KR0125548Y1 - Over-voltage protection circuit using poly switch - Google Patents

Abstract

The disclosed overvoltage protection circuit relates to a circuit that causes the voltage supplied to the load circuit to drop when an unexpected overvoltage is applied to the power circuit so as not to be operated, and then reloads the load circuit normally when the normal voltage is applied.

In the overvoltage protection circuit using a poly switch according to the present invention, one of two AC power sources is permitted by a user by operating an input selection switch, and has a large voltage value among two AC power sources by an operation of the input selection switch. When the AC power is selected, the AC transformer drops to the voltage value of another AC power, and then the DC load is output to the DC transformer supplying the voltage for generating the DC power to operate. The input terminal of the AC transformer and the DC transformer A power circuit comprising a lew which is connected in series between a primary winding of a circuit and protects a circuit on the DC transformer side from overcurrent, wherein the power circuit is connected in series between a terminal of one side of the fuse and the primary winding of the DC transformer. As the magnitude of the current flowing through the secondary winding increases, the primary winding of the DC transformer It is characterized in that it further comprises a poly switch for lowering the output voltage of the DC voltage converter by a predetermined value by dropping the voltage value.

Therefore, the circuit of the present invention has the advantage that the load circuit can be safely protected from overvoltage without destroying the protection elements such as fuses and varistors used in the power circuit.

Description

Overvoltage Protection Circuit Using Poly Switch

The present invention relates to an overvoltage protection circuit in a power circuit.

More specifically, when an unexpected overvoltage is applied to the power circuit, the characteristics of the poly switch can be used to drop the voltage supplied to the load circuit so that it is not operated, and then the load circuit can be restarted normally when the normal voltage is applied. The present invention relates to an overvoltage protection circuit using a poly switch.

FIG. 1 is a circuit diagram showing an example of a conventional power circuit of the related art, and shows an embodiment in which 110 [V] or 220 [V] is used as a voltage of an AC power input.

As shown in FIG. 1, the power circuit of FIG. 1 includes an input selection switch 3 for selecting one of two AC power sources 110 [V] or 220 [V] input by a user's operation, and an input selection switch. If the AC power of 220 [V] is selected as the input power according to the operation of (3), the output of the AC transformer 1 and the output of the AC transformer 1 are lowered after dropping 220 [V] to 110 [V]. A DC transformer 4 for inputting the primary winding and supplying a voltage Vout for generating a DC power source for operating the DC load with the secondary winding, an input terminal of the AC transformer 1 and a DC transformer 4 A fuse connected in series between the primary winding of the circuit) to protect the circuit on the DC transformer 4 side from overcurrent and a parallel connection with the primary winding of the DC transformer 4 to block the overvoltage and surge voltage. It consists of a varistor 5.

Here, the input selection switch 3 should be connected to terminal ⓐ and terminal ⓑ when the user wants 110 [V] as the AC input power (Vin). It must be connected.

2 is a graph showing the no-load current characteristics of the DC transformer shown in FIG.

The operation of the conventional power circuit having the above configuration is as follows.

First, when the user manipulates the terminal ⓐ and the terminal ⓑ of the input selection switch 3 to be connected, when 110 [V] AC power is input, the AC input power Vin of 110 [V] is connected to the fuse 2. ) Is supplied to the primary winding of the DC transformer (4).

At this time, since the voltage supplied to the primary winding of the DC transformer 4 is a steady voltage, a steady voltage of 110 [V] is also supplied to both ends of the varistor 5.

Here, the varistor 5 is a semiconductor element in which the resistance value is changed non-linearly with the voltage, and the varistor 5 has a predetermined resistance value set when the normal voltage is applied.

In this state, an AC voltage Vout of a predetermined magnitude is induced on the secondary side of the DC transformer 4 according to the winding ratio with the primary side, and this voltage Vout is connected to the secondary side of the DC transformer 4 again. It is supplied as a voltage for generating a direct current power source for operating the direct current load.

Here, since the direct current transformer 4 exhibits no-load current characteristics (leakage current characteristics) as shown in FIG. 2, when the alternating current voltage of about 90 [V] to 130 [V] is supplied, 100 is applied to the primary winding. The current below flows and it operates normally.

On the other hand, if the user manipulates the terminal ⓐ and the terminal ⓒ of the input selection switch 3 to be connected to the AC power source of 220 [V], the AC power of 220 [V] is supplied through the AC transformer 1. It is stepped down to 110 [V] and supplied to the primary winding of the DC transformer 4 through the fuse 2.

At this time, since the voltage supplied to the primary winding of the DC transformer 4 is a normal voltage, the same process as when the above-described 110 [V] is applied is performed.

However, if the user inputs 220 [V] of the input voltage of 220 [V] while operating the terminal ⓐ and terminal ⓑ of the input selection switch 3 to be connected, the AC input power of 220 [V] is a fuse. (2) is supplied to the primary winding of the DC transformer 4 and the varistor 5, respectively.

This is a case where an overvoltage that is not allowed by the circuit is supplied, and when such an overvoltage is supplied, the varistor 5 reduces the resistance value extremely and flows a large current, such as a DC transformer 4 connected in parallel thereto. This prevents overcurrent from being applied to the other circuit numbers.

However, the varistor 5, which is generally used, is used to cut off only the surge voltage generated during initial turn-on or when an unstable voltage is applied. Since the limit value of the overvoltage is very small, about 220 [V] is used. When the voltage of was applied, it could not withstand this overvoltage and was destroyed.

In addition, the AC voltage of 220 [V] supplied through the fuse 2 is supplied to the primary winding of the DC transformer 4, where the no-load current characteristics of the DC transformer 4 shown in FIG. When an overvoltage of 220 [V] is supplied, a current of 500 [㎃] or more flows in the primary winding, whereby the primary winding is disconnected by heat, and as a result, the DC transformer 4 is destroyed.

When the DC transformer 4 is destroyed in this manner, the fuse 2 is first disconnected to prevent overvoltage and overcurrent from being supplied to the circuit of the DC transformer 4. If the DC transformer 4 is disconnected and destroyed before 2), it also occurs.

In addition, when any one of the DC transformer 4, the fuse 2 and the varistor 5 is destroyed, the DC power is also not generated by the AC voltage Vout generated on the secondary side of the DC transformer 4, Therefore, since the DC load operated by receiving the DC power does not operate, there is a problem that the user cannot use the DC load until the repair of the power circuit of FIG. 1 is completed.

In addition, the user had to spend extra costs such as repair costs due to the destruction of parts as described above.

Therefore, the object of the present invention is that when an overvoltage greater than the allowable voltage is applied as the AC input power of the power circuit, the voltage supplied to the load circuit of the power circuit is dropped so that it is not operated. An overvoltage protection circuit using a poly switch that can be restarted is provided.

1 is a circuit diagram showing an example of a conventional power circuit.

2 is a graph showing the no-load current characteristics of the DC transformer shown in FIG.

3 is a power circuit diagram showing an embodiment of an overvoltage protection circuit using a poly switch to which the present invention is applied.

4 (a) and (b) are graphs showing the characteristics of the poly switch of FIG.

* Explanation of symbols for main parts of the drawings

1: AC transformer 2: fuse

3: input selector switch 4: DC transformer

5, 8: Varistor 7: Poly switch

A feature of the present invention for achieving the object as described above, the user selects one of the two AC power supply is permitted by operating the input selection switch, the larger value of the two AC power supply by the operation of the input selection switch When the AC power is selected, the AC transformer drops to the voltage value of another AC power and is output to the DC transformer supplying the voltage for generating the DC power for operating the DC load. A power circuit comprising a fuse connected in series between a primary winding of a DC transformer and protecting a circuit on the DC transformer side from overcurrent, the power circuit being connected in series between a terminal of one side of the fuse and the primary winding of the DC transformer. As the magnitude of the current flowing through the primary winding of the circuit increases, the primary winding of the DC transformer By giving it away to the predetermined voltage value of the output voltage direct current transformer it is configured to further include a poly-switch that lowers below a value.

Hereinafter, one preferred embodiment of an overvoltage protection circuit using a poly switch according to the present invention will be described in detail with reference to FIGS. 3 and 4.

3 is a power circuit diagram showing an embodiment of an overvoltage protection circuit using a poly switch to which the present invention is applied, and FIGS. 4A to 4B show characteristics of the poly switch of FIG. 3 applicable to the present invention. The graph shown.

As shown in FIG. 3, 110 [V] or 220 [V] is used as the voltage Vin of the AC power input as in FIG. 1, and in FIG. 3, the same reference numerals as in FIG. It represents an element and its action is the same. Therefore, the configuration and operation of the overlapping circuit will be omitted and will be described based on the components unique to the present invention.

First, as shown in FIG. 3, a power circuit diagram showing an embodiment of an overvoltage protection circuit using a poly switch to which the present invention is applied is shown in FIG. Connected in series, the output of the DC transformer 4 is reduced by dropping the voltage value applied to the primary winding of the DC transformer 4 as the magnitude of the current flowing through the primary winding of the DC transformer 4 increases. And a poly switch 7 for lowering the voltage below a predetermined value.

In addition, the varistor 5 of FIG. 1 was removed and the varistor 8 with a larger capacity than the varistor 5 of FIG. 1 was mounted.

The operation of the overvoltage protection circuit using the poly switch of the present invention having such a component is as follows.

First, when an AC power source (Vin) of 220 [V] is input instead of 110 [V] while the user operates the terminal ⓐ and the terminal ⓑ of the input selection switch 3 to be connected, the AC power source is an overvoltage fuse. 2) an overcurrent flows through the primary winding of the poly switch 7 and the direct current transformer 4 (see FIG. 2).

As described above, when a current equal to or higher than the rated current flows through the poly switch 7, as shown in FIG. 4 (a), the temperature rapidly rises to have a resistance value of 100 [㏀] or more, and the input is provided at both ends thereof. Since a voltage of 200 [V] or more corresponding to about 90% of the AC power source Vin is applied, a voltage of less than about 20 [V] is applied to the rear end of the poly switch 7, that is, at both ends of the primary winding of the DC transformer 4. This makes sense.

Therefore, the secondary winding of the DC transformer 4 is induced with a very small voltage or hardly induced with the voltage, and the driving of the load circuit connected thereto is stopped so that it can be prevented from being destroyed by the overvoltage.

As shown in FIG. 4 (b), the response speed of the poly switch 7 is determined according to the magnitude of the current. In the above-described case, the response speed of the poly switch 7 is 220 [V]. ], An overvoltage is applied, and the current flowing through the poly switch 7 becomes very large, and the response speed is also very fast.

On the other hand, when the steady state voltage is applied to the poly switch 7, the temperature of the poly switch 7 is lower than 20 ° C as shown in FIG. The resistance value is also less than 10 [Ω], and a voltage within 0.2 [V] is applied to both ends of the poly switch 7.

Since the AC power input (Vin) is less than 1%, in this case, a voltage of about 99% or more, that is, 109.8 [V] or more is applied to both ends of the DC transformer 4 so that 1 of the DC transformer 4 becomes 1. The voltage of a predetermined magnitude is induced from the secondary winding to the secondary winding to normally drive the load circuit to be supplied with the voltage.

As a result, when an overvoltage is applied to the power circuit, a minute voltage is output from the DC transformer 4 due to the increase in the resistance value of the poly switch 7, and the load circuit connected thereto stops driving the drive. When the normal voltage is applied, the resistance value of the poly switch 7 decreases so that the normal voltage is output from the DC transformer 4 so that the load circuit is normally driven.

Here, the poly switch 7 has a very fast response time to the current as described above, so that the poly switch 7 operates first before the fuse 2 is shorted due to overvoltage, so that the fuse 2 is destroyed. Can be prevented.

On the other hand, in the present invention, by increasing the capacity of the varistor (8), not only can the surge voltage be completely removed, but also the overvoltage is applied to the varistor (8) before the resistance value of the poly switch (7) is rapidly increased. Can be prevented from being destroyed.

However, in the present invention, since the overvoltage protection function is performed by mounting the poly switch 7, the varistor 8 may be removed.

As described above, according to the overvoltage protection circuit using the poly switch according to the present invention, the load circuit can be protected from the overvoltage without destroying the fuse or varistor provided in the power circuit.

In addition, if the normal voltage is applied again after the operation of the load circuit is stopped due to the overvoltage, the resistance value of the poly switch decreases and the normal voltage is applied to the DC transformer, so that the load circuit operates normally. It also has the effect of restarting the load circuit.

In addition, since the separate parts are not destroyed or destroyed by the overvoltage, no separate repair cost is generated.

Claims (1)

If the user selects one of the two AC powers allowed to be input by operating the input selection switch, and an AC power supply having a larger voltage value is selected among the two AC powers by operation of the input selection switch, the AC power supply is further changed by the AC transformer. After dropping to the voltage value of AC power, it outputs to DC transformer supplying voltage to generate DC power to operate DC load, and is directly connected between input terminal of AC transformer and primary winding of DC transformer, A power circuit including a fuse that protects a circuit on a transformer side, the power circuit comprising: a series connection between a terminal of one side of the fuse and a primary winding of a DC transformer, so that the magnitude of the current flowing through the primary winding of the DC transformer increases. The output voltage of the DC transformer is lowered by dropping the voltage across the primary winding of the DC transformer. A poly-switch, characterized by configured including poly switch that lowers below a predetermined value, the overvoltage protection circuit using the same.