KR0112823Y1 - Over voltage prevention circuit - Google Patents

Abstract

The present invention is an overvoltage inflow prevention circuit, which is applied to a frequency converter protection circuit of a receiver tuner to prevent an expensive frequency converter from being destroyed when an overvoltage flows over a set, and compares the reference voltage with a comparator (OP1). The input voltage of the frequency converter is compared to cut off the inflow of the voltage when an overvoltage occurs, and the signal is grounded through the switching controller 22 due to the change in the resistance value of the transistor PH1 even when the heat sink temperature rises, thereby inducing the inflow of the frequency converter 6. It is to protect the expensive frequency converter 6 from being destroyed by overvoltage by blocking the voltage.

Description

Overvoltage protection circuit

1 is a power supply circuit diagram of a conventional frequency converter.

2 is an overvoltage protection circuit diagram of a frequency converter of the present invention.

* Explanation of symbols for main parts of the drawings

20: lightning protection unit 21: overvoltage detection comparison unit

23: heat sink temperature rise detection unit 24: abnormal operation display unit

25: coaxial cable

The present invention relates to an overvoltage prevention circuit, and more particularly, to a circuit applied to a satellite broadcast receiver tuner to prevent overvoltage from being destroyed by a frequency converter (LNB).

FIG. 1 is a power supply circuit diagram of a conventional frequency converter, and includes transistors TR7, resistors R21, capacitors C21 and C22, and zener diodes ZD21 that constantly control and output the voltage of the power supply terminal Vcc1. The first constant voltage unit 1, the diode D23 outputting a constant voltage of the regulator IC20, the second constant voltage unit 7 outputting to the resistor R25, and a power switch for the user to operate the on / off state. (3) and transistors TR8 (TR9) for supplying and interrupting the output of the first constant voltage unit 1 of the output of the second constant voltage unit 7 in accordance with the on / off of the power switch 3, A switching unit 2 including resistors R22 and R23, a tuner pack 4 for receiving the output signal of the switching unit 2, and a parabolic antenna 5, and being installed in the center of the tuner pack ( And a frequency converter 6 which is driven by the voltage output from 4) and converts the frequency of the radio signal received by the antenna. (Unexplained symbol D22 in the drawing is a diode, 25 is a coaxial cable.)

In the power supply circuit of the conventional frequency converter configured as described above, the voltage drops to the resistor R21 in the first constant voltage unit 1 that receives the voltage of the power source Vcc1, and the ripple component is removed from the capacitor C21. After that, a voltage corresponding to the zener voltage of the zener diode ZD21 is applied to the base of the transistor TR7, and a constant voltage is output to the transistor TR7, and this voltage is again controlled by an AC component through the capacitor C22. do.

On the other hand, in the second constant voltage unit 7, the constant voltage output from the regulator IC20 is dropped to the resistor R23 when the power switch 3 is turned on through the diode D23 and the resistor R25, and thus the transistor TR9. Drive the transistor TR8 through the resistor R22.

Accordingly, the voltage output from the first constant voltage unit 1 is input to the power supply inlet B of the tuner pack 4 through the transistor TR8 via the diode D22, and this signal is inputted through the same cable ( 25) is input to the frequency converter 6 in the parabolic antenna (5).

At this time, the frequency converter 6 converts a signal of 16GHZ into 1GHZ.

However, the power supply circuit of the conventional frequency converter has a problem in that an expensive voltage converter is destroyed due to an overvoltage input when an abnormality occurs in an external condition of the constant voltage unit or when a heat sink temperature of the power unit is higher than a set temperature.

The present invention improves this point and detects overvoltage in comparison with the reference voltage applied to the frequency converter and the output of the second constant voltage section output for power supply of the system when an abnormality occurs in the set and overvoltage at the time of overvoltage detection. In order to block the signal from being caught by the frequency converter, an embodiment of the present invention will be described in detail with reference to the accompanying drawings.

2 is an overvoltage protection circuit diagram of a frequency converter of the present invention. As shown therein, a transistor TR7, a capacitor C21 (C22), a resistor R21, which constantly control and output the voltage of the power supply terminal Vccl, The first constant voltage unit 1 formed of the zener diode ZD21, the second constant voltage unit 7 outputting a constant voltage of the regulator IC20 through the diode D23, the resistor R25, and the user turn on / off And a transistor for supplying and blocking the output voltage of the first constant voltage unit 1 to the output of the second constant voltage unit 7 according to the on / off of the power switch 3 for operating the power switch 3. The center of the tuner pack 4 and the parabolic antenna 5 that receive the output of the switching unit 2 and the switching unit 2 including TR8, TR9, and resistors R22, R23, and R24. It is installed in the frequency converter 6 for converting the frequency of the radio signal received by the antenna by driving the voltage output from the tuner pack (4) The second constant voltage unit includes a voltage of the comparison voltage point A input to the frequency converter of the switching unit 2, a diode D3, a resistor R7, a resistor R8, and a resistor D6. The overvoltage detection comparison unit 21 for comparing and outputting the reference voltage which is the output voltage of (7), the resistors R1, R2, R3, R4, R5, the transistor PH1, the transistor TR1, and the diode D1. ) And an inverter (INVERT) to detect the overvoltage of the heat sink temperature rise detection unit 23 and the overvoltage detection comparison unit 21 which cuts off the voltage inflow of the frequency converter 6 when the heat sink (not shown) rises. And a switching control unit 22 composed of a resistor R21 and a transistor TR2 which stops the signal detected when the temperature rise detection unit 23 detects the temperature rise, and the overvoltage detector 21 when the overvoltage or heat sink temperature rises. The abnormal copper is composed of a resistor (R10) (R11), a light emitting diode (LED1), and a transistor (TR3) indicating an abnormal voltage with a signal of Is a display unit 24 and a diode (D5) (D7), the resistance (R9) consists of a lightning protection unit 20 to prevent backflow of the voltage when a lightning stroke.

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

The comparison voltage point A to which the reference voltage which is the output signal of the second constant voltage unit 7 input to the inverting terminal of the comparator OP1 through the diode D3 and the resistor R7 and the output of the switching unit 2 are applied. When the voltage of is input to the inverting terminal of the comparator OP1 and the non-inverting terminal input is an overvoltage, the output of the comparator OP1 is made high and this signal causes the transistor TR2 through the resistor R6 diode D4. The voltage output from the second constant voltage unit 7 by driving is grounded, and thus the transistors TR8 and TR9 are turned off, so that no voltage is input to the frequency converter 6.

At this time, the high signal of the comparator OP1 through the resistor R6 and the diode D4 is inputted voltage-divided into the resistors R11 and R5 at the base terminal of the transistor TR3 of the abnormal operation display unit 24 so that the transistor ( Since the TR3 is turned on, the collector side of the transistor TR3 is applied high, so that the light emitting diode LED1 is turned on.

On the other hand, when the heat sink is overheated, the resistance value of the transistor PH1 becomes large due to a rise in temperature, so that the voltage on the base side of the transistor TR1 becomes high, and thus the transistor TR1 is driven. The collector has a low potential and the low signal of the inverter INVERT input through the diode D2 is output high, and the high signal turns on the transistor TR3 through the resistor R4 and the diode D2. The LED (LED1) connected to the collector of TR3) turns on to indicate abnormal operation.

At this time, the diodes D7 and D5 prevent the reverse voltage during lightning.

As described above, the present invention has the effect of preventing an expensive frequency converter from being destroyed by applying an abnormal voltage to the set in advance and displaying the abnormal voltage with light so that the abnormal situation can be easily recognized.

Claims (1)

An overvoltage detection comparison unit 21 for checking whether the overvoltage is compared by comparing the reference voltage of the second constant voltage unit 7 for supplying operating power to the system with the voltage input to the frequency converter 6, and the temperature at the time of the heat sink temperature rise. A heat sink temperature rise detection unit 23 operable to detect a voltage and cut off the voltage, a switching control unit 22 that receives the overvoltage detection signal and the temperature rise detection signal and supplies and cuts the voltage applied to the frequency converter 6; And an abnormal operation display unit (24) for displaying the overvoltage and temperature rise signals, and a lightning protection unit (20) for preventing a reverse voltage from being applied during a lightning strike.