KR820001954B1 - Overvoltage protected de-boots regulator - Google Patents

Abstract

The electronic regulator produces a direct voltage less than the raw direct voltage input. The load on the regulated output is the primary winding of the horizontal output transformer of television horizontal deflection circuit(260). A secondary winding of the output transformer is connected in series with the source of raw direct voltage. An energy storage capacitor is coupled across the secondary winding, and charged by a gated rectifier. The regulated output voltage is taken across the raw direct voltage source and capacitor. An overvoltage protection circuit for protecting against fault conditions is provided.

Description

Voltage regulator

1 is a schematic diagram of a power regulator according to the present invention.

2 is a schematic circuit diagram showing in more detail a power regulator according to the present invention.

The present invention relates to a voltage regulator for supplying a voltage to a load circuit, in particular a technique for protecting the load from the effects of overvoltage in the event of a fault.

In order to avoid the problem of reducing the weight and cost of the line separating transformer, the television receiver may be directly supplied power from the AC power line through the rectifier and the filter. The value of rectified DC voltage fluctuates in proportion to the variation of AC power line voltage, which is undesirable, and the value of rectified DC voltage is almost the peak value of AC input, which is larger or smaller than desired value. have.

The use of serial transmission regulation circuits can produce regulated output voltages that are smaller than the unregulated DC inputs, but the drawback is that they consume significant power when the load current and / or the difference between the unregulated and regulated voltages is large. In television receivers, it is shown in US Pat. No. 3,881,135 to obtain a boosted and regulated voltage by combining a winding of a transformer and a controlled rectifier in series with an unregulated direct current input. The windings of the transformer are driven by a horizontal deflection circuit, so that the regulated output suppression occurs as the resulting alternating voltage is controllably rectified and filtered. In the configuration of the U.S. patent, the load includes an SCR that clamps the boost adjustment output voltage to the unregulated input voltage when a difference between the boost adjustment output voltage and the unregulated input voltage exceeds the zener diode of the zener diode. The clamping device containing the diode is protected against excessive regulation voltage.

In order to reduce the influence of the voltage applied to the horizontal output transformer, it is preferable to make the output voltage after adjustment lower than the unregulated DC voltage. This can be done by the step-down device. By this step-down device, the unregulated voltage is brought to a lower regulated voltage by the windings of the transformer, the controlled rectifier and the capacitor. In order to prevent damage to the horizontal output transistor in the event of an overvoltage, it is desirable to perform overvoltage protection of the step-down regulator.

The voltage regulator according to the preferred embodiment of the present invention includes a unregulated DC voltage source connected to the first terminal with respect to the reference point. The AC voltage source and the capacitance are connected to the unregulated DC voltage source by controlled switch means such that a regulated voltage is generated at the second terminal. In the event of a failure, the voltage at the second terminal is almost limited to the above unregulated voltage by the overvoltage protection means. The overvoltage protection means includes a din direction current conduction means coupled between the first and second terminals such that the voltage is applied to the second terminal when the voltage exceeds the voltage of the first terminal. The protective means has resistance means for limiting the current of the AC voltage source when the unidirectional current conducting means is connected in series with the AC voltage source in series.

EMBODIMENT OF THE INVENTION Hereinafter, this invention is demonstrated in detail with reference to drawings.

1 shows a power regulator 10 in accordance with the present invention. This power regulator 10 has a diode rectifier 12 and a filter capacitor 14, and is powered from a pair of terminals 16a and I6b coupled to an AC diagram (not shown). The terminal 16b acts as a reference terminal of the adjustment circuit. The junction of the diode rectifier 12 and the capacitor 14 is coupled to the load represented by the resistor 40 through the capacitor 20. The smaller value is a series circuit including the resistor 22, the secondary winding 24b of the transformer 24, and the anode-cathode passage of SCR26, connected in parallel with the capacitor 20. In addition, a diode 28 whose anode is coupled to the connection point between the capacitor 20 and the resistor 40 is connected in parallel with the capacitor 20. The primary winding of the transformer 24 is shown by a block 30 and is driven by an AC power source.

An SCR control circuit, shown in block 32, is connected between both ends of the load 40 and to the gate of SCR26.

In operation, an unregulated direct current voltage appears between both ends of the capacitor 14. An AC voltage is generated between the both ends of the secondary winding 25b and supplied as a DC voltage to the capacitor 20 by SCR26 acting as a control rectifier. The voltage between both ends of the load 40 is the logarithm of the voltage between both ends of the capacitor 14 and the voltage between both ends of the capacitor 20.

The thyrister, ie, SCR26, becomes periodically non-conducting when the voltage generated in the winding 24 causes the anode of SCR26 to be negative with respect to its cathode. During the period in which the positive pole of the SCR is positive with respect to the negative pole due to the winding 24b and the voltage, the SCR is kept in a non-conductive state until a pulse is supplied from the control circuit 32 to the gate. The control circuit 32 generates a gate pulse having a time relationship with respect to the alternating voltage of the winding 24b, thereby controlling the relative conduction time of the SCR26 in response to an adjustment voltage between both ends of the load 40, thereby changing the load impedance. Alternatively, the regulated voltage is kept constant regardless of the variation of the unregulated DC voltage.

The diode 12 is connected at a polarity such that the unregulated DC voltage appearing between the both ends of the capacitor 14 becomes positive with respect to the reference terminal 16b. If it is just a rectifier, the capacitor 20 is charged such that the pole plate on the left side of FIG. 1 is negative and the pole plate on the right side is positive, and the adjustment voltage is greater than the voltage between the two ends of the capacitor 14, It will be more positive. On the other hand, when the SCR26 is in a non-conductive state, the capacitor 20 is charged to the opposite polarity through the load 40.

The control circuit 32 has a conduction level of the SCR26, in which the adjustment voltage seems to be maintained more negative than the unadjusted voltage, that is, the pole plate on the left side of the capacitor 20 is made to have a positive potential with respect to the pole plate on the right side. Is adjusted to set.

In the case of a fault condition, for example, SCR26C becomes a diode, the voltage between both ends of the load 40 tries to increase.

When a significant AC peak voltage appears in the winding 24b, the voltage rise between the terminals of the load is destructive. The rise of the voltage between the load terminals above the unregulated voltage is stopped by the diode 28. This diode 28 is forward biased to provide a low impedance path from the load circuit 40 to the capacitor 14.

The resistor 22 limits the short circuit current of the secondary winding 24b when the SCR26 is in the high transient state and the diode 28 is in the conduction state. As is known, the grinding resistor 22 may be the internal resistance of the winding 24b. As is well known, the capacitor 20 may be connected in parallel with the load circuit 40 as shown by the dotted line and the reference numeral 20.

FIG. 2 is a circuit diagram of an embodiment in which the principle of the circuit shown in FIG. 1 is applied to a television receiver. The AC power supply 30 and the resistor 40 of FIG. 1 are horizontal deflection circuits in FIG. In FIG. 2, the unadjusted voltage source 210 has a plug 212 which is applied to the terminal of the full-wave bridge rectifier, shown as 213 to rectify the alternating voltage. A filter capacitor 214 is connected between the diagonal connection points of the bridge rectifier 213 to filter the rectified output. One terminal of capacitor 214 is coupled to terminal 210a by a radio frequency interference signal (RFI) filter inductance 215 and the other terminal to terminal 210b through filter inductance 216. . The unregulated DC voltage is represented by the terminal 210a based on the reference terminal 210b (hereinafter, referred to as a ground point).

A shunt adjusting unit, shown as 220, is coupled between the terminal 210a and the ground point. The regulator 220 includes a series drop resistor 222 having one end connected to a terminal 210a. The other end of the resistor 222 is connected to a zener diode 224 whose anode is connected to the ground point. A capacitor 226 is connected between both ends of the diode 224 for noise reduction. The Zener adjustment output voltage of the regulator 220 appears at the terminal 228 with reference to the ground point.

The unadjusted voltage at which the terminal 210a appears is coupled with the voltage between both ends of the filter capacitor 240 by the conductive line 230. The sum of these voltages is supplied to the load circuit composed of the winding 272d of the transformer 272 and the NPN type horizontal output transistor 262 of the horizontal deflection circuit 260 at the terminal 251. Transistor 262 has an emitter connected to a ground point, and a damper diode 264, a retrace capacitor 266, a grease horizontal deflection winding 268 and an S-shape in parallel with the emitter-collector passage. The series connection of the crystal capacitor 270 is respectively connected. A resistor 273 is connected in parallel with the base-emitter junction of the transistor 262.

The base of the transistor 262 is coupled to the secondary winding of the drive transformer 277 by a series inductor 274, a shunt capacitor 275, and a series resistor 276. The primary winding 277a is driven by a drive circuit 278 that receives an input from another portion (not shown) of the television receiver.

A resistance-capacitance connected between the both ends of the small current limiting resistor 242, the secondary winding 272a of the transformer 272, the inductor 244, and the anode-cathode passage of the SCR246 in parallel with the capacitor 240. The damping circuit 28 reduces the effect of the transient caused by switching. The overvoltage protection diode 250 has a negative electrode coupled to the terminal 210a and a positive terminal coupled to the terminal 251. A capacitor 249 for preventing radio frequency interference is connected between the gate of the SCR246 and the cathode.

Gate control of the SCR 246 is performed by a control circuit 280 that receives operating power from the terminal 288. Circuit 280 includes a capacitor 282 coupled as an oscillator to current source 283 and latch circuit 290.

The oscillator controls the gate of the SCR 246 by means of a pulse generated during the horizontal deflection period through the transformer 286. The occurrence time of this pulse during the horizontal deflection period is changed under the control of the error amplifier shown by reference numeral 320, and the voltage between the terminal 251 and the terminal of the horizontal deflection circuit 260 is kept constant along the ground point.

One end of the capacitor 282 is coupled to the power supply terminal 228, and the other end is coupled to the collector of the NPN transistor 284 of the current source 233. The emitter of transistor 234 is grounded by resistor 235. The latch circuit 290 has a PNP transistor 292 and an NPN transistor 294, and the emitter of the transistor 294 is connected to the collector of the transistor 994 by a protective diode 295. The collector of the transistor 294 is connected to the power supply terminal 228 by the resistors 296 and 297 of the voltage divider 298. The base of the transistor 292 is connected to a tap of the voltage divider 298. The base of the transistor 294 is biased by a voltage divider 300 including resistors 302 and 304 connected between a power supply terminal and a ground point.

The voltage at the base of the transistor 294 is provided by a resistor 306 connected between the base of the transistor 294 and the collector of the transistor 292 and the collector and transistor 284 of the transistor 292. It is partly controlled by a resistor 308 in contact with the emitter. The collector of the transistor 292 is connected to the primary winding 286a of the transformer 286 by a diode 310. The other end of the winding 286a is connected to the collector of the transistor 284. The latch circuit 290 is slowed down by the radio frequency interference suppression capacitor 312 connected between the base of the transistor 294 and the collector.

The error amplifier 320 includes a PNP transistor 322 having an emitter coupled to the power supply terminal 288 and a collaborator coupled to the base of the transistor 284 through resistors 324a and 324b. . The base of the transistor 284 is connected to the ground point by a resistor 326. The base of transistor 322 is coupled to a tab of voltage divider 330, which is a resistor 332 and 334 coupled between terminal 251 and the ground point, that is, between the terminals of horizontal deflection circuit 266. The cathode of the diode 340 is coupled to the power supply terminal 228, and the anode of the diode 340 is coupled to the collector of the transistor 284. In addition, the cathode of the diode 342 is coupled to the anode of the diode 340, and the anode thereof is coupled to the collector of the horizontal output transistor 252 through the series resistor 344.

When alternating current is initially applied to plug 212, power source 210 and regulator 220 generate voltages at terminals 210a and 228 in a known manner. The horizontal deflection circuit 260 is initially in an inoperative state and the SCR 246 is in an off state. Therefore, the voltage at the adjustment output terminal 251 is lower than a desired value, and the transistors 322 and 284 are sufficiently conducted to charge the capacitor 282 rapidly. The voltage of the collector of transistor 284 falls, i.e., becomes more negative as the capacitor 282 charges, and the transistor 294 has an emitter voltage of which it is associated with the plane 304, the resistors 285, 306 and 308; It is conducted when the voltage is lower than the voltage of the voltage divider 300 as modified by being connected in parallel.

When the transistor 294 conducts, the transistor 292 conducts. The collector voltage increases due to the conduction of the transistor 292, and the voltage of the base of the transistor 294 is positively raised, resulting in the transistor 292 being saturated, and the primary winding of the transformer 286 with respect to the capacitor 292. Discharge paths refer to the 286a and the diode 310. Saturation of transistor 292 raises the emitter voltage of transistor 284 to cut off the current from current source 283, while eliminating the converters connected in parallel to resistor 304 and instead of resistor 306. Is connected in parallel to the resistor 202 to modify the base voltage of the transistor 294.

The emitter voltage of transistor 294 rises, ie, becomes more positive with respect to the ground point with the discharge of capacitor 282. Capacitor 282 continues to discharge until the emitter voltage of transistor 294 rises above the base voltage determined by resistor 306 and voltage divider 300 coupled to saturation transistor 292 to a power supply terminal. do. When the emitter voltage of the transistor 294 is higher than the base voltage, the transistor 294 has reduced conductivity and the driving action of the transistor 292 is reduced so that the transistors 292 and 294 are positively turned off. (tun-off). As a result, the operation of the current source 283 is restored to start charging the capacitor 282 again. This repetitive oscillation generates a pulse on the secondary winding 286b of the transformer 286, which is applied to the gate of the SCR 246, which makes the SCR 246 conduction and increases the voltage between both ends of the load. The horizontal deflection circuit 260 starts its operation in a known manner to cause horizontal deflection of the television receiver, and also generates a retrace pulse between both ends of the transistor 262 and the primary winding 272d.

The voltage of the pulse state which makes SCR 246 periodically non-conducting flows to the secondary winding 272a. At the same time, the horizontal retrace pulse in the collector of transistor 262 is applied to capacitor 282 via resistor 334 and diode 342 to discharge capacitor 282. During each successive horizontal retrace period, the diode 340 is brought into a conductive state due to the excess current flowing through the resistor 344 which maintains the discharge of the capacitor 282.

As a result, charging of the capacitor 282 is started at the end of each horizontal retrace period.

The discharge of the control circuit 280 is shorter than the period of the horizontal deflection, which is the original, i.e., non-synchronized period. After the horizontal retrace period during which capacitor 282 is completely discharged, capacitor 282 is charged by current source 283 until transistor 294 conducts and latch circuit 290 performs a latching operation. The capacitor 282 then discharges through the windings 286a and 292 until the transistor 294 and the latch circuit 290 are turned off, and by turning off the transistor 294 and the latch circuit 290. Then, the next charger is started. Shortly after charging, the capacitor 282 discharges with the next horizontal lit period and the cycle starts again. In this manner, the capacitor 282 discharges twice in one full adjustment cycle, that is, once when the latch circuit 290 is triggered, and once during the horizontal retrace period. Thus, the full charge period preceding the trigger of the latch circuit always starts at the end of the retrace period, and stable control is performed. When the adjustment voltage of the terminal 251 with respect to the ground point is about to rise, the abnormal power is transmitted to the base of the transistor 322 by the voltage divider 330 to reduce the conductivity of the transistors 322 and 284, As a result, the filling rate of the capacitor 282 is lowered. As a result, the trigger of the latch circuit 290 during the oscillation period is delayed and the SCR 246 is also delayed in opening. As a result, the conduction time until the turn-off by the next horizontal pulse is shortened. The required voltage level is restored. On the contrary, when a low voltage appears at the terminal 251, the conduction of the transistors 322 and 284 increases, so that the trigger of the SCR 246 during the oscillation period is accelerated, and the required voltage level is restored.

When the SCR 246 deteriorates and becomes a diode, or when an arc discharge occurs between the high electrode and the terminal 251, or a fault such as an open circuit state of the zener diode 224, for example. When this regulator occurs, the voltage at jar 251 is about to rise. Under such a fault condition or arcing of the video tube, the diode 250 becomes conductive when the voltage of the terminal 251 exceeds the unregulated current flow voltage at the terminal 210a. Accordingly, terminal 251 is coupled to a low impedance by capacitor 214 to prevent the voltage at terminal 251 from exceeding the unregulated input voltage.

Without resistor 242, secondary winding 272a is substantially shorted as SCR 246 and diode 250 conduct at the same time. This short circuit is coupled to the primary winding 272d by the action of the transformer to lower the impedance between the two ends, causing the transistor 262 to flow a large amount of current when the voltage at the terminal 252 is higher than normal. As a result, the transistor 262 has an unwanted power burden along with the voltage burden. The resistor 242 not only limits the current flowing through the winding 272a, but also presents a load to the winding 272d that maintains the impedance of the primary winding 272d to a magnitude sufficient to relieve such a burden. As in the case of FIG. 1, the resistor 242 may be provided at any position in the series converter including the winding 272a, the inductor 244, and the SCR 246. As shown in FIG.

In the above description, it was explained that the capacitor 240 is connected between the adjustment voltage terminal 251 and the unadjusted voltage terminal 210a, but this is between the terminal 251 and any reference voltage point, in particular FIG. Like the capacitor 240 whose point velocity is shown by the dotted line, it may connect between the terminal 251 and the reference point 210b. In this connection hole, the circuit operation is the same as in the above-mentioned case, but the adjustment voltage appearing between the terminals of the load is only the voltage between the both ends of the capacitor 240, not the sum of the voltages between the capacitors 214 and 240, respectively.

In certain particular embodiments of the present invention, the values of the elements of the circuit necessary to enable satisfactory operation are as follows.

Claims (1)

An unregulated direct current voltage source having a first terminal at which a unregulated direct current voltage is generated based on a reference point; In the voltage regulator of the type including an AC voltage source; Capacitor; and Control switch device coupled to the unregulated DC voltage source and the AC voltage source and the capacitor to generate a regulated DC voltage at a second terminal, Unidirectional current conduction device 28: 250 coupled between the first terminal 210a and the second terminal 251 with a polarity such that the voltage of the second terminal becomes conductive when the voltage of the second terminal exceeds the voltage of the first terminal. Wow; And a resistance device (22; 242) connected in series with the AC voltage source to limit the current flowing therethrough when the unidirectional current conduction device (28; 250) is in a conductive state, so that the second terminal in case of failure And an overvoltage protection device for substantially limiting the voltage appearing to the unregulated DC voltage.

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