KR20080021367A - Power circuit - Google Patents

Abstract

A power output stabilizing circuit is provided to stabilize all power outputs of a transformer by linking voltages, which are not connected to each other by a feedback, to the feedback voltage. A power output stabilizing circuit includes a feedback voltage generation unit(50) and a connection unit(55). The feedback voltage generation unit generates a feedback voltage to detect a normal operation of a first output voltage. The connection unit connects a different output voltage from a first output voltage to the feedback voltage generation unit. The connection unit is a transistor. The connection unit is connected to a next terminal of a rectifying unit which rectifies an output voltage.

Description

Output power stabilization circuit

1 shows an exemplary view of an output power stabilization circuit according to the prior art,

2 shows an exemplary view of an output power stabilization circuit according to the present invention.

Explanation of symbols on the main parts of the drawings

50: trance 51: SCR

52: phototransistor 55: transistor

The present invention relates to an output power stabilization circuit, and more particularly, to an output power stabilization circuit to stabilize the output power and maximize the efficiency.

All electronic and communication equipment uses a power supply such as a switching mode power supply (hereinafter referred to as SMPS). The power supply generates DC power of various sizes required in the product. To this end, the power supply device inputs an external AC power and generates a DC power of various sizes required by the product by using a transformer such as a transformer.

The transformer is configured to input a voltage obtained by rectifying an external AC power source to the primary side, and generate secondary voltages of various magnitudes using the primary side voltage. Therefore, when various sizes of voltage are required in the product, the secondary winding ratio of the transformer is controlled to provide multiple terminals on the secondary side, and a voltage having a desired magnitude is generated from each terminal.

The SMPS with a transformer operating in this manner needs to protect the transformer from the overvoltage and the overcurrent. If overvoltage and overcurrent occur on the secondary side of the transformer, the control circuit configured to receive DC voltage from the transformer is in a state of receiving overvoltage and overcurrent, and the control circuit is caused by overvoltage and overcurrent higher than the rated voltage. Malfunction or circuit breakage.

On the other hand, the transition from the existing analog electronics to digital electronics, the digital electronics, the high-definition, high sound quality, and the like, the IC design used in the digital electronics requires a high-density process technology. In addition, high speed data processing is accompanied by high density processing technology in digital electronic devices. In other words, as the speed of the CPU is increased, high-speed data processing is required for signal processing. Therefore, various circuit elements are configured to enable high-speed switching for high-speed data processing, and the same also applies to various elements used in the SMPS power supply. Digital electronics also have a much higher current compared to conventional products. Therefore, since digital electronic devices use high-speed switching and high current, if an overcurrent condition occurs in SMPS, which is a power supply device, the product may be damaged and further, it may cause fatal injury.

In the conventional output power stabilization circuit, as shown in FIG. 1, a PWM control circuit (not shown) for switching the voltage supplied to the primary coil of the transformer 25 is connected. The PWM control circuit switches the voltage supplied to the primary coil of the transformer 25 by PWM control.

The secondary side of the transformer 25 is composed of a coil having a plurality of output terminals. Output terminals connected to the secondary coil of the transformer 25 have different turns ratios and output voltages of different magnitudes. As such, the voltage generated at the secondary side of the transformer 25 is supplied to various control circuits in the product through an output line connected to the output terminal.

In order to monitor the short circuit of the supply line to which the secondary side generated voltage of the transformer 25 is supplied, the conventional output power supply stable circuit feeds back the secondary side voltage of the transformer 25. That is, as shown, when a short occurs in the output line of the transformer 25, the divided voltage V1 of the feedback line falls. When the feedback voltage V1 falls, the cathode voltage V2 of the switching element SCR 21 rises.

When the cathode voltage V2 of the switching element 21 rises, the current Ic of the photo transistor 22 falls, and the photo transistor 22 is turned off. When the photo transistor 22 is turned off, the feedback voltage of the PWM control circuit increases, and an overcurrent protection circuit (OCP) inside the PWM control circuit that senses the voltage operates to supply the voltage to the transformer 25. Will be blocked.

On the other hand, in contrast to the case where the output voltage of the transformer 25 is fed back and stabilized as described above, as shown in FIG. 1, an LDO regulator is maintained in order to maintain a constant output power according to load variation. (23) is used.

The LDO regulator 23 has a voltage drop between an input voltage and an output voltage, and the input / output voltage difference generates a lot of heat so that a heat sink is used for a product using the LDO regulator 23. ) Also needs to be used.

As described above, the conventional output power supply stabilization circuit maintains the output power constant by using the LDO regulator for the output power other than the feed back power supply. However, since the LDO regulator consumes a lot of power and generates a lot of heat, there is a problem that a separate heat sink must be used.

Accordingly, an object of the present invention is to provide an output power stabilization circuit capable of maximizing efficiency while stabilizing output power by configuring a stabilizing automatic circuit for all output powers.

Output power stabilization circuit according to the present invention for achieving the above object, in the power supply for generating a voltage of various sizes required in the product,

Feedback voltage generation means for generating a feedback voltage to detect normal operation of the first output voltage; And

And connecting means for associating an output voltage different from the first output voltage to the feedback voltage generating means.

In addition, the connecting means of the present invention is characterized by using a transistor.

The connecting means of the present invention is characterized in that it is connected to the next stage of the rectifying circuit for rectifying the output voltage.

Hereinafter, an output power stabilization circuit according to the present invention will be described in detail with reference to the accompanying drawings.

2 shows an exemplary diagram of an output power stabilization circuit according to an embodiment of the present invention.

The output power stabilization circuit of the present invention shown in FIG. Is divided into a primary side and a secondary side around the transformer 50.

The primary coil of the transformer 50 is provided with a PWM control circuit (not shown) for PWM switching control of the voltage supplied to the transformer 50. The PWM control circuit is configured to interrupt the primary side supply voltage of the transformer 50 when a short circuit occurs, based on the secondary side feedback voltage of the transformer 50.

A plurality of output lines L1, L2, ... are formed in the secondary coil of the transformer 50. The output line L1 of the secondary coil of the transformer 50 generates 12 volt output, and the output line L2 generates 5.3 volt output, so that the control circuit part (not shown) provided on the secondary side of the transformer 50 is output. Power on. In order to generate the 12 volt and 5.3 volt voltages, a rectifier circuit composed of a high voltage diode, a capacitor, an inductor, and the like is provided at each output line of the transformer 50. Since the output voltage of the transformer is controlled by the secondary winding ratio of the transformer, the magnitude of the final output voltage is not important.

In addition, the present invention connects the transistor 55 between the output line (L1) and the output line (L2) for outputting a 12-volt voltage of the transformer 50, the output line (2) to the output line (L2) being fed back L1) is linked to stabilize the power output through the output line L1.

The feedback voltage V1 of the present invention is a voltage divided by a voltage divider resistor connected in series between the output line L2 and the ground. The feedback voltage V1 controls the gate terminal of the SCR 51 which is a switching element to control the on / off operation of the SCR 51.

The SCR 51 controls the current flow of the light emitting device of the phototransistor 52. Accordingly, when the SCR 51 is turned on, the phototransistor 52 is operated to lower the feedback voltage of the PWM control circuit. However, when the SCR 51 is turned off, the phototransistor 52 does not operate and the feedback voltage of the PWM control circuit is increased.

That is, when 12 volt power is normally output from the output line L1 and 5.3 volt power is normally output from the output line L2, the transistor 55 connects the base terminal to the output line L1 through a resistor. ) Is a normal amplification operation to generate a feedback voltage of normal magnitude. Therefore, while the normal feedback voltage is provided to the primary side of the transformer 50, the normal secondary voltage generation operation of the transformer 50 is maintained.

However, when the output voltage is lowered due to the increase in the load of the output line L1, the current applied to the base terminal of the transistor 55 is also lowered. At this time, the collector current of the transistor 55 decreases, and therefore the feedback voltage V1 falls.

The operation lowers the gate voltage of the SCR 51 so that the SCR 51 is almost closed. In connection with this, the voltage V2 is raised. The elevated voltage V2 controls the photo transistor 52 in a nearly closed state. And the feedback voltage of the PWM control circuit is raised.

Therefore, when the feedback voltage of the PWM control circuit rises, the voltage is supplied to the primary side of the transformer 50 until the output of the output line L1 returns to the normal state and the feedback voltage V1 is stabilized. .

In addition, when a short circuit occurs in the output line L1, a large voltage drop occurs, and a voltage of about zero volts is applied to the base terminal of the transistor 55. That is, while the low logic signal is applied to the base terminal of the transistor 55, the output of the collector terminal of the transistor 55 is also absent.

The feedback voltage V1 at this time causes the SCR 51 to be in an off state. In connection with this, the photo transistor 52 is controlled to an off state. And the feedback voltage of the PWM control circuit is raised.

Therefore, when the feedback voltage of the PWM control circuit rises above a predetermined value (a reference value determined as a short detection condition), the overcurrent protection circuit (OCP) operates inside the PWM control circuit, and the control is performed according to the occurrence of a short circuit. Voltage supply is cut off to the primary side of

In addition, when a short occurs in the output line L2 of the transformer 50, the divided voltage V1 of the feedback line falls. When the feedback voltage V1 falls, the SCR 51 is turned off and the cathode voltage V2 of the switching element SCR 51 rises.

When the cathode voltage V2 of the switching element 51 rises, the current Ic of the photo transistor 52 falls, and the photo transistor 52 is turned off. When the photo transistor 52 is turned off, the PWM control circuit feedback voltage rises, and an overcurrent protection circuit (OCP) inside the PWM control circuit which senses the voltage operates to block the supply of voltage to the transformer 50. Let's go.

In addition, when +5.3 volts is normally output from the positive voltage output line L2 of the transformer 50, the distribution voltage V1 of the feedback line is a constant value (a voltage capable of turning on the SCR). Keeping the above, the SCR 51 is turned on.

When the SCR 51 is turned on, a current path of the photo transistor 52 is formed, the photo transistor 52 is turned on, and the on-operated photo transistor 52 is a feedback voltage of a PWM control circuit. Lower it.

As described above, the output power stabilization circuit according to the present invention is characterized in that all voltages are mutually influenced by the feedback by linking the voltages which are not connected by the feedback to the feedback voltage. According to this feature, the power supply circuit according to the present invention can stabilize all the output power of the transformer.

The above-described preferred embodiment of the present invention is disclosed for the purpose of illustration, and may be applied to the case of pursuing stabilization of the output power in the SMPS power supply. Therefore, those skilled in the art will be able to improve, change, substitute or add other embodiments within the technical spirit and scope of the present invention disclosed in the appended claims.

The output power stabilization circuit according to the present invention described above is characterized in that all voltages are mutually influenced by the feedback by linking the voltages which are not connected by the feedback to the feedback voltage. According to this feature, the power supply circuit according to the present invention can stabilize all the output power of the transformer. In addition, the present invention can achieve power supply stabilization without using a power-consuming LDO regulator, thereby achieving economical and power efficiency. In addition, the present invention can be achieved by the appropriate measures and prevention of the occurrence of a short circuit to achieve the effect of prolonging the life and safety accidents for the product.

Claims (3)

In the power supply for generating a voltage of various sizes required by the product, Feedback voltage generation means for generating a feedback voltage to detect normal operation of the first output voltage; And And connecting means for associating an output voltage different from said first output voltage to said feedback voltage generating means. The method of claim 1, And said connecting means uses a transistor. The method of claim 1, And said connecting means is connected to the next stage of the rectifying circuit for rectifying the output voltage.

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