JPH0524748B2 - - Google Patents

Description

[Detailed Description of the Invention] [Summary] When the output current of a switching power supply becomes excessive, the voltage drop due to the output current supplied via the rectifier and smoothing circuit increases, and the output voltage is controlled to be constant. However, the voltage induced in the secondary winding of the main transformer increases by the voltage drop. Therefore, an overcurrent condition is detected based on the relationship between the voltage induced in the secondary winding and the output voltage, and the output voltage is allowed to drop at a constant current to protect the switching power supply from overcurrent.

[Industrial application field]

The present invention relates to an overcurrent protection circuit in a switching power supply.

Switching power supplies are used as stabilized power supplies for various electronic devices. In such a switching power supply, when the load is short-circuited, an overcurrent may flow and burnout may occur. Therefore, it is necessary to protect the switching power supply from such overcurrent.

[Conventional technology]

Conventional switching power supplies are also provided with an overcurrent protection circuit that detects the output current and lowers the output voltage when the current increases above a predetermined value to protect against overcurrent. Figure 4 shows an example of a conventional overcurrent protection circuit, in which the main transformer 21
The current supplied from the DC power supply 23 to the primary winding is turned on and off by the transistor 22, and the voltage induced in the secondary winding of the main transformer 21 is
It is rectified by diodes D1 and D2, smoothed by a smoothing circuit consisting of reactor L1 and capacitor C1, and supplied to the load.The output voltage is detected by output voltage detection circuit 25, and the detection signal is added to control circuit 24. so that the output voltage is constant,
Transistor 22 via drive transformer 26
control on and off.

Such constant voltage control is generally performed using a pulse width control method that controls the on period of the transistor 22 within a fixed period, and is controlled so that the on period becomes longer as the output current increases.

When the output current supplied to the load increases, the current flowing through the primary winding of the main transformer 21 also increases, so the current transformer 27 detects this primary current and applies it to the control circuit 24 via the rectifier and smoothing circuit 28. . The control circuit 24 controls the on-period of the transistor 22 so that the output voltage is constant when the output current is smaller than a preset value, and controls the on period of the transistor 22 when the output current exceeds the preset value. By shortening the on-period of the output voltage and preventing the output current from increasing,
This provides overcurrent protection.

In addition, by connecting a current detection resistor to the load and detecting the voltage drop proportional to the current flowing through the resistor, the output current is detected, and when the overcurrent state exceeds a predetermined value, the A configuration in which the output voltage is controlled to droop in the same way as in the case of is also known.

[Problem that the invention seeks to solve]

If the output current of a switching power supply is relatively small, it is possible to detect the output current as a voltage drop across a current detection resistor, but in the case of a switching power supply with a rated output current of several hundred amperes or more, the current Even if low resistance is used for detection,
Since a large current flows, a large resistor must be used, and there is also the problem of heat generation, making it difficult to miniaturize. Therefore, when the output current is large, a configuration is adopted in which the current flowing through the primary winding of the main transformer 21 is detected by the current transformer 27, as shown in FIG.

However, since the current transformer 27 is configured to be connected between the primary side of the main transformer 21 and the secondary side of the main transformer 21 to which the control circuit 24 etc. are connected, there is no connection between the primary side and the secondary side. This requires an insulating structure to separate circuits of different voltage levels, making it difficult to miniaturize and having the disadvantage of increasing costs.

The present invention aims to protect a switching power supply by detecting overcurrent with a simple configuration.

[Means for solving problems]

The overcurrent protection circuit of the present invention protects the switching power supply by detecting the output current by utilizing a voltage drop caused by the impedance of the output circuit of the switching power supply, and will be explained with reference to FIG.

A switching element 2 such as a transistor is connected to the primary winding of the main transformer 1, a rectifying and smoothing circuit 3 including a rectifying diode, a reactor, and a capacitor is connected to the secondary winding, and the output voltage of this rectifying and smoothing circuit 3 is In an overcurrent protection circuit in a switching power supply that stabilizes the output voltage by a control circuit 4 that detects and controls the switching element 2,
An auxiliary rectifier circuit 5 that rectifies the voltage induced in the secondary winding of the main transformer 1 by an auxiliary rectifier diode and outputs the rectified voltage via a reactor on the terminal side common to the rectifier and smoothing circuit 3; A capacitor 6 which adds the output voltage of the circuit 5 to obtain an average value rectified output voltage, compares the terminal voltage of this capacitor 6 or a voltage proportional to it, and the output voltage of the rectifier smoothing circuit 3 or a voltage proportional to it,
When it is determined that the voltage drop due to the output current outputted via the rectifying and smoothing circuit 3 has exceeded a predetermined value, the control circuit 4 is controlled to control the output voltage of the rectifying and smoothing circuit 3 by constant current drooping. It is equipped with an overcurrent detection section 7.

[Effect]

In the switching power supply, the switching element 2 is turned on and off by a control circuit 4 so that the output voltage is constant. Therefore, the voltage induced in the secondary winding of the main transformer 1 is controlled to be higher by the voltage drop due to the impedance of the rectifier and smoothing circuit 3.

Furthermore, since no output current to be supplied to the load flows through the auxiliary rectifier circuit 5, its voltage drop can be ignored, and the rectified output voltage represents the induced voltage in the secondary winding of the main transformer 1. Become. In addition, the capacitor 6 allows the auxiliary rectifier circuit 5 to perform average value rectification, and even in the case of a sudden drop in the output voltage when the load 9 is short-circuited or in a state close to it.
The output voltage of the auxiliary rectifier circuit 5 is held by a capacitor 6.

Therefore, by comparing the output voltage of the auxiliary rectifying circuit 5 and the output voltage of the rectifying and smoothing circuit 3 in the overcurrent detection section 7, it is possible to detect whether the load suddenly becomes short-circuited or close to it, resulting in an overcurrent condition. Even if the switching element 2 is damaged, overcurrent detection can be performed, and thereby the control circuit 4 can shorten the ON period of the switching element 2, perform constant current droop control of the output voltage, and protect the switching power supply. can.

〔Example〕

Embodiments of the present invention will be described in detail below with reference to the drawings.

FIG. 2 is a circuit diagram of an embodiment of the present invention, and 11
12 is a main transformer, 12 is a transistor as a switching element, 13 is a DC power supply, 14 is a control circuit, 15 is an output voltage detection circuit, 16 is a drive transformer, 17 is an overcurrent detection section, 18 is an operational amplifier, and 19 is a feedback resistor. , D1 and D2 are rectifying diodes of the rectifying and smoothing circuit, D3 and D4 are auxiliary rectifying diodes of the auxiliary rectifying circuit, L1 and C1 are the reactor and capacitor of the rectifying and smoothing circuit, and C2 is a capacitor that applies the output voltage of the auxiliary smoothing circuit. R1~R
4 is a voltage dividing resistor.

In order to keep the output voltage detected by the output voltage detection circuit 15 constant, the control circuit 14 controls the ON/OFF state of the transistor 12 via the drive transformer 16 to reduce the induced voltage in the secondary winding of the main transformer 11. The structure and operation of rectifying and smoothing the signal and supplying it to the load by a rectifying and smoothing circuit including diodes D1 and D2, reactor L1, and capacitor C1 are the same as those of the conventional example.

In this embodiment, an auxiliary rectifier circuit consisting of auxiliary rectifier diodes D3 and D4, a capacitor C2, and an overcurrent detection section 17 are provided, and a common terminal side of the rectifier circuit and the auxiliary rectifier circuit is provided. The rectified voltage of the auxiliary rectifying circuit is applied to the capacitor C2 to obtain an average rectified output voltage. The terminal voltage V ₂ of this capacitor C2 is divided by resistors R3 and R4,
The divided voltage V ₄ is applied to the + terminal of the operational amplifier 18 of the overcurrent detection section 17 . Further, the output voltage _V1 of the rectifying and smoothing circuit is divided by resistors R1 and R2,
The divided voltage V ₃ is the operational amplifier 1 of the overcurrent detection section 17.
It is added to the - terminal of 8.

FIG. 3 is an explanatory diagram of the operation of the embodiment of the present invention,
If the voltage dividing resistors R1 to R4 are set so that when the output current is less than the set current _I1 , the relationship of _V4 < _V3 is established, the divided voltage _V3 will be controlled by the output voltage _V1 at a constant voltage. As shown by the solid line, the output current remains constant below the set current I ₁ , but the divided voltage V ₄
increases as the output current increases, as shown by the dotted line. In other words, as the output current increases, the voltage drop caused by the rectifier and smoothing circuit etc. is compensated for.
The induced voltage in the secondary winding of the main transformer 11 will increase.

Further, the output voltage V ₅ of the operational amplifier 18, that is, the overcurrent detection signal is zero when V ₄ ≦V ₃ .
When V ₄ >V ₃ , the value corresponds to the difference. Therefore, the control circuit 14 performs constant voltage control to keep the detected value of the output voltage V ₁ by the output voltage detection circuit 15 constant when the output current is less than the set current I ₁ . Then, when the output current exceeds the set current _I1 , the output voltage _V5 of the operational amplifier 18 increases, and the control circuit 14 shifts from constant voltage control to constant current control. Therefore, the output voltage
V ₁ is drooped and correspondingly the divided voltages V ₃ , V ₄
It also droops.

Also, the output voltage _V2 of the auxiliary rectifier circuit is connected to the capacitor C.
2, a load short-circuit condition suddenly occurs, and the secondary winding of the main transformer 11 becomes short-circuited through the rectifier and smoothing circuit, and the voltage of the secondary winding also drops to near zero. When the terminal voltage of the capacitor C2 decreases, the terminal voltage of the capacitor C2 is maintained at the output voltage _V2 of the auxiliary rectifier circuit immediately before the short circuit, so the relationship of _V3 < _V4 is established, and the control circuit 14 immediately causes the output voltage _V1 to drop. The switching power supply can then be shifted to constant current control to protect the switching power supply from overcurrent.

In the above embodiment, the voltage V 3 obtained by dividing the output voltage V ₁ by the resistors R1 and R2 is compared with the voltage V ₄ obtained by dividing the output voltage V ₂ of the auxiliary rectifier circuit by the resistors R3 and _R4 . However, if the output voltages V ₁ and V ₂ are low, they can be directly compared without voltage division. It is also possible to set the detected voltage of the output voltage detection circuit 15 for constant voltage control to be the divided voltage V ₃ applied to the overcurrent detection section 17. Further, the relationship between the divided voltages V ₃ and V ₄ can be selected to be other than that in the above-described embodiment. For example, if V ₃ = V ₄ when the output current is zero, then the divided voltage V ₃ at the set current I ₁ ,
It is also possible to adopt a configuration in which overcurrent detection is performed by detecting that the difference between V ₄ (V ₃ -V ₄ =V _{0 )} is equal to or greater than a predetermined value.

〔Effect of the invention〕

As explained above, the present invention includes the auxiliary rectifier circuit 5, the capacitor 6, and the overcurrent detection section 7 for detecting the voltage of the secondary winding of the main transformer 1,
The overcurrent detection unit 7 compares the terminal voltage of the capacitor 6 or a voltage proportional to the terminal voltage with the output voltage or a voltage proportional to the output voltage to detect an overcurrent state and perform constant voltage control. This is because the control circuit 4 for the main transformer 1 is controlled to perform drooping of the output voltage by constant current control, and to protect against overcurrent, and it is possible to detect overcurrent on the secondary side of the main transformer 1. Since problems such as separation and insulation between the primary side and the secondary side of the main transformer 1 are eliminated, and a current transformer is not required, there is an advantage that miniaturization is possible. Furthermore, when a load short-circuits, the switching power supply can be protected by speeding up the output voltage droop control compared to the case where control is performed by overcurrent detection on the primary side.

In addition, in the overcurrent detection section 7, the auxiliary rectifier circuit 5
The average value rectified output voltage of the main rectifying and smoothing circuit 3 is compared with the average value rectified output voltage of the main rectifying and smoothing circuit 3 to identify whether or not there is an overcurrent. The input conditions to the operational amplifier 18 constituting the detection section 7 are the same, so there is an advantage that the drooping point at which constant current droop control is performed can be kept constant. Further, since the reactor of the main rectifying and smoothing circuit 3 and the reactor for obtaining the average value rectified output voltage of the auxiliary rectifying circuit 5 are shared, there is an advantage that costs can be reduced.

[Brief explanation of the drawing]

FIG. 1 is a diagram explaining the principle of the present invention, FIG. 2 is a circuit diagram of an embodiment of the invention, FIG. 3 is a diagram explaining the operation of the embodiment of the invention, and FIG. 4 is a circuit diagram of a conventional example. 1 is a main transformer, 2 is a switching element such as a transistor, 3 is a rectifier and smoothing circuit, 4 is a control circuit, 5 is an auxiliary rectifier circuit, 6 is a capacitor, 7 is an overcurrent detection section, 8 is a DC power supply, 9 is a load, 11 is a main transformer, 12 is a transistor, 13 is a DC power supply, 14 is a control circuit, 15 is an output voltage detection circuit, 16 is a drive transformer, 17 is an overcurrent detection section, 18 is an operational amplifier, 19 is a feedback resistor, D1 to
D4 is a diode, C1 and C2 are capacitors, L
1 is a reactor, and R1 to R4 are resistors.

Claims (1)

[Claims] 1. A rectifying and smoothing circuit 3 in which a switching element 2 is connected to the primary winding of the main transformer 1, and a rectifying diode, a reactor, and a capacitor are included in the secondary winding.
a control circuit 4 which is connected to the rectifying and smoothing circuit 3, detects the output voltage of the rectifying and smoothing circuit 3, and controls the switching element 2;
Accordingly, in the overcurrent protection circuit in the switching power supply that stabilizes the output voltage, the voltage induced in the secondary winding of the main transformer 1 is rectified by an auxiliary rectifier diode, and the rectified voltage is an auxiliary rectifier circuit 5 that outputs via the riator on the terminal side common to the smoothing circuit 3; a capacitor 6 that adds the output voltage of the auxiliary rectifier circuit 5 to obtain an average rectified output voltage; and a terminal voltage of the capacitor 6. Or, by comparing the voltage proportional to the terminal voltage and the output voltage of the rectifying and smoothing circuit 3 or a voltage proportional to the output voltage, it is possible to determine whether the voltage drop due to the output current output via the rectifying and smoothing circuit 3 is The overcurrent detecting section 7 controls the control circuit 4 to control the output voltage of the rectifying and smoothing circuit 3 to constant current droop when it is determined that the voltage exceeds a predetermined value. Current protection circuit.