KR0121570B1 - Heat emission for constant voltage power supply - Google Patents

Abstract

Disclosed is a heat radiation circuit for a constant voltage supplier comprising a voltage supply portion(70) and a heat radiation portion. A constant voltage supplier supplies an input voltage dropped by a trans(T") to a load(40) as a constant voltage of a constant level by the control of a control portion(50) driven by the output of an error amplification portion(10), a comparison portion(20) and a reference voltage generator(30). The voltage supply portion(70) rectifies and smooths the output of the trans(T"). The heat radiation portion(60) controls the input voltage of the control portion(50) by switching operation in response to the input voltage level demultiplied on the voltage by the voltage supply portion(70). Thus, it is possible to protect the breakdown of the components.

Description

Heat dissipation circuit of constant voltage power supply

1 is a circuit diagram showing a conventional constant voltage device,

2 is a circuit diagram showing a heat radiation circuit of the constant voltage power supply device according to the present invention.

* Explanation of symbols for the main parts of the drawings

10: error amplification part, 20: comparison part,

30: reference voltage generator, 40: load,

50: control unit, 60: heat dissipation unit,

70: power supply, Q ₁ -Q ₂ : transistor,

R ₁ -R ₂ : resistance, R: resistance,

C ₁ -C ₃ : condenser, D ₁ -D ₃ : diode

BD: bridge diode, T, T ': trance,

ZD: Zener Diode.

The present invention relates to a constant voltage power supply device, and more particularly, to provide a constant voltage power supply device in which power supplied to a transistor, which is a main element constituting the constant voltage power supply, is excessively supplied to prevent fluctuation of constant voltage or destruction of the transistor. It relates to a heat radiation circuit.

As the technology of home appliances has developed, power sources using home appliances as power sources have also been supplied in various ways according to the characteristics of home appliances. In addition, the power supplied to the home appliances, as the home appliances are finer and more precise, has required a constant voltage at a lower level of power. Therefore, in order to meet the characteristics of the home appliances as described above, instead of directly supplying the power supplied to the home appliances from a general power supply device, the power level is converted to a level required by the home appliances and maintained at a constant voltage. To supply. Therefore, since the home appliance is supplied with only a certain level of power from which the noise generated from the power supply device or the noise component generated during the transmission of power is removed, the home appliance does not malfunction due to the interference of the noise or disturbance included in the power supply. Normal operation is performed.

As described above, the constant voltage power supply device for maintaining the power supplied to the home appliance at a constant level is configured as shown in FIG.

Where 10 is an error amplifier, 20 is a comparator, 30 is a reference voltage generator, 40 is a load, 50 is a controller, T is a transformer, BD is a bridge diode, C ₁ is a capacitor, Q ₁ is a transistor, and R ₁ and B ₂ is the resistance

In the constant voltage power supply device configured as described above, AC power is stepped down through the transformer T, rectified through the bridge diode BD composed of a plurality of diodes, and applied to both ends of the capacitor C ₁ . The output voltage of the bridge diode BD, which contains the ripple component at both ends of the capacitor C ₁ and is supplied, is a constant voltage from which the ripple component is removed while passing through the capacitor C ₁ of the transistor Q ₁ of the controller 50. It is applied to the collector side and supplied to the load 40 at a constant voltage.

At this time, a driving signal for driving the same is supplied to the base side of the transistor Q _l of the control unit 50 for supplying a constant voltage to the load 40, which is outputted from the emitter side of the transistor Q _l to receive a resistor. The output of the error amplifier unit 10 amplifying the comparison value of the comparison unit 20 comparing the output voltage divided by (R ₁ ) with the resistor (R ₂ ) and the reference voltage generated from the reference voltage generator 30. is a stable constant voltage from the base side of the transistor (Q ₁₎ of the controller 50 is supplied to the base side of the transistor (Q ₁₎ of the controller 50 to the drive signal to be supplied to the load it is 40.

Here, the power P consumed by the transistor Q ₁ of the controller 50 is expressed by Equation 1 below.

P = I _L (V _i -V _O ). … … … … … … … … … … … … … … … … … … … … … … (One)

Where P is the power consumption of the transistor, I _L is the current flowing across the transistor, V _i is the input voltage input to the collector side of the transistor, and V _O is the output voltage output from the emitter side of the transistor.

As in the above formula, the voltage difference between the collector side and the emitter side of the transistor is consumed by the transistor and dissipated as heat.

That is, the input supplied to the base side of the transistor keeps the emitter side output constant. When the voltage value input from the collector side of the transistor has a higher value than the voltage value output to the emitter side, the transistor itself is a column. Will be consumed by

In this way, if the input voltage input to the collector side of the transistor is input at a constant level (a level that can be controlled by heat in the transistor itself), the transistor controls this to supply a constant level output voltage to the load, but the collector of the transistor When the input voltage input to the side is excessively input, the transistor generates excessive heat to control it.

Therefore, the transistor's inherent operation cannot be performed properly, and the output of the transistor is not output at a constant level (constant voltage), and the power consumption of the transistor increases, so that the heat generated in the transistor is increased and the transistor is destroyed. Had

The present invention has been made to solve the shortcomings in the conventional transistor as described above, by dividing the voltage applied to the constant voltage control transistor for supplying a constant voltage to the load by regulating the input power by dividing the voltage applied by the heat radiation transistor to a constant voltage It is an object of the present invention to provide a heat dissipation circuit of a constant voltage power supply device in which a heat generated from a control transistor is reduced so that the constant voltage control transistor is not broken by overheating while maintaining the input voltage at a constant voltage.

In the heat dissipation circuit of the constant voltage power supply device of the present invention for realizing the above object, in a constant voltage power supply device for supplying a load by controlling the input voltage stepped down through a transformer to a constant voltage at a predetermined level, Rectifying and dividing the input voltage generated on the secondary side of the circuit, switching operation according to the divided input voltage level, and cuts the divided voltage to the constant voltage control transistor and the heat radiation transistor during overvoltage input, and when the input voltage of a predetermined level is input, the input voltage The overvoltage applied to the constant voltage control transistor and the heat dissipation transistor are divided to allow the overvoltage added to the transistor for constant voltage control.

Hereinafter, the configuration of the present invention in more detail with reference to the accompanying drawings as follows.

As shown in FIG. 2, the control unit 50 drives the input voltage stepped down by the transformer T 'to the output of the error amplifier 10, the comparator 20, and the reference voltage generator 30. In the constant voltage power supply device to be supplied to the load 40 at a constant voltage of a constant level, the power supply unit 70 for rectifying / smoothing and dividing the output of the transformer (T '), and the divided input voltage It is composed of a heat dissipation unit 60 to control the input voltage input to the control unit 50 by switching operation according to the level.

Here, the power supply unit 70 is connected to the secondary side of the transformer (T ') to rectify the input voltage (D ₂ ) (D ₃ ) and the heat output by smoothing the output of the diode (D ₂ ) (D ₃ ) It is composed of a capacitor (C ₂ ) output to the unit 60 and a diode (D ₁ ) connected to the secondary side of the transformer (T ') to divide the input voltage to supply to the heat dissipation unit (60).

In addition, the radiator 60 applies a resistor R for applying the output of the diode D ₁ to a connection point between the base of the radiation transistor Q ₂ and the control diode ZD, and the resistor R from the resistor R. FIG. A transistor for dividing / interrupting a zener diode (ZD) operating on / off according to the input voltage level and the output voltage applied from the power supply unit 70 to the control unit 50 by driving back and forth with the zener diode (ZD). It consists of (Q ₂ ).

In addition, the Zener diode ZD is turned on when the input voltage applied from the transformer T 'to the constant voltage control transistor Q ₁ is higher than or equal to a predetermined level, and when the Zener diode ZD is lower than or equal to a predetermined level, the resistance R of the resistor R is performed. Set the resistance value. That is, the resistance value of the resistor R is set so that the zener diode ZD can be turned on when the input voltage is overvoltage.

In the figure, C ₃ is a capacitor capable of delaying the operation of the zener diode ZD to a level at which the input voltage divided by the resistor R is charged at C ₃ to turn on the zener diode ZD. That is the capacitor (C ₃₎ an excessive input voltage is charged Zener diode transistor (Q ₂ for heat dissipation without interrupting the voltage supplied by that charge time in the constant-voltage control transistor (Q ₂₎ to a level capable of turning on the (ZD) in It is possible to process by dividing at).

Referring to the operational effects of the present invention configured as described above are as follows.

The input voltage stepped down in the transformer T is rectified via the diode D ₂ and D ₃ , and then smoothed through the capacitor C ₂ and applied to the collector side of the transistor Q ₂ . In addition, a resistor R connected to the connection point of the zener diode ZD and the base side of the transistor Q ₂ with the input voltage through the diode D ₁ is applied to the capacitor C ₃ to drive the zener diode ZD. Control.

Accordingly, the input voltage supplied to the load 40 through the transistor Q ₁ of the controller 50 is divided by the reference voltage generator 30, the comparator 20, and the error amplifier 10, and thus the load 40 is divided. Since it is supplied to, the load 40 is not overloaded.

Looking at this in more detail by the operating state of the zener diode (ZD) by the input voltage, first, the operating voltage (V _z ) of the zener diode (ZD) operating by the input voltage passing through the diode (D ₁ ) and the resistor (R) ) Is set to V _O + X.

When the input voltage (V _i) is less than the operating voltage (V ₂₎ of the Zener diode (ZD), the current (I _Z) passing through the Zener diode (ZD) to the state zero.

Therefore, the input voltage Vi through the resistor R is applied to the base side of the transistor Q ₂ at a high level to drive the transistor Q ₂ , so that the input voltage rectified by the diode D ₂ (D ₃ ) is increased. via a transistor (Q ₁₎ it is to be applied to the partial pressure of the transistor (Q ₁₎ of the controller 50.

On the other hand, when the input voltage Vi is greater than the operating voltage V _Z of the zener diode ZD, the base voltage V _B applied to the base side of the transistor Q ₂ is the operation of the zener diode ZD. Since the voltage V ₂ is kept constant, the collector voltage of the transistor Q ₁ is expressed by Equation (20) below.

V _C2 = V _Z -V _r (V _C2 ). … … … … … … … … … … … … … … … … … … … (2)

Where V _C2 is the collector voltage, V _Z is the operating voltage of the zener diode ZD, and V _r is the voltage applied to the resistor R.

Thus, transistors (Q_OnePower Consumption from_Q1) Is P_Q1 = I_L(V_z-V_r-V_O)to be.

Where P _Q1 is the power consumption of transistor Q ₂ , I _L is the current flowing through transistor Q ₁ , V _Z is the operating voltage of zener diode ZD, V _r is the voltage applied to resistor R , V ₀ is the output voltage supplied to the load 40.

In addition, the transistor (Q₂Power Consumption from_Q2) Is P_Q2 = I_L(V_i-V_z-V_r)to be.

Where P _Q2 is power consumption consumed by transistor Q ₂ , I _L is a current flowing through transistor Q ₂ , V _i is an input voltage input to the collector side of transistor Q ₂ , and V _Z is a zener diode ( ZD), the operating voltage, V _r is the voltage applied to the resistor (R).

Therefore, the transistor in the input voltage (V _i) is a Zener diode to flow (ZD) if the operating voltage (V _Z) is more than the high voltage, the applied voltage is distributed in the transistor (Q ₁₎ and the transistor (Q ₂₎ of the ( In Q ₁ ), overheating caused by excessive input voltage can be prevented.

As described above, in the present invention, when the input voltage input to the constant voltage control transistor is excessively input, since the transistor dissipates and inputs the input voltage by separate heat dissipation, the constant voltage power supply device is normal by reducing the amount of heat generated by the constant voltage control transistor. It is possible to prevent the destruction of the elements by configuring the constant voltage power supply device as well as to perform the operation.

Claims (5)

The input voltage stepped down by the transformer T 'is controlled by the control unit 50 which is driven by the outputs of the error amplifier 10, the comparator 20, and the reference voltage generator 30. In the constant voltage power supply device to be supplied to 40, the power supply unit 70 for rectifying / smoothing and dividing the output of the transformer (T '), and switching operation according to the divided input voltage level to the control unit 50 A heat dissipation circuit of a constant voltage power supply, characterized in that consisting of a heat dissipation unit 60 to regulate the input voltage input. The method of claim 1, wherein the power supply unit 70 is connected to the secondary side of the transformer (T ') of the diode (D ₂ ) (D ₃ ) and rectifying the input voltage of the diode (D ₂ ) (D ₃ ) Condenser C ₂ for smoothing the output and outputting to the heat dissipation unit 60 and a diode D ₁ connected to the secondary side of the transformer T 'to divide the input voltage and supply it to the heat dissipation unit 60. A heat dissipation circuit of a constant voltage power supply, characterized in that the. The resistor R of claim 1, wherein the radiator 60 applies the output of the diode D ₁ to a connection point between the base of the radiation transistor Q ₂ and the zener diode ZD. Zener diode (ZD) on / off operation according to the input voltage level applied from the R), and the output voltage applied to the controller 50 from the power supply unit 70 by driving back to the zener diode (ZD) A heat dissipation circuit of a constant voltage power supply, characterized in that it is composed of a voltage dividing / interrupting transistor (Q ₂ ). 4. The heat dissipation circuit according to claim 3, wherein the resistance value of the resistor (R) is set so that the zener diode (ZD) can be turned on when the input voltage is input with an overvoltage. 4. The zener diode according to claim 3, wherein the time constants of the resistor R and the capacitor C ₃ are set after a time period during which the constant voltage controlling transistor Q ₁ and the radiating transistor Q ₂ operate normally even at excessive input voltages. A heat dissipation circuit of a constant voltage power supply, characterized in that the (ZD) is set to turn on.