JP2858370B2 - Power supply for television - Google Patents

Description

Description: BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention provides a television receiver having a function of receiving a satellite broadcast, a teletext broadcast, or the like, to supply a stable DC voltage to the television receiver, and to operate the television receiver alone by itself. The present invention relates to a television power supply device designed in accordance with the present invention.

2. Description of the Related Art In recent years, television receivers have built-in satellite broadcast receivers and text broadcast receivers, and can be operated independently. In order to cope with such multi-functionality, conventionally, it has been possible to operate each unit independently by means of providing one power supply for one function.

Hereinafter, an example of the above-described conventional television power supply device will be described with reference to the drawings.

FIG. 7 shows a configuration of a conventional television power supply device. In FIG. 7, 1 is an AC power input terminal,
2 is a manual main switch that turns off all power to the TV,
Reference numeral 3 denotes a control signal for turning on / off the power of the television by a remote controller, 4 denotes a relay switch for turning on / off the power of the television by a control signal 3 from the microcomputer, 5 denotes a control signal for turning on / off only the power of the television, and 6 Is a relay switch which is turned on / off by a control signal 5 from a microcomputer for turning off the power of only the television and setting the answering machine in which only the satellite broadcast receiving circuit 24 is operating, 7 is a line filter, 8 is an AC input A rectifier circuit section of a switching power supply for television for rectifying and smoothing a voltage, 9 is a rectifier circuit section of a switching power supply of a satellite broadcast receiving circuit 24, 10 is a switching power supply for television, 11
Is a switching power supply for the satellite broadcast receiving circuit 24, 12 is a remote control transformer for supplying standby power for the microcomputer, 13 is a rectifier circuit for standby power supply, 14 is a high voltage generation circuit composed of a flyback transformer, and 15 is an electron beam. A horizontal deflection circuit for horizontal deflection, 16 is a flyback pulse from the horizontal deflection circuit 15, 17 is a power supply voltage of the high voltage generation circuit 14 and the horizontal deflection circuit 15, 18 is a vertical deflection circuit for vertically deflecting the electron beam, and 19 is a vertical deflection. Power supply voltage of the circuit, 20 is a video signal processing circuit for converting an RF signal to an RGB signal for reproducing an image on a CRT, 21 is a power supply voltage of the video signal processing circuit 20,
Reference numeral 22 denotes an audio output circuit including an amplifier circuit, 23 denotes a power supply voltage of the audio output circuit 22, 24 denotes a satellite broadcast receiving circuit, and 25 denotes a plurality of power supply voltages of the satellite broadcast receiving circuit 24. In addition, 17,1
The power supply voltages 9, 21, and 23 are output from the switching power supply 10, and the power supply voltage 25 is output from the switching power supply 11.

The operation of the television power supply configured as described above will be described below.

First, a case where all circuits operate and a television is displayed will be described. When the main switch 2 is closed, an AC voltage is supplied from the AC power input terminal 1 to the remote control transformer 12, so that standby power is generated in the rectifier circuit section 13 on the secondary side, power is supplied to the microcomputer, and the microcomputer operates. start. At this time, if the user of the television selects to watch the television, the control signal 3 and the control signal 5 from the microcomputer are output so that the relay switch 4 and the relay switch 6 are both closed. Then, the AC voltage from the AC input terminal 1 passes through the line filter 7, and the power supply voltage rectified by the rectification circuit 8 is supplied to the switching power supply 10, and the power supply voltage from the rectification circuit 9 is similarly supplied to the switching power supply 11. , Both start oscillating. And switching power supply 10
The power supply voltage 17, the power supply voltage 19, the power supply voltage 21, and the power supply voltage 23 are supplied to the horizontal deflection circuit 15, the vertical deflection circuit 18, the video signal processing circuit 20, and the audio output circuit 22, which are the secondary loads, respectively.
Supply as shown in the figure and likewise the switching power supply 11
Also supplies the power supply voltage 25 to the satellite broadcast receiving circuit 24. Therefore, at this time, the television is in a state where all circuits for displaying images and outputting sound are operating, and the user can arbitrarily watch ordinary television broadcast and satellite broadcast programs.

Next, a state in which a satellite broadcast program is recorded from the above state will be described. That is, when recording an arbitrary program with the connected video recorder when the user is absent, the power supply to the television receiver side circuit is stopped to save power, and only the satellite broadcast reception circuit is used. This is the function to operate.

When the user gives an instruction for answering machine and gives the instruction from the remote control or the keyboard on the front of the television, the microcomputer receives the instruction and outputs a control signal 5 so that the relay switch 6 is opened. Then, the switching power supply 10 does not operate because the power supply voltage is not supplied through the line filter 7 and the rectifier circuit unit 8. Therefore, each circuit, which is a load on the secondary side, does not operate, and no image appears on the screen. At this time, since the main switch 2 and the relay switch 4 are kept closed, the switching power supply 11 is operating, and the satellite broadcast receiving circuit 24 is in a state of answering machine which continues to operate by selecting an arbitrary broadcast.

SUMMARY OF THE INVENTION However, in the above configuration, two line filters, two rectifier circuits, and two switching power supplies are required.
There is a problem that the mounting area is large and the cost is high.

SUMMARY OF THE INVENTION The present invention has been made in view of the above circumstances, and provides a small-sized television power supply device capable of performing an answering / recording operation of satellite broadcasting with one switching power supply.

Means for Solving the Problems In order to solve the above problems, a power supply device for television of the present invention is a regenerative control system in which the output voltage on the secondary side is stable from no load to the maximum load state and the regulation is good. Power supply to the horizontal deflection circuit can be controlled by a switch provided between the switching power supply and the horizontal deflection circuit, and the power supply voltage of the vertical deflection circuit and the power supply voltage of the video signal processing circuit can be controlled. Is supplied from the secondary side of the flyback transformer of the high voltage generation circuit.

Effect According to the television power supply device of the present invention, the mounting area occupied by the power supply can be reduced to about half that of the conventional power supply, and the price of the power supply can be reduced.

An embodiment of the present invention will be described below with reference to the drawings. First
FIG. 1 is a block diagram of a television power supply device according to the present embodiment.

In FIG. 1, 1 to 25 except for 5, 6, 7, 8, 9, 10, 11
Up to this point, the operation is the same as the conventional example shown in FIG. 26 is a regenerative control switching power supply, 27 is a rectifier circuit composed of a diode and an electrolytic capacitor with a higher current capacity than the rectifier circuit 8 in FIG. , A switch means which is turned on / off by a control signal 28 from the microcomputer, is inserted between the switching power supply 26 and the horizontal deflection circuit 15.

The operation of the television power supply device configured as described above will be described below with reference to FIG.

First, a case where all circuits operate and a television is displayed will be described. When the main switch 2 is closed, an AC voltage is supplied from the AC power input terminal 1 to the primary side of the remote control transformer 12, so that standby power is generated in the rectifier circuit unit 13 on the secondary side, and power is supplied to the microcomputer. Start working. At this time, if the user of the television selects to watch the television, the control signal 3 and the control signal
28 are output so that the relay switch 4 and the switch means 29 are both closed. Then, the AC voltage from the AC input terminal 1 passes through the line filter 7, and the power supply voltage rectified by the rectification circuit unit 27 is supplied to the switching power supply 26. The switching power supply 26 starts oscillating, and outputs a voltage to its secondary side. Then, a power supply voltage 17, a power supply voltage 23, and a power supply voltage 25 are supplied to the horizontal deflection circuit 15, the audio output circuit 22, and the satellite broadcast receiving circuit 24, which are loads, as shown in FIG. Therefore, at this time, the television is in a state where the circuits for displaying the received broadcast image and outputting the sound are all operating, and the user can arbitrarily watch the television broadcast and satellite broadcast programs.

Next, an operation of changing the state of the above-described state to a state where a satellite broadcast program is recorded in an answering machine will be described. The state of the answering machine is the same as the content described in the above-mentioned conventional example, and thus the description is omitted.

When the user desires an absence message and gives an instruction from the remote control or the keyboard on the front of the television, the microcomputer outputs a control signal 28 for opening the switch means 29.
Then, the switching power supply 26 continues to operate and outputs respective power supply voltages, but the power supply voltage 17 is not supplied to the horizontal deflection circuit 15. Therefore, the flyback pulse 16 is not generated, and the high voltage generation circuit 14 does not operate. Then, the power supply voltage 19 and the power supply voltage 21 are supplied from the secondary side of the flyback transformer of the high voltage generation circuit 14 to the vertical deflection circuit 18 and the video signal processing circuit 20.
Are no longer supplied. This state is the same as when the switching power supply 10 of the conventional example shown in FIG. 7 is not operating because all the circuits for displaying images are not operating. Thus, the answering machine state in which only the satellite broadcast receiving circuit 24 to which the power supply voltage 25 is supplied operates can be realized.

Next, the operation of the switching power supply 26 using the regenerative control method will be described. FIG. 2 is a circuit diagram of the switching power supply 26 used in the present invention. Reference numeral 30 denotes a power supply voltage which is an output voltage from the rectifier circuit unit 27 shown in FIG. 1, reference numeral 31 denotes a primary ground terminal, reference numeral 32 denotes a transformer, reference numeral 33 denotes a primary winding, reference numeral 34 denotes a bias winding, and reference numeral 35 denotes a field effect transistor (hereinafter, referred to as a field effect transistor). A switching element 36 using FET) is a body diode parasitically incorporated in the switching element 35. When the energy stored in the transformer 32 is regenerated to the power supply voltage 30 through the primary winding 33, In addition, a body diode 36 incorporated in the switching element 35 is used to allow the regenerative current of the primary winding 33 to flow even when the switching element 35 is off. 37 turns on the switching element 35 in a predetermined on-period, and turns off the switching element 35 so that the off-period continues until the polarity of the induced voltage of the bias winding 34 is reversed. Synchronous oscillation circuit that keeps oscillating by repetition, 38 is power supply voltage
44 secondary winding, 39 is switching element using FET, 40
Is the body diode of the switching element 39, and the energy of the transformer 32 stored during the on-period of the switching element 35 is transmitted from the body diode 40 or the switching element 39 via the secondary winding 38 during the off-period of the switching element 35. After being discharged to the smoothing capacitor 42, the switching element 39
Is controlled by the control circuit 43 during a reverse flow period in which a secondary current flows through the secondary winding through the secondary winding. 41 is a drive resistance of the switching element 39, 42 is a smoothing capacitor for smoothing the induced voltage of the secondary winding 38 rectified by the body diode 40, 43 is a voltage between the power supply voltage 44 and the ground terminal 61 and detects an internal reference. The above-described control circuit for controlling the backflow period in which the secondary current of the switching element 39 flows compared with the voltage, 44 is the power supply voltage for the horizontal deflection circuit, 45 is the secondary winding of the power supply voltage 48, 46 is the rectifier diode , 47 is a smoothing capacitor, 48 is a power supply voltage for an audio output circuit, 49 is a secondary winding of a power supply voltage 52, 50 is a rectifier diode, 51 is a smoothing capacitor, 53 is a secondary winding of a power supply voltage 56, 54 is Rectifier diode, 55 is a smoothing capacitor, 57
Is a secondary winding of a power supply voltage 60, 58 is a rectifier diode, 59 is a smoothing capacitor, 52, 56, and 60 are all power supply voltages for a satellite broadcast receiving circuit, and 61 is a secondary-side ground terminal. Power-supply voltage
48 is the power supply voltage 23 of FIG. 1, and the power supply voltages 52, 56 and 60 are those of FIG.
25 respectively.

Next, the operation will be described with reference to FIG. 3A shows a voltage waveform VDS across the switching element 35, and FIG. 3B shows a primary current flowing through the primary winding 33.
Indicates the ID, (c) shows a driving pulse waveform VG1 synchronous oscillation circuit 37, shows the (d), flows through the secondary winding 38 secondary current waveform I _0, (e) Shows a drive pulse waveform VG2 of the switching element 39 on the secondary side, and a hatched period in the off period indicates a reverse flow period in which a secondary current flows through the secondary winding 38. The primary current flowing through the primary winding 33 during the on-period of the switching element 35 that operates during the on-period determined by the synchronous oscillation circuit 37 generates magnetic flux in the transformer 32 and accumulates energy. At this time, an induced voltage is generated in the secondary winding 38 of the transformer 32, but a voltage is applied in a direction to reverse bias the body diode 40, and the switching element 39 on the secondary side is turned off. It is configured to be. When the switching element 35 is turned off by the OFF signal of the synchronous oscillation circuit 37, a flyback voltage is generated in the primary winding 33, and a flyback voltage is also generated in the secondary winding 38 to forward bias the body diode 40. Since a voltage is applied in the direction, the energy stored in the transformer 32 is released as a secondary current through the secondary winding 38, and is smoothed by the smoothing capacitor 42 and supplied as the power supply voltage 44. At this time, the switching element 39 on the secondary side is also turned on via the drive resistor 41 by the flyback voltage generated in the secondary winding 45, but the body diode 40
Even if a secondary current flows through any of the switching element 39 and the FET, no change in operation occurs. When all the energy stored in the transformer 32 is released and the secondary current becomes zero, the secondary-side switching element that is already on
Since the voltage across the smoothing capacitor 42, that is, the power supply voltage 44, is applied to the secondary winding 38 via 39, a current flows in the reverse direction from the smoothing capacitor 42, and a magnetic flux in the opposite direction to the above flows through the transformer 32. Generated and energy is stored. In this state, the polarity of the induced voltage generated in each winding of the transformer 32 does not change, and the flyback voltage of the bias winding 34 does not change.
Lasts 35 off periods. The on-period of the secondary-side switching element 39 is controlled by the control circuit 43, and when the secondary-side switching element 39 is turned off, the induced voltage generated in each winding of the transformer 32 reverses its polarity. The induced voltage generated in the winding 38 reverse biases the body diode 40 and the secondary-side switching element 39 is also turned off, so that the secondary winding current does not flow, and the induced voltage generated in the primary winding 33 is This occurs in a direction in which the connection end of the switching element 35 is set to a negative voltage and the connection end of the power supply voltage 30 is set to a positive voltage. Therefore, a primary current flows in the direction of charging the power supply voltage 30 via the body diode 36, and the energy of the transformer 32 accumulated during the off period is regenerated to the power supply of the power supply voltage 30. At this time, the polarity of the induced voltage generated in the bias winding 34 is also inverted.
Turns on the switching element 35, but there is no particular change in operation even when the primary current flows in either of them. When all the energy stored in the transformer 32 during the OFF period is released and the primary current becomes zero, the primary current is discharged from the power supply voltage 30 via the switching element 35 which is already ON so that the primary current is discharged in a direction opposite to the above. The magnetic flux is generated in the transformer 32 and energy is accumulated. In this state, the polarity of the induced voltage generated in each winding of the transformer 32 changes, and the switching element 35 is kept on by the synchronization generation circuit 37. When the switching element 35 that operates during the ON period determined by the synchronous oscillation circuit 37 is turned off, the energy stored in the transformer 32 is released as a secondary current via the secondary winding 38. The power supply voltage 44 is continuously supplied by repeating these operations. Further, the secondary winding 45, the secondary winding 49, and the secondary winding 5 of the
3. A secondary winding 57 is provided to provide a multi-output configuration. One of the power supply voltages 48 is a flyback voltage generated in the secondary winding 45 when the switching element 35 is turned off, and a voltage is applied in a direction of forward biasing the rectifier diode 46. A current flows by the stored energy, and is smoothed by the smoothing capacitor 47 and output. At this time, the other secondary windings have the same operation, and the description is omitted.

Further, an operation in which the output voltage is controlled stably will be described. FIG. 3 shows the operation waveforms of the synchronous oscillation circuit.
The OFF period (t1 to t3) of the 37 drive pulses VG1 is TOFF,
Of which the return period of the secondary current I ₀ (t2 to t3) and T'OFF, whereas the on-period (t3 to t5) and TON, of which the regeneration period of the primary current ID (t3 to t5) and T'ON .

Since the ON period TON is maintained at a constant value determined by the synchronous oscillation circuit 37, if the power supply voltage 44 is constant, the OFF period TOFF is constant and the oscillation frequency f is constant. But the backflow period T'OFF, the control is controlled by the circuit 43 can be changed in the secondary side of the switching element 39, the output current I _out the return period and changes T'OF
Control becomes possible by changing F. Furthermore, the power supply voltage 3
In response to the change of 0, the power supply voltage 44 is changed by changing T'OFF to control the on-period of the switching element 39 on the secondary side controlled by the control circuit 43, so that the backflow period T'OF is controlled.
It is controlled so that F is changed and is constantly constant.

FIG. 4 shows operation waveforms when the output current _Iout changes. Among them, the same components as those in FIG. 3 are denoted by the same reference numerals, and description thereof is omitted. In FIG. 4, the solid line is the output current of the power supply voltage 44.
When _Iout is flowing to the maximum, it indicates the so-called maximum load, and the dotted line indicates when the output current _Iout is zero, that is, when there is no load.

FIG. 5 shows the characteristics of the output voltage with respect to the change in the load of the switching power supply according to the regenerative control method. The vertical axis corresponds to the output voltage on the secondary side, and the horizontal axis is the total load power extracted on the secondary side. At this time, the output voltage is always constant with respect to a change in load.

FIG. 6 shows another embodiment of the present invention. In the configuration shown in FIG. 1, a teletext receiving circuit 64 and a microcomputer between the teletext receiving circuit 65 and the teletext receiving circuit 65 from the power supply voltage 25 are provided. And a switch circuit 63 controlled by a control signal 62 from the controller.

The operation is the same as that of the configuration of FIG. 1. In addition to realizing the answering machine of the satellite broadcast, whether the power supply voltage 64 is supplied to the teletext receiving circuit 65 by turning on or off the switch circuit 63 is determined. Is selected by the user according to the instruction to the microcomputer, the operation of the circuit for displaying the image is stopped when the user is absent, the teletext receiving circuit 65 is operated, and the content of any teletext is transmitted to the teletext receiving circuit. Store it in the memory inside 65,
It is something that the user can later see on any machine.

In this configuration, the user selects one of two states, one in which only the satellite broadcast receiving circuit 24 is operating and the other in which both the satellite broadcast receiving circuit 24 and the teletext receiving circuit 65 are operating. And the telephony answering machine is realized, so that the state where only the teletext receiving circuit 65 is operating is impossible.

Effect of the Invention As described above, according to the present invention, the mounting area occupied by the power supply can be reduced to about half, and the cost can be reduced as compared with the conventional switching power supply, because the power supply can be realized by one system. And other effects.

[Brief description of the drawings]

1 is a circuit diagram showing a television power supply according to an embodiment of the present invention, FIG. 2 is a circuit diagram of a regenerative control type switching power supply used in FIG. 1, and FIG. 3 is FIG. 4 is an explanatory diagram showing operation waveforms of the circuit diagram of FIG. 2, FIG. 4 is an explanatory diagram showing operation waveforms of the circuit diagram of FIG. 2, FIG. 5 is an output characteristic diagram of FIG. 1 of the present invention, and FIG. FIG. 7 is a circuit diagram showing another embodiment of the present invention. 1 AC input power supply terminal 2 Main switch 3
Control signal, 4 ... Relay switch, 7 ... Line filter, 12 ... Remote control transformer, 13,27 ... Rectifier circuit section, 14 ... High voltage generation circuit, 15 ... Horizontal deflection circuit, 16 ...
Flyback pulse, 18 vertical deflection circuit, 20 video signal processing circuit, 22 audio output circuit, 24 satellite broadcast receiving circuit, 25, 64 power supply voltage, 26 switching power supply, 28 power supply ... control signal, 29 ... switch means, 62 ... control signal, 63 ... switch circuit.

Claims (1)

(57) [Claims] A switching power supply for outputting a plurality of stabilized power supply voltages having different values, a fly for outputting a power supply voltage for a vertical deflection circuit and a power supply voltage for a video signal processing circuit, a tuner circuit and the like from a secondary side. A horizontal deflection circuit having a back transformer and a high voltage generating circuit; a first rectifier circuit for rectifying an AC voltage from an AC power supply to the switching power supply to supply a DC voltage; and a power supply voltage output terminal of one of the switching power supplies. A first switch inserted between a horizontal deflection circuit and a power supply voltage terminal for a high-voltage generation circuit; a second switch inserted between the AC power supply and the first rectifier circuit; Control means for turning on and off the first and second switches; and second rectification means for rectifying an AC voltage from an AC power supply and supplying a DC voltage to the control means. Another power supply voltage output terminal of the switching power supply is connected to at least a satellite broadcast receiving circuit, and when the second switch is on, a DC voltage is always supplied to the satellite broadcast receiving circuit and the first switch is turned on. The supply of the DC voltage to the horizontal deflection circuit and the high-voltage generation circuit is controlled to be on / off by turning off, and the satellite broadcasting program received and processed by the satellite broadcasting receiving circuit is recorded by a recording means such as a tape recorder when a viewer is absent. Wherein the first switch is turned off and only the satellite broadcast receiving circuit is operated when recording with the television.