JP2007335950A - Electronic equipment - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide electronic equipment whose services are not stopped except a power supply service to external electronic equipment even when a line of supplying power to the external electronic equipment is failed. <P>SOLUTION: The power output from a SW power supply 21 is supplied to a built-in RF amplifier section 20 and also output via a DC transmission circuit 22 from an input terminal 23a, from which the power is supplied to a satellite broadcast reception antenna as its operating power supply. The DC transmission circuit 22 includes an overcurrent protection circuit 22a that suppresses an overcurrent when the overcurrent flows due to the occurrence of a fault in a line including the satellite broadcast reception antenna from the input terminal 23. Thus, when the overcurrent flows through the line, the overcurrent protection circuit 22a suppresses the overcurrent, an overcurrent protection circuit 21a of the SW power supply 21 is not activated and the power is continuously supplied to the RF amplifier section 20. <P>COPYRIGHT: (C)2008,JPO&INPIT

Description

  The present invention relates to an electronic device that can supply power for operation to an external electronic device connected by a line.

  In a transmission system for transmitting satellite broadcasting and other services (CATV, UHF, VHF, etc.), a satellite broadcasting receiving antenna, UHF antenna, and VHF antenna are provided, and the received signals received at these antennas are mixed. Has been transmitted. In this case, a DC power supply for operating the converter is supplied to the satellite broadcast receiving antenna, but this DC power supply is supplied from a coaxial cable through which a high-frequency signal output from the satellite broadcast receiving antenna is propagated. Yes. That is, an electronic device such as a booster or a tuner to which a high-frequency signal output from the satellite broadcast receiving antenna is supplied supplies operating power to the external satellite broadcast receiving antenna.

  FIG. 5 shows the configuration of a conventional booster 111 that can supply power for operation to an external satellite broadcast receiving antenna. The booster 111 shown in FIG. 5 includes an RF amplifying unit 120. The RF amplifying unit 120 amplifies the IF signal input from the input terminal 123a and outputs the amplified IF signal from the output terminal 123b. The IF signal is an IF signal for satellite broadcasting supplied from a parabolic antenna converter connected to the input terminal 123a via a cable. The RF amplifying unit 120 is supplied with a DC power supply for operation from a built-in switching power supply (SW power supply) 121. The SW power supply 121 converts commercial alternating current supplied from the power plug 111 a into direct current power, and the direct current power output from the SW power supply 121 is also supplied to the DC power transmission circuit 122. The DC power transmission circuit 122 outputs a DC power supplied from the SW power supply 121 as a DC output from the input terminal 123a. A parabolic antenna is connected to the input terminal 123a via a coaxial cable, and the DC output output from the input terminal 123a is supplied to the converter of the parabolic antenna as a power source for operation.

  As described above, the booster 111 includes the SW power supply 121, and is provided with an overcurrent protection circuit 121a for protecting the SW power supply 121 when an overcurrent flows from the SW power supply 121 due to a transmission line accident or the like. . The overcurrent protection circuit 121a protects the SW power supply 121 by setting the power supplied from the SW power supply 121 to a constant power at the time of abnormality. In this case, when an accident such as a short circuit occurs in a coaxial cable or a coaxial plug with a satellite dish receiving parabola antenna and an overcurrent flows through the transmission line, the overcurrent protection circuit 121a in the SW power supply 121 is Come to work. However, even if the overcurrent protection circuit 121a is operated, constant power is continuously supplied from the SW power supply 121, so that there is a possibility that an abnormal current continues to flow through the short-circuited portion and the short-circuited portion may be damaged. It was. Further, since constant power is continuously supplied from the SW power supply 121, the RF amplifier 120 operates but does not operate as rated.

  SUMMARY OF THE INVENTION An object of the present invention is to provide an electronic device in which services other than the supply of power to an external electronic device do not stop even if there is an abnormality in a line that supplies power to the external electronic device.

  In order to achieve the above object, an electronic device of the present invention is a power transmission circuit capable of supplying power output from a power supply unit that supplies power for operation to a circuit unit to an external electronic device via a line. And the power transmission circuit has an overcurrent protection circuit that suppresses an overcurrent when an overcurrent flows due to an abnormality in the line.

  The present invention includes a power transmission circuit capable of supplying power to an external electronic device via a line to supply power output from a power source that supplies power for operation to the circuit part. Because it has an overcurrent protection circuit that suppresses overcurrent when overcurrent flows, even if there is an abnormality in the line that supplies power to external electronic devices, the circuit from the power supply unit It is possible to supply sufficient power for the unit to operate as rated.

FIG. 1 is a block diagram showing a configuration of a receiving system to which an electronic device according to the present invention is applied.
A receiving system 1 shown in FIG. 1 is a receiving system that receives satellite broadcasting in a transmission system that transmits satellite broadcasting and other services (CATV, UHF, VHF, etc.). The reception system 1 includes a parabolic antenna 10 for satellite broadcast reception, and a satellite broadcast reception signal received by the parabolic antenna 10 is converted into an intermediate frequency signal (IF signal) by a converter 10a and output. The IF signal is a high frequency signal of 1200 MHz band for BS broadcasting and 1800 MHz band for CS broadcasting. A first booster 11 and a second booster 12 are cascade-connected to the parabolic antenna 10, and an IF signal output from the parabolic antenna 10 is amplified and transmitted by the cascaded first booster 11 and the second booster 12. It will be done.

In this case, the first booster 11 and the second booster 12 are an embodiment of the electronic apparatus according to the present invention, and the first booster 11 includes a power supply unit that supplies power to the built-in RF amplification unit. A part of the power output from the power supply unit is supplied to the converter 10a of the parabolic antenna 10 as an operating DC power supply (DC). In this case, the parabolic antenna 10 and the first booster 11 are connected via a coaxial cable, and the DC power output from the coaxial plug that is the input terminal of the first booster 11 is converted to the converter 10a via the coaxial cable. Is supplied as a power source for operation.
The second booster 12 also includes a power supply unit that supplies power to the built-in RF amplifying unit. However, in the receiving system 1 shown in FIG. There is no need to supply the equipment. Therefore, the second booster 12 is switched so that power is not output from the second booster 12 by the built-in switching means.

FIG. 2 is a block diagram showing the configuration of the first booster 11 which is an embodiment of the electronic apparatus according to the present invention. The first booster 11 and the second booster 12 have the same configuration.
The first booster 11 has a built-in RF amplification unit 20, and the RF amplification unit 20 amplifies the IF signal input from the input terminal 23a and outputs it from the output terminal 23b. The IF signal is a satellite broadcast IF signal supplied from the converter 10 a of the parabolic antenna 10. The RF amplification unit 20 is supplied with a DC power supply for operation from a built-in switching power supply (SW power supply) 21. The SW power supply 21 converts commercial AC supplied from the power plug 11a into a DC power supply, and the SW power supply 21 is provided with an overcurrent protection circuit 21a. The overcurrent protection circuit 21a protects the SW power supply 21 by making the power supplied from the SW power supply 21 constant power in order to protect the SW power supply 21 when an overcurrent flows through the SW power supply 21. . Further, the DC power output from the SW power supply 21 is also supplied to the DC power transmission circuit 22. The DC power transmission circuit 22 outputs the DC power supplied from the SW power supply 21 as a DC output from the input terminal 23a. The parabolic antenna 10 is connected to the input terminal 23a via a coaxial cable, and the DC output supplied to the input terminal 23a is supplied to the converter 10a of the parabolic antenna 10 as an operating power source.

  The DC power transmission circuit 22 includes an overcurrent protection circuit 22a, a changeover switch 22b, and a display circuit 22c. The overcurrent protection circuit 22a is a circuit that detects an overcurrent that flows when a fault such as a short circuit occurs in the path of the DC output that is output from the DC power transmission circuit 22, and suppresses the overcurrent. The changeover switch 22b is a switch that can switch supply / stop of DC output from the DC power transmission circuit 22. The display circuit 22c is a display circuit that displays the switching state of the changeover switch 22b. Here, if a short circuit accident occurs on the path including the input terminal 23a of the first booster 11 to the parabolic antenna 10, an overcurrent flows through the overcurrent protection circuit 22a and the equivalent resistance of the overcurrent protection circuit 22a increases. Therefore, overcurrent is suppressed. Since a fault such as a short circuit has occurred in the DC output path, the output voltage of the current protection circuit 22a becomes almost zero. Thereby, the abnormal current flowing through the short-circuited portion becomes a limited current value, and the short-circuited portion can be prevented from being damaged.

  In the SW power supply 21, when the above-described short circuit accident occurs, the overcurrent protection circuit 21a temporarily operates. However, the overcurrent protection circuit 22a also instantaneously starts the protection operation and performs DC output. The value of the current that flows through is limited. As a result, the overcurrent protection circuit 21a of the SW power supply 21 returns to the normal operation from the protection operation, and sufficient power is supplied from the SW power supply 21 so that the RF amplification unit 20 operates normally. Become.

Next, an example of a circuit diagram showing the configuration of the DC power transmission circuit 22 is shown in FIG.
In the DC power transmission circuit 22 shown in FIG. 3, a power source output from the SW power source 21 is input to the DC input side, and a DC output is output from the DC output side. The switch SW1 corresponds to the changeover switch 22b. When the movable contacts a1 and a2 are switched to the fixed contacts c1 and c2 as shown in the figure, no DC output is output from the DC output side, and external electronic The DC output is not supplied to the device. Further, when the movable contacts a1 and a2 are switched to the fixed contacts b1 and b2, a DC output is output from the DC output side, and a DC output can be supplied to an external electronic device. The positive temperature coefficient thermistor PR corresponds to the overcurrent protection circuit 22a, and when the overcurrent flows to the DC output side due to a short circuit accident or the like, the positive temperature coefficient thermistor PR self-heats due to the overcurrent flowing through the positive temperature coefficient thermistor PR and the equivalent resistance value increases. become. Thereby, even if the voltage of the power supply output from the SW power supply 21 is applied between both ends of the positive characteristic thermistor PR, the current value of the overcurrent flowing is limited, and the RF amplification unit 20 is normally operated from the SW power supply 21. Sufficient electric power can continue to be supplied to operate. Further, the series circuit of the resistor R1 connected between the positive temperature coefficient thermistor PR and the movable contact a1 and between the ground and the light emitting diode LED1 corresponds to the display circuit 22c, and is connected to the DC power transmission circuit 22 from the SW power source 21. Lights when power is supplied, indicating that power is supplied from the SW power supply 21. Further, when a short circuit accident or the like occurs on the DC output side when the switch SW1 is switched to the fixed contacts b1 and b2 side, the potential on the switch SW1 side of the positive temperature coefficient thermistor PR becomes almost zero. Turns off and indicates that there was an accident.

Next, another example of a circuit diagram showing the configuration of the DC power transmission circuit 22 is shown in FIG.
In another DC power transmission circuit 22 ′ shown in FIG. 4, a power source output from the SW power source 21 is input to the DC input side, and a DC output is output from the DC output side. The switch SW2 corresponds to the changeover switch 22b. When the movable contacts a1 and a2 are switched to the fixed contacts c1 and c2 as shown in the figure, no DC output is output from the DC output side. When the movable contacts a1 and a2 are switched to the fixed contacts b1 and b2, a DC output is output from the DC output side. The positive temperature coefficient thermistor PR corresponds to the overcurrent protection circuit 22a, and when an overcurrent flows to the DC output side due to a short circuit accident or the like, the positive temperature coefficient thermistor PR self-heats due to the overcurrent flowing through the positive temperature coefficient thermistor PR and the equivalent resistance value increases. become. Thereby, even if the voltage of the power supply output from the SW power supply 21 is applied between both ends of the positive characteristic thermistor PR, the current value of the overcurrent flowing is limited, and the RF amplifier 20 is normally operated from the SW power supply 21 Sufficient electric power can continue to be supplied to operate.

  Further, the series circuit of the resistor R2 and the light emitting diode LED2 connected between the positive temperature coefficient thermistor PR and the movable contact a1 and between the earths constitutes a part of the display circuit 22c, and is connected to the DC power transmission circuit 22 ′. When the power is supplied from the SW power source 21, the light emitting diode LED2 is turned on to indicate that the power is supplied from the SW power source 21. The series circuit of the resistor R3 and the light emitting diode LED3 connected between the fixed contact b2 and the ground also constitutes the display circuit 22c. In this case, the movable contact a2 is connected to a terminal on the DC input side. When the switch SW2 is switched to the fixed contacts c1 and c2 side to output a DC output from the DC output side, the movable contact a2—the fixed contact b2 Power is supplied to the light-emitting diode LED3 through the LED and the light-emitting diode LED3 is turned on. Thus, when the switch SW2 is switched to the fixed contacts c1 and c2 side, only the light emitting diode LED2 is lit, and when the switch SW2 is switched to the fixed contacts b1 and b2 side, the light emitting diode LED2 and the light emitting diode LED3 are switched on. Both come on. When the switch SW2 is switched to the fixed contacts b1 and b2 side, when a short circuit accident or the like occurs on the DC output side, the light emitting diode LED2 is turned off because the potential on the DC output side is almost zero. The light emitting diode LED3 continues to be lit, indicating that there was an accident. It is preferable that the light emission color of the light emitting diode LED2 is green and the light emission color of the light emitting diode LED3 is red. If these light-emitting diodes LED2 and LED3 are two-color light-emitting diodes, when SW2 is switched to the fixed contacts c1 and c2, the two-color light-emitting diodes are lit in green, and SW2 is fixed to the fixed contacts b1. When switching to b2, the two-color light emitting diode is lit in orange, and if an accident occurs at this time, the two-color light emitting diode is lit in red, and each state can be displayed in the lighting color. .

  In the above description, the electronic device of the present invention is a booster. However, the present invention is not limited to this, and a satellite broadcast receiving tuner capable of supplying power to the satellite broadcast receiving antenna, or a television receiver incorporating this tuner. Can be a container. Thus, the present invention can be applied to a general electronic device that can supply power to an external electronic device connected by a track. Further, the switch is not limited to a mechanical switch, and may be an electronic switch, and other light emitting display elements may be used instead of the light emitting diodes.

It is a block diagram which shows the structure of the receiving system with which the electronic device concerning this invention is applied. It is a block diagram which shows the structure of the 1st booster which is the Example of the electronic device concerning this invention. It is an example of the circuit diagram which shows the structure of the DC power transmission circuit in the 1st booster which is an Example of the electronic device concerning this invention. It is another example of the circuit diagram which shows the structure of the DC power transmission circuit in the 1st booster which is an Example of the electronic device concerning this invention. It is a block diagram which shows the structure of the conventional booster which can supply a power supply to a satellite broadcast receiving antenna.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Reception system, 10 Parabolic antenna, 10a converter, 11 1st booster, 11a Power plug, 12 2nd booster, 20 Amplification part, 21 SW power supply, 21a Overcurrent protection circuit, 22 DC power transmission circuit, 22a Overcurrent protection circuit, 22b changeover switch, 22c display circuit, 23a input terminal, 23b output terminal, 111 booster, 111a power plug, 120 amplifier, 121 SW power supply, 121a overcurrent protection circuit, 122 DC power transmission circuit, 123a input terminal, 123b output terminal

Claims (3)

A circuit unit for processing a signal supplied from an external electronic device via a line;
A power supply section for supplying power for operation to the circuit section;
A power transmission circuit capable of supplying power output from the power supply unit to the external electronic device via the line, and
The electronic device according to claim 1, wherein the power transmission circuit includes an overcurrent protection circuit that operates to suppress overcurrent when an overcurrent flows due to an abnormality in the line. The power transmission circuit is provided with a selector switch for switching whether to supply power to an upstream electronic device, and a display means for displaying a switching state of the selector switch,
2. The electronic apparatus according to claim 1, wherein the display means can display that the overcurrent protection circuit has been operated. 3. The electronic apparatus according to claim 1, wherein the power supply unit includes a power supply protection circuit that operates to supply constant power when an overcurrent flows.

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