KR20060111763A - Half-bridge inverter - Google Patents

Abstract

A half-bridge inverter is provided to reduce a manufacturing cost and the size of products by not requiring an additional peripheral circuit for circuit protection. A half-bridge inverter includes a transformer(Tr), an external driving switch(Q1), a self driving switch(Q2), and a resonating capacitor(C3). The transformer(Tr) has a primary winding, a secondary winding, and an auxiliary winding. The external driving switch(Q1) is connected to the primary winding and a ground and is controlled by a square control signal. The self driving switch(Q2) is connected to the primary winding, the auxiliary winding, and a DC power source and controlled by an output voltage of the auxiliary winding. The resonating capacitor(C3) is connected to the secondary winding. And, the square control signal controls the switching of the external driving switch(Q1) and the output voltage of the auxiliary winding controls the switching of the self driving switch(Q2) to introduce the direct current into the primary winding of the transformer(Tr).

Description

Half-Bridge Inverter {HALF-BRIDGE INVERTER}

1 is a schematic circuit diagram of a half bridge inverter circuit for driving a load according to the prior art;

2 is a schematic diagram showing an output control signal of a half bridge control chip and a voltage waveform of an AC power supply according to the prior art;

3 is a schematic circuit diagram of a half bridge inverter circuit for driving a load according to the present invention;

4A-4F are schematic diagrams showing the operation of a circuit in one cycle in accordance with the present invention; And

5 is a schematic diagram illustrating waveforms in one cycle of a circuit in accordance with the present invention.

The present invention relates to a half-bridge inverter, and more particularly, to a half-bridge inverter for performing inversion by switching the external drive switch and the self-drive switch.

As electronic and computer devices become more complex, power supplies are becoming more important than ever. There are two main types of power supplies: linear and switching. Since the switching type is advantageous over the linear type, most power supplies are switching types.

The power supply for the backlight of the TFT panel mainly uses a DC-AC inverter circuit for power conversion and drives a cold cathode fluorescent lamp (CCFL) for illumination. Using different circuit configurations, conventional inverter circuits are generally divided into half bridge inverter circuits, full bridge inverter circuits, and push-pull inverter circuits, which are inverter circuits for converting direct current into alternating current.

U.S. Patent 5,615,093 discloses a half bridge inverter circuit. 1 is a schematic circuit diagram of a half bridge inverter circuit for driving a load. In Fig. 1, transformer T1 divides the circuit into a primary circuit and a secondary circuit, and a feedback network 30 is connected between these two circuits. The primary circuit includes a DC power supply (VDD), two electronic switches (Q1 and Q2), a half bridge control chip 10, and an LCC resonant network 40, the secondary circuit including a lamp load 20 do. Referring to FIG. 2 together with FIG. 1, an output control signal and an AC voltage waveform of a half bridge control chip according to the related art are schematically illustrated. The half bridge control chip 10 outputs the control signals D1 and D2 using two output stages LFET1 and LFET2, and the control signals D1 and D2 switch the two electronic switches Q1 and Q2, respectively. To control. By switching the two electronic switches Q1 and Q2, the power of the direct current power source is supplied to the primary winding of the transformer T1 via the LCC resonant network 40 to define the AC power source ac. An AC power source ac is provided for supplying power to the transformer T1, and the transformer T1 steps up and converts the AC power into the secondary winding to drive the lamp load 20.

In the above description, the half bridge inverter circuit disclosed in US Pat. No. 5,615,093 has a half bridge control having at least two outputs for directly driving the power switches Q1 and Q2 and controlling the AC connection of the switches Q1 and Q2. Chip 10 is required. In addition, the half bridge control chip 10 needs to control the first switch Q1 and the second switch Q2 to alternate for a short time by alternately turning on / off the switch. Therefore, in order to prevent electrical connection of the first switch Q1 and the second switch Q2 which will destroy both the first switch Q1 and the second switch Q2, the control signal D1 as shown in FIG. And D2) needs to have some dead time.

In addition, the control signals D1 and D2 change the signal period to supply power to the load according to the power requirements of the lamp load 20 and control the switching of the first switch Q1 and the second switch Q2. There is a need. The half bridge control chip 10 needs to protect the circuit according to the conditions fed back from the load stage such as, for example, too low voltage output, too high voltage output, open circuit of the lamp, overheating and the like. The outputs of the control signals D1 and D2 are adapted to switch off the first switch Q1 and the second switch Q2 in order to achieve the circuit protection function.

As described above, the conventional half bridge inverter circuit has a half bridge control chip 10 having two drive signals for driving the half bridge circuit. On the other hand, a protection circuit for protecting the second circuit of the transformer is also required. This requirement causes a problem of high cost and excessively large product size.

It is an object of the present invention to provide a half-bridge inverter that performs inversion by using a PWM integrated circuit and switching external drive switches and self-drive switches. The external drive switch is controlled by a square wave signal and works in conjunction with a self-driven switch to convert DC power into AC power to power at least one lamp.

The present invention includes a transformer having a primary winding, a secondary winding, and an auxiliary winding. The transformer is connected to an external drive switch. This externally driven switch is connected to the primary winding and ground of the transformer and controlled by a square wave signal. The self-driving switch is connected to the primary winding of the transformer, the auxiliary winding, and the direct current power source and controlled by the output voltage of the auxiliary winding. The resonant capacitor is connected to the secondary winding. Therefore, the present invention controls the switching of the external drive switch using a square wave signal and the switching of the self-drive switch using the output voltage of the auxiliary winding. By alternately switching these switches, a direct current power source is introduced into the primary winding of the transformer while detecting an alternating voltage in the secondary winding of the transformer. This AC voltage is converted into AC power through a resonant capacitor. In addition, the external drive switch of the present invention includes a first polar capacitor (or additional capacitor) and a first interface diode (or additional diode) between two output gates in the external drive switch. The self-drive switch of the present invention includes a second polar capacitor (or additional capacitor) and a second interface diode (or additional diode) between two output gates in the self-drive switch. Thus, the square wave signal and the output voltage of the auxiliary winding control the switching of the external drive switch and the self drive switch, respectively, to charge and discharge the polar capacitor (or additional capacitor) and the second polar capacitor (or additional capacitor) by the DC power supply. . This charge and discharge power is supplied to the primary winding of the transformer to detect an alternating voltage in the secondary winding of the transformer and converted to AC power by a resonant capacitor.

Hereinafter, with reference to the accompanying drawings will be described in detail the aspects and advantages of the present invention.

3 is a schematic circuit diagram of a half bridge inverter according to the present invention. The half bridge inverter of the present invention is controlled by a square signal (S _PWM ) to convert a DC power source (VDC) into AC power supplied for use of at least one cold cathode fluorescent lamp (CCFL). The half bridge inverter comprises a primary winding Np, a secondary winding Ns, and an auxiliary winding Na of the transformer Tr. The external drive switch Q1 is connected to the primary winding Np and ground G and controlled by the square wave signal S _PWM . The self-driving switch Q2 is connected to the primary winding Np, the auxiliary winding Na, and the direct current power source VDC and is controlled by the output voltage of the auxiliary winding Na. The resonant capacitor is connected to the secondary winding Ns.

By using the switching of the external drive switch Q1 controlled by the square wave signal S _PWM and the switching of the self-driven switch Q2 controlled by the output voltage of the auxiliary winding Na, the DC power supply VDC Introduced into the primary winding Np of the transformer Tr, an alternating voltage is detected in the secondary winding Ns of the transformer Tr, and converted into AC power by the resonant capacitor C3.

Referring to Fig. 3, the present invention is intended to suppress the current flowing through the control stage when the external drive switch Q1 is electrically connected and to turn off the external drive switch Q1 while the external drive switch Q1 is off. It further comprises a high speed diode D1 connected to the control stage of the external drive switch Q1 for accelerating. The second acceleration diode D2 accelerates to suppress the current flowing through the control stage when the self-drive switch Q2 is electrically connected and to turn off the self-drive switch Q2 while the self-drive switch Q2 is off. Connected to the control stage of the self-actuated switch Q2 and the auxiliary winding Na. Here, the external drive switch Q1 has an N-channel field effect with a first polar capacitor CQ1 (or additional capacitor) and a first interface diode (or additional diode) located between two output gates of the external drive switch. Transistor (FET). The self-drive switch Q2 also has an N-channel field effect transistor having a second polar capacitor CQ2 (or additional capacitor) and a second interface diode (or additional diode) located between the two output gates of the self-drive switch. (FET).

4A-4F are schematic diagrams showing the operation of a circuit in one cycle according to the present invention, and FIG. 5 is a schematic diagram showing waveforms in one cycle of the circuit of the present invention. During the I period, the square wave signal S _PWM is in a high state, at which time the external drive switch Q1 is turned ON by the control of the square wave signal S _PWM and the self-drive switch Q2 Is turned off. Thus, the DC power supply VDC is provided along the path from the capacitor C1 and the transformer Tr to the external drive switch Q1, the current is stored in the transformer Tr, and the positive alternating voltage Vo Is detected by the secondary winding Ns of the transformer Tr.

During the period II, the square wave signal S _PWM is turned OFF by the control of the external drive switch Q1, and the self drive switch Q2 is still in the OFF state. At this time, the power temporarily stored in the second polarity capacitor CQ2 or the additional capacitor of the self-driving switch Q2 will be discharged, and the current stored in the transformer Tr is the first polarity capacitor of the external driving switch Q1. (CQ1) or an additional capacitor will be charged. Thus, the AC voltage Vo of the secondary winding Ns of the transformer Tr is in a low voltage state.

During the III period, the external drive switch Q1 and the self drive switch Q2 are still in the OFF state. When the first polarity capacitor CQ1 or the additional capacitor is charged to the voltage of the DC power supply VDC and the second polarity capacitor CQ2 or the additional capacitor is discharged to zero voltage, the second interface diode DQ2 or the additional diode is It is turned on and the self-acting switch Q2 is switched to zero voltage. Therefore, the AC voltage detected by the secondary winding Ns of the transformer Tr is in a negative AC voltage Vo state.

During the IV period, the self-drive switch Q2 is turned ON by the control of the auxiliary winding Na of the transformer Tr. At this time, the direction of the current flowing through the primary winding Np of the transformer Tr is reversed, and energy will accumulate in the transformer Tr. In this period, the AC voltage detected by the secondary winding Ns of the transformer Tr is in a negative AC voltage state.

During the V period, the self-drive switch Q2 is switched to the OFF state, and the external drive switch Q1 is still in the OFF state. At this time, the first polar capacitor CQ1 or the additional capacitor in the external drive switch Q1 temporarily discharges the stored power, and the current stored in the transformer is the second polar capacitor CQ2 in the self-drive switch Q2. Or will charge an additional capacitor. Thus, the AC voltage Vo detected by the secondary winding Ns of the transformer Tr is in a rising voltage state.

During the VI period, when the second polar capacitor CQ2 or the additional capacitor is charged up to the voltage of the DC power supply VDC and the first polar capacitor CQ1 or the additional capacitor is discharged to zero voltage, the first interface diode DQ1 or The additional diode will be turned on. At this time, the external drive switch Q1 is switched to zero voltage. Therefore, the AC voltage detected by the secondary winding Ns of the transformer Tr is in a positive AC voltage Vo state.

As described above, the operation of the circuit returns to the I period after the VI period is sorted to complete one cycle. The waveform of the AC voltage Vo output in the cycle of this circuit is converted into AC power Vac by the resonant capacitor C3.

Although what has been described as what is considered to be the most practical and preferred embodiment of the invention, it is a matter of course that the invention is not limited to the embodiment disclosed herein. The present invention is intended to cover various modifications that fall within the spirit and scope of the appended claims in accordance with the broadest interpretation so as to encompass various modifications and similar constructions.

The present invention can achieve inversion according to the cycle of the foregoing circuit. Also, the present invention only needs a square signal to drive the half bridge circuit. If a short circuit or other malfunction occurs in the secondary winding of the transformer, the self-actuating switch Q2 cannot continue its operation. The present invention does not require additional peripheral circuitry for circuit protection, thus reducing manufacturing costs and product size.

Claims (7)

A half bridge inverter controlled by a square wave to convert a direct current power source into an alternating current power for use of at least one lamp, A transformer having a primary winding, a secondary winding, and an auxiliary winding; An external drive switch connected to the primary winding and the ground and controlled by the square control signal; A self-driven switch connected to said primary winding, said auxiliary winding, and said direct current power source and controlled by an output voltage of said auxiliary winding; And A resonant capacitor connected to the secondary winding, The square signal controls the switching of the external drive switch and the output voltage of the auxiliary winding controls the switching of the self-drive switch that introduces the direct current power source into the primary winding of the transformer, the alternating current voltage of the transformer And the secondary winding is detected by the secondary winding and converted into AC power by the resonant capacitor. The method of claim 1, To the control stage of the external drive switch for suppressing passage of current in the control stage when the external drive switch is electrically connected, and for accelerating to turn off the external drive switch when the external drive switch is off. And a connected first high speed diode. The method of claim 1, The control stage of the self-drive switch for inhibiting passage of current in the control stage when the self-drive switch is electrically connected and for accelerating to turn off the self-drive switch when the self-drive switch is off. And a second acceleration diode connected to the half bridge inverter. The method of claim 1, Wherein said external drive switch is an N-channel field effect transistor and comprises a first polarity capacitor and a first interface diode located between two output gates in said external drive switch. The method of claim 1, Wherein said external drive switch is an N-channel field effect transistor and comprises a capacitor and a diode located between two output gates in said external drive switch. The method of claim 1, Wherein said self-drive switch is an N-channel field effect transistor and comprises a second polarity capacitor and a second interface diode positioned between two output gates in said self-drive switch. The method of claim 1, Said self-drive switch being an N-channel field effect transistor and comprising a capacitor and a diode located between two output gates in said self-drive switch.

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