3], a current control circuit block [4] ₁ ], the LED matrix array [B ₂ ] is divided into an LED array [11] that does not control current and an LED array [21] that performs current control, Is connected to the (+) output terminal of the bridge rectifier circuit block 1, the cathode terminal of the LED array 11 is connected to the anode terminal of the (second) diode D _{2, and} the anode terminal of the D the cathode terminal of the _second is one of a LED array, [21] connected to the anode terminal and the LED array [21] the cathode terminal of the first coil of the block [5] the energy charging and discharging circuit of [L _1] in which the current control Terminal of the coil [L ₁ ] is branched and one branch of the coil [L ₁ ] is connected to the terminal Connected to one terminal of the current control circuit block [4] and the other branch is connected to the anode terminal of the LED array [21] performing the current control through the first diode [D ₁ ], and the current control circuit block [4 ] the other terminal is a ground terminal via the resistor [R _CS] for current detection of [

, The LED array [11], which does not control the current, controls the LED array [11] to be always on, and the LED array [21] to control the current is repeatedly turned on and off, So that a constant current is maintained
Split control type LED lamp. The LED matrix array B ₂ is embedded in an LED lamp which is divided into an array 11 in which current is not controlled and an LED array 21 in which current is controlled. The bridge rectifier circuit block 1 and the overcurrent shutoff circuit block [ 3, the current control circuit block [LED lamp drive device [according to B _1], the anode terminal of [11] LED array that does not have the current control containing 4] and block [5] the energy charging and discharging circuit the bridge The cathode terminal of the LED array 11 is connected to the anode terminal of the (second) diode D ₂ and the cathode of the diode D ₂ is connected to the (+) output terminal of the rectifying circuit block 1, And the cathode terminal of the LED array 21 is connected to one terminal of the first coil L ₁ of the energy charging and discharging circuit block 5 And one terminal of the coil [L ₁ ] is branched and one branch is connected to the current control Is connected to one terminal of the circuit block [4] and the other one is connected to the anode terminal of the current-controlled LED array [21] through the first diode [D ₁ ] the other terminal is a ground terminal via the resistor [R _CS] for current detection [

, The LED array [11] which does not control the current is controlled to be always on [ON] condition, and the LED array [21] which performs the current control is repeatedly turned on and off, [21] to maintain a constant current
Split control type LED lamp driving device. The bridge rectifier circuit block according to claim 1, wherein two bridge rectifier circuit blocks are constituted by a first bridge rectifier circuit block [1] and a second bridge rectifier circuit block [2] And the cathode terminal of the LED array 11 is connected to the (-) terminal of the first bridge rectifying circuit block 1, and the current control is performed by connecting the anode terminal of the LED array 11 [ The anode terminal of the LED array 21 is connected to the positive output terminal of the second bridge rectifying circuit block 2 and the cathode terminal of the LED array 21 is connected to the first terminal of the energy charging and discharging circuit block 5 coil [L _1] connected to the terminal of the other terminal of the coil [L _1] is a branch place the branch is connected to one terminal of the block [5] the current control circuit and the other branch comprises a first diode [ D ₁ ], the anode terminal of the LED array [21] Connected to the chair and the ground terminal the other terminal of the current control circuit block [4] through the resistor [R _CS] for current detection [

, The LED array [11] which does not control the current is controlled to be always on [ON] condition, and the LED array [21] which performs the current control is repeatedly turned on and off, [21] to maintain a constant current
Split control type LED lamp. An LED lamp according to claim 3, comprising an LED lamp [B] composed of the first bridge rectifier circuit block [1] and the current-controlled LED array [11] One input terminal of the first bridge rectifier circuit block 1 is connected to one of the two caps of the two caps of the LED lamp B and the other input terminal of the first bridge rectifier circuit block 1 is connected to the LED lamp B, The LED array [21] and the overcurrent shutoff circuit block [3], the current control circuit block [4], and the second bridge rectifier circuit block [2] And an energy input terminal of the second bridge rectifying circuit block is connected to one of two caps of the LED lamp [A] so as to constitute an LED lamp [A] composed of an energy charge and discharge circuit block [5] And one of the two input terminals of the second bridge rectifier circuit block [2] Terminal is connected to any one terminal of the other one of the LED lamps [A] so that the A lamp and the B lamp are used as a pair in the rapid fluorescent lamp ballast [RPB]
Split control type LED lamp.

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