KR790000815B1 - Line isolattion with scr deflection - Google Patents

Abstract

A device for insulating a TV receiver chassis from the AC line voltage power source, consisted of a rectifier(103) and a filter(105,106) to rectify and filter the AC line voltage, a switching device having primary and secondary bi-directional conductive switches. The primary coil for current conduction and the secondary coil for voltage control were magnetically coupled to each other, but electrically insulated.

Description

Line Insulation Circuit with SCR Deflection Circuit

1 is a block and schematic diagram of a deflection circuit incorporating an embodiment of the present invention.

2 is a block and schematic diagram of a deflection circuit incorporating yet another embodiment of the present invention.

The present invention relates to an apparatus for isolating a television receiver chassis from an AC line voltage power source. Considerable efforts have been made in the past to power television receivers without the use of isolation transformers. Since the isolation transformer must be physically large, difficult to handle, and expensive to obtain the power condition of the television receiver, the receiver containing the isolation transformer must not use the insulation transformer. It has been known that the volume must be larger and more expensive than ever.

The use of a solid state element that does not require the high DC operating voltage required for the tube tube receiver circuit results in the use of a low DC operating voltage directly drawn from the rectified and filtered AC line voltage without the need for an isolation transformer. However, there is a problem in removing the isolation transformer. The problem is the loss of receiver chassis insulation from the AC line. That is, the receiver chassis without the isolation transformer is connected to a certain reference voltage set by the AC line. Such sash is often referred to as hot sash as opposed to isolation or cold sash.

In a hot chassis, both the operation control and the receiver cabinet must be insulated from the chassis to prevent the operator from the possibility of shock. Furthermore, by adding to other functional receivers that require the use of peripheral devices such as television cameras and videotape recorders that are isolated from the AC line reference voltage, the problem of insulation becomes even greater. When connected to the receiver, these devices must be operated from the same reference voltage as the receiver in order to function properly. However, due to the fact that these reference voltages vary substantially from the reference voltage of the receiver, for example between the AC line reference voltages, the possibility of the operator's check as well as the damping between the various reference potentials set in the receiver and its associated peripherals (damping) The current is determined. As such, it is desirable to have a line transformer insulation design that has a low volume and associated cost.

The apparatus according to the present invention is arranged to insulate the reference panel within a television receiver from a voltage source between the AC lines, from which the power for the receiver is derived. The apparatus comprises first and second rectifier and rectifier and filter devices connected to the first and second terminals for rectifying and filtering the voltage between the AC lines to provide a first DC voltage source for the first terminal with respect to the second terminal. Contains the second terminal. In addition, a first and a second bidirectional conductive switch connected to the deflection winding are included to generate a deflection current in the deflection winding, and the first switch flows a DC current connected to the first and second terminals.

The first winding is connected to a switching device for inducing a current flowing there in response to the operation of the switching device. The second winding is magnetically connected to the first winding and is electrically insulated, and in response to a current flowing in the first winding, a voltage change is brought there. The second winding is connected to the reference potential source to have the voltage change caused therein with respect to the reference potential.

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings. In the first embodiment of the present invention shown in FIG. 1, an alternating current line is connected to two terminals P and Q of the bridge rectifier 103 via a switch 101. Terminals P and Q are also connected across the primary winding 165a of transformer 165. The secondary winding 165b of the transformer 165 lowers the AC line voltage accumulated in the capacitor 170 and rectified by the rectifier 168 to provide the low power requirement of the horizontal oscillator 175, that is, the low direct current operating voltage. The horizontal sync signal 100 is connected to terminal F of the horizontal oscillator 175.

Accumulation capacitor 104 is connected to the remaining two terminals R and S of bridge rectifier 103. Filter resistor 106 is connected to terminal R. The other terminal of resistor 106 is connected to the terminal of the filter capacitor 105, and the other terminal of the capacitor is connected to the terminal S. The junction terminal V of the resistor 105 and the capacitor 106 is connected to the terminal of the primary winding 108a of the input reactor 108. The other terminal of winding 108a is connected to the anode of SCR 109 and to the cathode of diode 110, which is comprised of a bidirectional conductive rectifying switch. The cathode of SCR 109 and the anode of diode 110 are connected to terminal S.

The anode of SCR 109 and the cathode of diode 110 are connected to the first terminal of the rectifying inductor 112 and the other terminal of the inductor is connected to the first terminal of the capacitive voltage divider network consisting of capacitors 114 and 116 connected in series. The other terminal of capacitor 116 is connected to terminal S. The first terminal of the rectifying capacitor 120 is connected to the junction of the capacitors 114 and 116 and the other terminal thereof is connected to the anode of the SCR 121 and the cathode of the diode 123.

The SCR 121 and the diode 123 together form a trace switch having bidirectional conductivity. The cathode of SCR 121 and the anode of diode 123 are connected to terminal S. The series combination of primary winding 130a of the horizontal output transformer 130 and the accumulating capacitor 125 is connected across the bidirectional conductive sweep line switch consisting of SCR 121 and diode 123. The primary winding of the relatively small, low power isolation transformer 180 is connected to a horizontal oscillator 175. The secondary winding of the transformer 180 is connected to the gate electrode and the terminal S of the rectifying SCR 109.

The secondary winding 108b of the input capacitor 108 is connected to one terminal and the terminal S of the capacitor 141. The other terminal of the capacitor 141 is connected to the terminal S via a resistor 142 and to the gate electrode of the sweep line SCR 121 via the winding 143. The circuit consisting of elements 141, 142, and 143 forms the voltage pulses appearing across winding 108b when current flows through 108a. The pulse is used to trigger the SCR 121 to its conductive state.

Winding 130b of the horizontal output transformer 130 is connected between the high voltage multiplier 160 and terminal C. The output terminal HV of the high voltage multiplier 160 supplies the kinescope (not shown) with the high voltage leaked due to the rectification and increase of the horizontal deflection retrace voltage pulse generated across the winding 130b. Terminal C is one terminal of accumulator capacitor 146 and the other terminal thereof is connected to a reference board such as ground. The voltage change in the sweep line period across the capacitor 146 is supplied to another receiving circuit.

Winding 130d of transformer 130 is connected between the reference source, such as ground, and the anode of rectifying diode 155. The negative terminal of rectifier 155 is connected to terminal D of accumulation capacitor 154 and the other terminal of the capacitor is connected to the ground reference potential. The rectified voltage is provided from terminal D for another receiver circuit. Winding 130d is also connected to horizontal oscillator 175 to provide pulses for automatic frequency regulation (AFC) of horizontal oscillator 175.

One terminal of the winding 130c of the transformer 130 is connected to a reference board such as ground, and the other terminal is connected to a series coupling of a deflection yoke and an S-type capacitor 151 composed of two series-connected windings 152a and 152b. The other terminal of this series circuit is connected to the ground reference potential.

The ground potential mentioned in the operation on the circuit of FIG. 1 is the potential of the receiver chassis. The operation of the bidirectional switch horizontal deflection device shown in FIG. 1 is described in detail in US Pat. No. 3,452,244, issued June 24, 1969 to the same inventor as the present invention, but here also to aid the understanding of the present invention. I will briefly describe it.

At the beginning of the horizontal deflection sweep line segment, the trace line damper diode 123 is forward biased at the end of the continuous return section by the current flowing in the winding 130a. Current flows forward through diode 123 to charge capacitor 125 again. The above-described current flowing from the direct current voltage source installed at terminal V via windings 108a and 112 charges capacitors 114, 116, 120 and 125. Occasionally, about half way through the sub-line section, diode 123 is reverse biased.

As energy is applied to the device, the current flowing through the winding 108a induces a corresponding voltage across the winding 108b formed by the elements 141, 142 and 143 when the SCR 121 is replaced by the conductive state. At that time, the SCR 121 is forward biased so that current begins to flow backward in the winding 130a when the capacitor 125 is discharged. The inversion of the current flow in the winding 130a means the beginning of the second half of the sweep line section.

The output pulses from the horizontal oscillator 175 are connected to the secondary winding of transformer 180 which applies sufficient voltage to its gate electrode so that SCR 109 conducts, so that capacitors 114, 116 and 120 charged from the current flowing through windings 108a and 112 are Discharge through the winding 112 begins. This occurs shortly before the start of the return section. Capacitors 114, 116 and 120 discharge through winding 112 and SCR 109. Discharge currents of capacitors 114 and 120 flow through diode 123. When the discharge current of capacitors 114 and 120 increases, SCR 121 becomes non-conductive. Discharge currents of the capacitors 114 and 120 also flow in the winding 130a.

When capacitors 114 and 120 are discharged, the energy accumulated in windings 112 and 130a charges them in the opposite direction, and diode 123 is reverse biased, thereby becoming nonconductive. The retrace section then begins when the resonant retrace circuit consisting of the inductance of the winding 130a and the capacitors 125, 120, and 116 transfers energy from the inductance to the capacitance and slows it down for a positive half cycle of operation. As capacitors 125, 120, and 116 are charged and energy is recovered, the current in winding 130 rapidly decreases.

At that time, when capacitors 125, 120, and 116 are discharged back through winding 130, the current in winding 130a is reversed. When the current in winding 130 reaches its maximum, the deflection return section ends. Diode 123 begins to conduct between the winding 130 and capacitors 125, 120, and 116 to reduce the negative half period of amplitude. When diode 123 conducts and charges capacitor 125, energy begins to recover from winding 130a. This means the start of the next succeeding minorship segment.

Current flow in winding 130a results in a voltage change across windings 130b, 130c and 130d. The retrace section pulses appearing at the junction of winding 130b and high voltage multiplier 160 are rectified to produce a high kinescope voltage at terminal HV. The positive sweep line voltage shown at terminal C supplies the operating potential required for the other receiving circuit connected across capacitor 146. In a similar manner, the positive sweep line voltage present at the anode of diode 155 supplies a direct current voltage to terminal D. Similar voltage induced across winding 130c is sufficient to cause a deflection current flowing through deflective windings 152a and 152b coupled in series. S-type capacitor 151 helps to achieve deflection linearity.

It should be noted that the voltages induced in windings 130b, 130c and 130d are based on the receiver chassis ground reference potential connected to the terminals of capacitors 146 and 154 and not on the AC line flowing out of the reference potential of terminal S of the horizontal deflection generator. do. By adjusting the capacity of the SCR horizontal deflection device and using the power coupled to the voltage change induced in the winding 130a via the horizontal output transformer 130, the power required when the receiving circuit is stopped is insulated from the sash from the AC line. It is supplied while it is maintained. This isolation is achieved without the need for an isolation transformer for the receiver power source. Since the low voltage, ie low power, provided by transformer 165 and signal coupled isolation transformer 180 is not necessary, the need for an isolation transformer of the receiver is eliminated.

It should be noted that the switching voltage across the secondary winding of transformer 180 and across winding 108b for SCR 109 and 121, respectively, is based on the deflection generator reference potential at terminal S. Furthermore, it should be noted that the voltage across the series coupling of deflection windings 152a and 152b is based on the sash potential rather than on the potential of terminal S. This is important in providing a potential difference control between potentials, such as receiver deflection windings, based on the potential of the chassis that is close to the highest horizontal deflection winding potential. This peak voltage difference can be reduced by conventionally known methods such as coupling the center tap to chassis ground rather than the junction of windings 130c and 152 using, for example, a secondary winding 130c that has become a center tap.

In the second embodiment of the present invention shown in FIG. 2, the AC line is connected to two terminals P 'and Q' of the bridge rectifier 203 via a switch 201. Terminals P 'and Q' are also connected across primary winding 265a of transformer 265. Secondary winding 265b of transformer 265 reduces the AC line voltage rectified by rectifier 268 and accumulated in capacitor 270 to provide a low direct current operating voltage, low power of horizontal oscillator 275. The horizontal sync signal 200 is connected to terminal F 'of the horizontal oscillator 275.

Accumulation capacitor 204 is connected across the two remaining terminals R 'and S' of bridge rectifier 203. Filter resistor 206 is also connected to terminal R '. The other terminal of resistor 206 is connected to one terminal of filter capacitor 205 and the other terminal is connected to terminal S '. Junction terminal V 'of resistor 205 and capacitor 206 is connected to one terminal of input reactor winding 208. The other terminal of winding 208 is connected to the anode of SCR 209 and the cathode of diode 210. These two devices constitute a rectifier switch with bidirectional conductivity. The cathode of SCR 209 and the anode of diode 210 are connected to terminal S '.

The anode of SCR 209 and the cathode of diode 210 are connected to the first terminal of rectifier inductor 212 and the other terminal of the inductor is connected to the first terminal of capacitor 214. The other terminal of the capacitor 214 is connected to the first terminal of the primary winding 230a of the horizontal output transformer 230. The other terminal of winding 230a is connected to terminal S '. The primary winding of the isolation transformer 280 is connected to a horizontal oscillator 275. The secondary winding of the transformer 2 280 is connected to the gate electrode of the rectifying SCR 209 and the terminal S '.

Winding 230b of horizontal output transformer 230 is connected between terminal C 'and high voltage multiplier 260. The output terminal HV of the high voltage multiplier 260 increases the horizontal deflection retrace pulse generated through the winding 230b and supplies the high voltage emanating from the rectification to the kinescope (not shown). Terminal C 'is connected to one terminal of the accumulator capacitor 246 and the other terminal of this capacitor is connected to a reference board such as ground. The sweep line duration voltage that appears across capacitor 246 is supplied to another receiver circuit.

Winding 230d of transformer 230 is connected between a reference conductor, such as ground, and the anode of rectifier diode 255. The negative terminal of rectifier 255 is connected to terminal D 'of accumulating capacitor 254 and the other terminal of the capacitor is connected to the ground reference potential. The rectified voltage is provided from terminal D 'for the other receiver circuit. Winding 230d is also coupled to the horizontal oscillator 275 to provide pulses for automatic frequency control (AFC) of the horizontal oscillator 275.

Winding 230c of transformer 230 is connected to a reference conductor, such as ground, at one terminal through accumulating capacitor 225. The other terminal of winding 230c is connected to a series coupling of a deflection yoke consisting of two parallelly connected deflection windings 252a and 252b and an S-type capacitor 251. The return capacitor 232 is connected across winding 230c. The other terminal of this series circuit is coupled to the ground reference potential. A two-wire conducting wire switch consisting of SCR 221 and diode 223 is connected to the junction of winding 230c and capacitor 251. The anode of SCR 221 and the cathode of diode 223 are connected to ground.

The ground potential mentioned in the operation of the FIG. 2 circuit is the potential of the receiver chassis. The operation of the dual bidirectional switch deflection device shown in FIG. 2 is similar to that of the device shown in FIG. The difference is described here to help understand the present embodiment. In the basic dual bidirectional switch deflection apparatus described in the above-mentioned US patent, the sweeping line and the rectifier switch are connected to an alternating current and are consumed in the deflection apparatus depending on the capacitive and inductive energy accumulating elements and the horizontal output from the apparatus. Generates a current that supplements the energy delivered to the secondary winding of the transformer. In the apparatus of FIG. 2, the sweep line and the rectifier switch are connected to an alternating current, but in this embodiment the switch is a transformer connected via a horizontal output transformer.

At the beginning of the horizontal deflection sweepline section, the tracer damper diode 223 is forward biased at the end of the immediately preceding section by the energy accumulated in the windings 252a and 252b. Current flows forward through diode 223 to charge capacitors 225 and 251. Sometimes diodes 223 are reverse biased at about half way through the sweep line.

The voltage pulse based on the sash ground supplied by the horizontal oscillator 275 causes the gate electrode of the SCR 221 to be positive to make the SCR 221 conductive. SCR 221 begins to conduct current reversely in windings 230c, 252a and 252b when capacitors 225 and 251 are discharged. The inversion of the current flowing in the yoke windings 252a and 252b means the beginning of the second half of the horizontal deflection sweep line section.

The output pulse from horizontal oscillator 275 is already charged from the current flowing through windings 208 and 212 when connected to the secondary winding of transformer 280 causing a voltage pulse on each of terminals S 'so that it is conducted at the gate electrode of SCR 209. Capacitor 214 begins to discharge through winding 212. This starts the commutation section and implies the return section. This occurs shortly before the start of the retrace section. Capacitor 214 discharges through windings 212,230a and SCR 209. The discharge current of the capacitor 214 flowing through the winding 230a causes a voltage change to appear across the winding 230c. This change causes current to flow in the sweep wire SCR 221 and diode 223. SCR 221 is reverse biased into a non-conductive state.

The current continues to flow in the diode 223 until the discharge flow of the capacitor 214 falls below a value corresponding to the deflection current in the windings 252a and 252b. At that time, the diode 223 is reverse biased. The windings 252a and 252b then oscillate for a positive half cycle with respect to the winding capacitor 232 as the winding transfers energy to the capacitor 232. When the voltage across capacitor 232 reaches its peak, the current in windings 252a and 252b reaches zero at the center of the retrace period. At that time, during the second half of the retrace period, the retrace capacitor 232 is discharged through the windings 252a and 252b to cause the necessary reverse current during the second half of the retrace period. When the current reaches maximum, the negative half period of the oscillation of windings 252a and 252b for retrace capacitor 232 is reduced by conduction of diode 223. When the damper diode 223 begins to conduct, the deflection return section ends. Since diode 223 is forward biased to cause deflection sweep line section current flowing through deflection windings 252a, 252b and capacitor 251, the energy accumulated in windings 230c, 252a and 252b is recovered. This means the start of the next succeeding minorship segment.

Current flowing in windings 230a and 230c causes a similar voltage change across windings 230b and 230d. The retrace section pulse appearing at the junction of winding 230b and high voltage multiplier 260 is rectified to generate a high kinescope voltage at terminal HV. The positive sweep line duration voltage caused at point C 'provides the sweep line duration DC voltage source across capacitor 246. In a similar manner, the positive sweep line voltage present at the anode of diode 255 supplies a direct voltage to terminal D '.

The voltage caused across windings 230b, 230c, and 230d is referenced to the receiver chassis ground potential connected to the terminals of capacitors 225, 246, and 254, and not to an AC line that outflows the reference potential set at terminal S 'of the horizontal deflection generator. It should be noted that no. By adjusting the capacity of the SCR horizontal deflector and using the power to connect the voltage change caused by the winding 230a to the windings 230b, 230c and 230d of the horizontal output transformer 230, the power required when the receiver circuit is stopped is alternating It will be supplied while maintaining the insulation of the chassis from the wire. This isolation is achieved without the need for an isolation transformer for powering the receiver as in the embodiment of FIG. Since the low voltage power provided by transformer 265 and signal coupled isolation transformer 280 is not required, the need for an isolation transformer of the receiver is raised.

It should be noted that in the embodiment of FIG. 2 the switching voltage for the sweep line SCR 221 must set the reference to the chassis ground rather than to the terminal S '. This is the result of the reason that the sweeping wire SCR 221 in the present embodiment is in the secondary winding 230c and the isolation transformer 230 of the horizontal output. As such, the cathode of SCR 221 is based on chassis ground rather than terminal S '.

The winding windings 152a and 152b of FIG. 1 are connected in series, and the windings 252a and 252b of FIG. 2 are connected in parallel, but either configuration in series or parallel is dependent on the impedance of the deflection winding used. It should also be noted that it can be used as a two degree sweep line switching device.

If transformer 230 is designed such that the leakage inductance between windings 230a and 230b is equal to the required inductance of rectification winding 212, the advantage of the embodiment of FIG. 2 is that rectification winding 212 can be eliminated. In a diagram, this may be shown by connecting the A-B terminal of the short winding 212 of FIG. 2 to A'-B '. This is because the arrangement of the sweep line switch consisting of diodes 223 and SCR 221 in the secondary winding 230c of the horizontal output transformer 230 placed a leakage inductance of windings 230a and 230c between the rectifying switch consisting of SCR 209 and diode 210 and the sweep line switch. It is possible. The configuration of the rectifying inductance and capacitance between the rectifying switch and the sweep line switch required for the proper operation of the dual bidirectional switch deflection device is maintained as above.

An additional advantage of the second embodiment is that only the current caused by the current flowing in the winding 230a required to flow in the winding 230c is followed by the rectifying section current required for the reverse bias of the sweep line SCR 221 and the recharging following the capacitors 225 and 251. It becomes a current. As such, a smaller RMS current flows in winding 230c than in the embodiment of FIG. Moreover, since the sweep line switch is in the secondary winding 230c having the deflection winding, there is much less interaction between the load current and voltage change at the terminals C ', D' and the current of the deflection winding 252a, 252b. As such, the embodiment of FIG. 2 makes the linearity of the horizontal deflection scan current better during the sweep line period.

Both the embodiments of FIGS. 1 and 2 achieve another unique advantage of overcoming the non-insulation or sash of the dual bidirectional switch deflection apparatus. As mentioned above, such devices typically use half-wave rectified line voltage to provide deflection power. The apparatus of FIGS. 1 and 2 uses a full-wave bridge rectifier using four diodes rather than one diode required for a half-wave rectifier device, so that the rectified voltage is supplied substantially continuously to the first and second device. It can be seen that. As a result, full-wave rectification voltages require smaller filter capacitors 104 and 105 in FIG. 1 and 204 and 205 in FIG. 2, resulting in cost savings in these filtered and accumulated power capacitors.

Claims (1)

As described in the text and shown in the drawings, an apparatus for insulating a reference panel in a television receiver from an AC line voltage source drained from the power for the receiver, the first and second terminals, the terminals and the ac A rectifier and filter device for rectifying and filtering the voltage between the AC line to provide a first direct current voltage source to the first terminal with respect to the second terminal, and a direct current connected to the first and second terminals. A switching device containing first and second two-way conductive switches connected to the deflection winding so that the current flows through the deflection winding and the first switch, and the switching device inducing a current to flow in response to the operation of the switching device. A primary winding connected to and electrically connected to the primary winding and electrically insulated therefrom with respect to the reference potential A line isolation circuit with SCR deflection circuit to have the voltage change characterized by including a secondary winding in response to the current flowing in the first and a secondary winding connected to the reference the potential source to obtain the voltage change induced on.

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