JP6050658B2 - Power supply device and SDI signal transmission system having the same - Google Patents

Description

  The present invention relates to a power supply apparatus having an overcurrent protection function and an SDI (Serial Digital Interface) signal transmission system including the power supply apparatus.

  In general, various protection functions (for example, an overcurrent protection function, an overvoltage protection function, an overheat protection function, etc.) are added to a power supply device or an electronic device.

  For example, Patent Document 1 discloses a small overcurrent protection circuit that can be applied to various electronic devices such as communication devices and measurement devices, has good responsiveness, and has low power consumption.

JP 2008-67489 A (paragraphs 0039 and 0040)

  However, the overcurrent protection circuit disclosed in Patent Document 1 automatically returns to the original state after overcurrent protection is applied. Therefore, if the abnormality is not resolved at the time of recovery, overcurrent flows again, and overcurrent protection is applied again. That is, in the overcurrent protection circuit disclosed in Patent Document 1, an overcurrent may repeatedly flow even after the overcurrent protection is once applied, which may cause excessive damage to the power supply device or the load.

  In view of the above situation, an object of the present invention is to provide a power supply device that can prevent unintentional recovery after overcurrent protection is applied and an SDI signal transmission system including the power supply device.

In order to achieve the above object, a power supply device according to the present invention includes a power supply line, current detection means for detecting a current flowing through the power supply line, and generating a current detection signal according to the value of the detected current, and latch means for latching said current detection signal, and an energizing switch means for turning on / off the energization of the power supply line in response to an output signal of said latch means, said latch means latches the current detection signal The power switch means is configured to turn off the power supply line (first configuration) while the power is being supplied.

  According to such a configuration, after the overcurrent protection by the energization switch means is applied, if the latch means is not turned off or the latch means is not reset, the energization switch means Since the overcurrent protection by continues, it is possible to prevent unintentional recovery after the overcurrent protection is applied.

  Further, in the power supply device having the first configuration, the PTC element provided on the power supply line, a power supply IC that outputs power of a predetermined voltage value to the power supply line, and provided on an input side of the power supply IC. It is desirable that the power supply IC has an overcurrent protection function (second configuration).

  According to such a configuration, since overcurrent protection is applied in multiple layers, even if a failure occurs in any of the overcurrent protections, the overcurrent protection is executed by normal overcurrent protection. Increases nature.

  In the power supply device of the second configuration, overcurrent protection by the energization switch means includes overcurrent protection by the PTC element, overcurrent protection by an overcurrent protection function of the power supply IC, and overcurrent protection by the fuse. It is desirable to adopt a configuration (third configuration) that protects with a smaller current.

  According to such a configuration, since overcurrent protection is always applied by the energization switch means when an overcurrent occurs unless a failure has occurred in the current detection means, the latch means, and the energization switch means, It is possible to reliably prevent unintentional recovery after overcurrent protection is applied.

  In the power supply device having any one of the first to third configurations, it is desirable to have a configuration (fourth configuration) including a notification unit that notifies the output state of the latch unit.

  According to such a configuration, the user can easily grasp whether or not the overcurrent protection is applied by the energization switch means.

  The power supply device having any one of the first to fourth configurations includes a high-frequency signal transmission line for transmitting a high-frequency signal, and the power carried by the power supply line is superimposed on the high-frequency signal transmission line and externally provided. It is desirable to use a configuration (fifth configuration) to be supplied to

  According to such a configuration, high-frequency signal transmission and power transfer can be performed with one cable, and the number of cables is reduced, so that convenience is enhanced.

  In order to achieve the above object, an SDI signal transmission system according to the present invention comprises a power supply device of the fifth configuration and an SDI device that outputs an SDI signal, and a high frequency signal transmission line provided in the power supply device. Is configured to transmit an SDI signal (sixth configuration).

  According to such a configuration, the high-frequency signal transmitted through the high-frequency signal transmission line can be a high-quality video signal.

  According to the present invention, it is possible to realize a power supply apparatus that can prevent unintentional recovery after overcurrent protection is applied, and an SDI signal transmission system including the power supply apparatus.

It is a figure which shows the structure of the SDI signal transmission system which concerns on one Embodiment of this invention. It is a figure which shows one structural example of a power supply separator. It is a figure which shows the example of 1 structure of a power supply insertion part. It is a figure which shows the structure of the SDI signal transmission system which concerns on other embodiment of this invention. It is a figure which shows the electric current which flows through an electric power supply line.

  Embodiments of the present invention will be described below with reference to the drawings. FIG. 1 is a diagram showing a configuration of an SDI signal transmission system according to an embodiment of the present invention. An SDI signal transmission system according to an embodiment of the present invention includes an imaging device 1, a power separator 2, an SDI repeater 3, a camera drive unit 4, a signal cable 5, coaxial cables 6 and 7, and a power cable. 8 and. In the present embodiment, each of the imaging device 1 and the SDI relay 3 corresponds to the SDI device described in the claims, and the camera drive unit 4 corresponds to the power supply device described in the claims.

  The imaging device 1 converts an imaging signal acquired by imaging into an SDI signal (SD-SDI signal or HD-SDI signal) and outputs it. The SDI signal output from the imaging device 1 is transmitted to the SDI repeater 3 via the signal cable 5, the power supply separator 2, and the coaxial cable 6.

  The power separator 2 separates the DC 24V DC power superimposed on the coaxial cable 6 from the SDI signal transmission line and supplies it to the imaging device 1 via the power cable 8. The imaging device 1 uses the DC power supplied from the power separator 2 as a power source. As the configuration of the power separator 2, for example, as shown in FIG. 2, the power output terminal 21 to which the power cable 8 is connected, the SDI input terminal 22 to which the signal cable 5 is connected, and the coaxial cable 6 are connected. The SDI output terminal 23, the DC blocking capacitor 24 disposed between the SDI input terminal 22 and the SDI output terminal 23, and the connection point 25 between the SDI output terminal 23 and the DC blocking capacitor 24 and the power output terminal 21 are disposed. And a high frequency grounding capacitor 28 disposed between a connection point 27 between the power output terminal 21 and the high frequency blocking coil 26 and the ground potential.

  The SDI repeater 3 is a device for enabling long-distance transmission of an SDI signal. The SDI repeater 3 corrects the SDI signal received from the coaxial cable 6 and outputs the corrected SDI signal to the coaxial cable 7. Compensates for signal attenuation and distortion. The SDI repeater 3 carries the DC power superimposed on the coaxial cable 7 and superimposes it on the coaxial cable 6.

  The camera drive unit 4 converts the SDI signal sent from the SDI repeater 3 via the coaxial cable 7 into an HDMI (High Definition Multimedia Interface) signal and outputs it to the outside, and from a commercial AC power source (not shown). The received AC power of 100 V AC is converted into DC power of 24 V DC, and the converted DC power of 24 V is superimposed on the SDI signal transmission line, whereby the DC power of 24 V DC is superimposed on the coaxial cable 7.

  The camera drive unit 4 includes a power supply insertion portion 9, a signal conversion portion 10, a fuse 11, an AC / DC converter 12 with an overcurrent protection function, a current detection resistor 13, and a polymer-based PTC (Positive Temperature Coefficient) element. Polyswitch (registered trademark) 14, relay switch 15, differential amplifier 16, set-reset flip-flop 17, relay coil 18, green LED 19 that emits green light when lit, and red light when lit And a red LED 20.

  In the present embodiment, the AC / DC converter 12 with an overcurrent protection function corresponds to the power supply IC described in the claims, and a circuit constituted by the current detection resistor 13 and the differential amplifier 16 is claimed. The polyswitch (registered trademark) 14 corresponds to the PTC element described in the claims, and the relay configured by the relay switch 15 and the relay coil 18 is described in the claims. The set / reset flip-flop 17 corresponds to the latch means described in the claims, and the green LED 19 and the red LED 20 correspond to the notification means described in the claims.

  In the present embodiment, the SDI signal transmission line from the coaxial cable connector to which the coaxial cable 7 is connected to the HDMI cable connector from which the HDMI signal is output via the power supply insertion unit 9 and the signal conversion unit 10 is provided. It corresponds to the high-frequency signal transmission line described in the claims, from the power input terminal to which AC power of AC 100V is input, fuse 11, AC / DC converter 12 with overcurrent protection function, current detection resistor 13, polyswitch ( The power supply line from the registered trademark 14 and the relay switch 15 to the connection point 93 (see FIG. 3) in the power supply insertion portion 9 corresponds to the power supply line recited in the claims.

  The power supply insertion unit 9 outputs the SDI signal received from the coaxial cable 7 to the signal conversion unit 10. Further, the power supply insertion section 9 superimposes the DC 24V DC power on the coaxial cable 7 by superimposing the DC 24V DC power output from the AC / DC converter 12 with the overcurrent protection function on the SDI signal transmission line. For example, as shown in FIG. 3, the power supply insertion portion 9 has a coaxial cable connection terminal 91 to which the coaxial cable 7 is connected, a DC blocking capacitor 92 having one end connected to the coaxial cable connection terminal 91, A high frequency blocking coil 94 having one end connected to a connection point 93 between the cable connection terminal 91 and the DC blocking capacitor 92, and a high frequency grounding capacitor 95 disposed between the other end of the high frequency blocking coil 94 and the ground potential. The structure provided with can be mentioned. In this configuration, an SDI signal is output from the other end of the DC blocking capacitor 92, and DC power of 24 V DC is supplied to a connection point 96 between the high frequency blocking coil 94 and the high frequency grounding capacitor 95.

  The signal conversion unit 10 converts the SDI signal output from the power supply insertion unit 9 into an HDMI signal. For example, when the high-frequency device that receives and processes the high-frequency signal output from the camera drive unit 4 has a SDI signal input interface and can process the SDI signal, the signal conversion unit 10 is removed from the camera drive unit 4. It is also possible.

  The fuse 11, the AC / DC converter 12 with an overcurrent protection function, the current detection resistor 13, the polyswitch (registered trademark) 14, and the relay switch 15 are all provided on the power supply line, and the fuse 11 has an overcurrent protection function. The current detection resistor 13, the polyswitch (registered trademark) 14, and the relay switch 15 are disposed on the output side of the AC / DC converter 12 with an overcurrent protection function.

  The AC / DC converter 12 with an overcurrent protection function converts AC 100 V AC power received from a commercial AC power supply (not shown) into DC 24 V DC power. In addition, the AC / DC converter 12 with an overcurrent protection function converts AC100V AC power received from a commercial AC power supply (not shown) into DC5V DC power, and the DC5V DC power is set / reset flip-flop 17. To supply. The set / reset flip-flop 17 uses DC power of DC 5V as a power source. As the AC / DC converter 12 with an overcurrent protection function, for example, a commercially available general-purpose power supply IC can be used. The configuration of the internal circuit that realizes the overcurrent protection function of the AC / DC converter 12 with an overcurrent protection function is not particularly limited. For example, the current that detects the input current or the output current of the AC / DC converter 12 with the overcurrent protection function An internal circuit that includes a detection circuit and a semiconductor switch that is on / off controlled according to a current detection signal output from the current detection circuit can be given.

  The differential amplifier 16 outputs a signal (current detection signal) obtained by amplifying the potential difference between both ends of the current detection resistor 13 to the set terminal of the set / reset flip-flop 17. One end of the relay coil 18 and the anode of the green LED 19 are connected to the inverting Q output terminal of the set / reset flip-flop 17, and the anode of the red LED 20 is connected to the Q output terminal of the set / reset flip-flop 17. The other end of the relay coil 18, the cathode of the green LED 19, and the cathode of the red LED 20 are connected to the ground potential.

  According to such a configuration, when an overcurrent flows through the current detection resistor 13 and the current detection signal becomes a high level signal, the set / reset flip-flop 17 is set, and no current flows through the relay coil 18 so that the relay switch 15 is turned on. The power supply line is turned off. That is, overcurrent protection by a relay is applied. Once an overcurrent flows through the current detection resistor 13 and the current detection signal becomes a high level signal, the set / reset flip-flop 17 must be turned off or the set / reset flip-flop 17 must be reset. After that, even if the current detection signal changes to a low level signal, the output state of the set / reset flip-flop 17 does not change, so the relay switch 15 continues to be off, and the overcurrent protection by the relay continues. Therefore, it is possible to prevent unintentional recovery after overcurrent protection is applied.

  In the present embodiment, the supply of AC power of 100 V AC to the camera drive 4 is stopped, so that the overcurrent protection by the relay is restored to the original state. The camera drive 4 is provided with a circuit capable of switching supply / non-supply of the reset signal to the reset terminal of the set-reset flip-flop 17 so that the set-reset flip-flop 17 can be reset. You may make it return to the original state from the overcurrent protection by a relay by resetting 17.

  In addition, since the current continues to flow through the red LED 20 during the period when the overcurrent protection by the relay is applied, the red LED 20 continues to be lit red. On the other hand, since the current continues to flow through the green LED 19 during the period when the overcurrent protection by the relay is not applied, the green LED 19 continues to be lit in green. Thereby, the user can easily grasp whether or not the overcurrent protection by the relay is applied by the lighting color of the LED. Instead of notifying whether or not the overcurrent protection by the relay is applied by display, for example, an electronic buzzer or the like may be provided in place of the red LED 20 to notify by a method other than display.

  In the present embodiment, the overcurrent protection by the relay is the overcurrent protection by the polyswitch (registered trademark) 14 or the AC / DC with an overcurrent protection function by setting the circuit constant of each element related to the overcurrent protection. The protection is applied with a smaller current than the overcurrent protection by the overcurrent protection function of the converter 12 and the overcurrent protection by the fuse 11. As a result, unless an overcurrent occurs, the current detection resistor 13, the differential amplifier 16, the set-reset flip-flop 17, the relay coil 18, and the relay switch 15 are always protected by an overcurrent protection by a relay. Therefore, it is possible to reliably prevent unintentional recovery after overcurrent protection is applied.

The overcurrent protection by overcurrent protection PolySwitch (TM) 14 due to overcurrent protection and over-current protection function AC / DC converter 12, which may be adapted such that protection with a smaller current. When overcurrent protection by the fuse 11 is applied, the fuse 11 needs to be replaced. Therefore, overcurrent protection by the fuse 11 includes overcurrent protection by a relay, overcurrent protection by a polyswitch (registered trademark) 14, and overcurrent protection. It is desirable that protection be applied with a larger current than the overcurrent protection by the overcurrent protection function of the AC / DC converter 12 with function.

  In the above-described embodiment, the imaging device 1 and the power supply separator 2 are separate devices. However, they may be integrated into one device (DC power superposition compatible imaging device). When integrating into one device (DC power superimposition compatible imaging device), for example, the power output terminal 21 (see FIG. 2), the power cable 8 (see FIG. 1), and the power input terminal of the imaging device 1 (not shown). Is replaced with printed wiring on the printed wiring board, and the SDI output terminal (not shown), the signal cable 5 (see FIG. 1), and the SDI input terminal 22 (see FIG. 2) of the imaging device 1 are printed on the printed wiring board. Is replaced.

  In the above-described embodiment, the SDI signal transmission system includes the SDI repeater 3. However, when the signal transmission distance is short, the power supply separator 2 and the camera drive unit 4 are not provided without providing the SDI repeater. May be connected by a single coaxial cable.

  In addition, the DC power of 24V DC, the DC power of 5V DC, and the AC power of AC 100V used in the above-described embodiment are merely examples, and power of other voltage values may be used. An AC / DC converter that does not have an overcurrent protection function may be used instead of the AC / DC converter 12 with an overcurrent protection function. In addition, a DC / DC converter may be used instead of the AC / DC converter, and an inverter that converts DC power into AC power may be used instead of the AC / DC converter as long as it conforms to the specifications of the imaging device 1. Good.

Further, in the above embodiment, although the power supply device according to the present invention is carried out by applying to the camera drive unit is not limited thereto, a power supply device according to the present invention, the connectable capacity of electronic devices in high frequency devices The present invention can be applied to all electronic devices including a power supply device.

  The camera drive unit 4 used in the above-described embodiment has the fuse 11, the AC / DC converter 12 with an overcurrent protection function, the current detection from the power input terminal to which AC power of AC 100V is input even if the imaging device 1 has an abnormality. There is a large change in the value of the current flowing through the power supply line up to the connection point 93 (see FIG. 3) in the power supply insertion section 9 via the resistor 13, the polyswitch (registered trademark) 14, and the relay switch 15. If not, the DC power of 24V DC conveyed by the power supply line cannot be stopped from being superimposed on the SDI signal transmission line and supplied to the imaging device 1.

  SDI signal transmission system that can solve this problem, that is, even if there is an abnormality in the imaging device but there is no significant change in the value of the current flowing through the power supply line for superposition, the power for superposition FIG. 4 shows an example of an SDI signal transmission system capable of stopping the supply of power carried by the supply line to the imaging device while being superimposed on the SDI signal transmission line. 4 that are the same as those in FIG. 1 are denoted by the same reference numerals, and detailed description thereof is omitted. Also, in FIG. 4, the imaging device provided on the input side of the camera drive unit is basically the same as in FIG.

  The camera drive unit 4 ′ is a camera drive unit capable of processing SDI signals for 4 channels, and includes a ch1 front end portion F1, a ch2 front end portion F2, a ch3 front end portion F3, and a ch4 front end portion F4. Prepare.

  The ch1 front end unit F1 includes a power supply insertion unit 9A, a signal detection unit 30A, a current detection resistor 13A, a polyswitch (registered trademark) 14A, a relay switch 15A, a differential amplifier 16A, a relay coil 18A, and a buffer amplifier 31A. . Since the ch2 to ch4 front end portions F2 to F4 have the same circuit configuration as that of the ch1 front end portion F1, only the ch1 front end portion F1 will be described here.

  The signal detection unit 30A distributes the SDI signal supplied from the power supply insertion unit 9A into two, one being output as the ch1SDI signal to the outside of the camera drive unit 4 'and the other being output to the signal conversion unit 10'. The signal conversion unit 10 ′ converts the SDI signal into an HDMI signal in the same manner as the signal conversion unit 10 of the camera drive unit 4 shown in FIG. 1. However, unlike the signal conversion unit 10, the signal conversion unit 10 ′ can process 4 channels. Therefore, ch1 to ch4 HDMI signals are output from the signal conversion unit 10 '. Four output images based on the ch1 to ch4 HDMI signals can be simultaneously displayed on a display screen divided into four, for example.

  The camera drive unit 4 ′ includes a microcomputer 29. In the present embodiment, the AC / DC converter 12 ′ with an overcurrent protection function supplies DC power of DC 5 V to the microcomputer 29. The AC / DC converter 12 ′ with overcurrent protection function performs AC / DC conversion in the same manner as the AC / DC converter 12 with overcurrent protection function of the camera drive unit 4 shown in FIG. Unlike the converter 12, AC / DC conversion for 4 channels is performed.

  The microcomputer 29 has a function as a latch circuit for ch1 to ch4. For example, when an overcurrent flows through the current detection resistor 13A and the current detection signal (the output signal of the differential amplifier 16A) becomes a high level signal, the ch1 latch circuit is set and no current flows through the relay coil 18A. The relay switch 15A is turned off, and the power supply line for ch1 is turned off. That is, overcurrent protection by a relay is applied. Once an overcurrent flows through the current detection resistor 13A and the current detection signal becomes a high level signal, the microcomputer 29 is turned off or the ch1 latch circuit is not reset. Even if the current detection signal changes to a low level signal, the output state of the ch1 latch circuit does not change, so the relay switch 15A continues to be turned off and the overcurrent protection by the relay continues.

  Further, the microcomputer 29 continues to supply current to the red LED 20A during a period in which the ch1 latch circuit holds the output state at the time of setting, that is, a period in which overcurrent protection is performed by the ch1 relay. Therefore, red lighting by the red LED 20A continues during a period in which overcurrent protection by the ch1 relay is applied. On the other hand, the microcomputer 29 continues to supply current to the green LED 19A during a period in which the ch1 latch circuit does not hold the output state at the time of setting, that is, a period in which the overcurrent protection by the ch1 relay is not applied. . Accordingly, green lighting by the green LED 19A continues during a period in which overcurrent protection by the ch1 relay is not applied. Thus, the user can easily grasp whether or not the overcurrent protection by the relay for ch1 is applied based on the lighting color of the LED. However, as will be described later, even if the overcurrent protection by the ch1 relay is not applied, it is provided in the ch1 front end F1 after a certain time has elapsed since the relay switch 15A was turned on. When the normal signal cannot be acquired from the signal detection output terminal of the signal detection unit 30A, the red LED 20A as well as the green LED 19A is lit. Here, ch1 has been described as an example, but the same applies to ch2 to ch4. Therefore, the microcomputer 29 includes a green LED 19B and red LED 20B for ch2, a green LED 19C and red LED 20C for ch3, and a green LED for ch4. An LED 19D and a red LED 20D are also connected.

  The signal detection unit 30A provided in the ch1 front end unit F1 has a function of determining whether or not an SDI signal can be input. When the SDI signal can be input, the signal detection output terminal 30A A normal signal is output. The microcomputer 29 acquires a signal output from the signal detection output terminal of the signal detection unit 30A provided in the ch1 front end unit F1, and is similarly provided in the ch2 to ch4 front end units F2 to F4. Each signal output from each signal detection output terminal of each signal detection unit is acquired.

  If the microcomputer 29 cannot acquire a normal signal from the signal detection output terminal of the signal detection unit 30A provided in the ch1 front end portion F1 after a certain time has elapsed since the relay switch 15A was turned on, the ch1 Therefore, the current is not supplied to the relay coil 18A. Thereby, the relay switch 15A is turned off. When the microcomputer 29 cannot acquire a normal signal from the signal detection output terminal of the signal detection unit 30A provided in the ch1 front end unit F1 after a predetermined time has elapsed since the relay switch 15A was turned on. In addition, if the ch1 latch circuit does not hold the output state at the time of setting, current is supplied to both the green LED 19A and the red LED 20A, and both the green LED 19A and the red LED 20A are lit. The green LED 19A and the red LED 20A are arranged close to each other. For this reason, when both the green LED 19A and the red LED 20A are lit, the user recognizes that the light is orange. This orange lighting indicates an abnormality not involving an overcurrent (including a case where an imaging device is not connected). On the other hand, the microcomputer 29 outputs a normal signal from the signal detection output terminal of the signal detection unit 30A provided in the ch1 front end unit F1 after a predetermined time has elapsed since the relay switch 15A was turned on. If it cannot be obtained and the ch1 latch circuit is in a period in which the output state at the time of setting is maintained, a current is supplied only to the red LED 20A. Here, ch1 has been described as an example, but the same applies to ch2 to ch4.

  Next, AC power of 100 V AC is supplied to the camera drive unit 4 ′, and the camera drive unit 4 ′ is provided with a power switch (for example, between the fuse 11 and the AC / DC converter 12 ′ with overcurrent protection function). The operation when the switch (which can be switched on / off by operation) is switched from off to on will be described with reference to FIGS.

  First, DC power of DC 5V is supplied from the AC / DC converter 12 'with an overcurrent protection function to the microcomputer 29, and the microcomputer 29 enters an operating state (at time t0). Next, the microcomputer 29 instructs the AC / DC converter 12 'with overcurrent protection function to supply DC 24V DC power to the power supply line for ch1, and the AC / DC converter with overcurrent protection function according to the instruction. 12 'supplies DC power of 24V DC to the ch1 power supply line (at time t1).

  Immediately after the DC power of 24V DC is supplied to the ch1 power supply line, an inrush current flows through the ch1 power supply line due to the rise of the ch1 imaging device or the like. Immediately after the DC power of 24V DC is supplied to the ch1 power supply line, the start-up of the ch1 imaging device or the like is not completed, and therefore the SDI signal is not transmitted. Therefore, the microcomputer 29 controls the relay according to the current detection signal for ch1 (the output signal of the differential amplifier 16A) and the signal detection output of the signal detection unit 30A after a predetermined time Tc has elapsed from the time point t1. Relays are controlled according to whether or not a normal signal is acquired from the terminal, and before that, these relays are not controlled, and a current is continuously supplied to the relay coil 18A so as to keep the relay switch 15A in an ON state.

  After the time point t1, more specifically, after the inrush current stops flowing in the power supply line for ch1, the microcomputer 29 supplies the DC / 24V DC to the power supply line for ch2 to the AC / DC converter 12 ′ with an overcurrent protection function. According to the instruction, the AC / DC converter 12 ′ with an overcurrent protection function supplies DC 24V DC power to the ch2 power supply line (at time t2). As in the case of ch1, the microcomputer 29 controls the relay according to the current detection signal for ch2 (the output signal of the differential amplifier for ch2) and the ch2 front after a predetermined time Tc has elapsed from time t2. The relay is controlled according to whether or not the normal signal is acquired from the signal detection output terminal of the signal detection unit provided in the end unit F2, and before that, these relays are not controlled, and the relay switch for ch2 is set. Continue to pass current through the relay coil for ch2 so as to keep it on.

  Since ch3 and ch4 are the same as those of ch1 and ch2, description thereof will be omitted. The maximum output current value of the AC / DC converter 12 'with an overcurrent protection function can be reduced by shifting the timing (t1 time to t4 time) at which DC power of 24V DC starts to be supplied to the power supply line between the channels. it can. Thereby, cost reduction of AC / DC converter 12 'with an overcurrent protection function can be achieved.

  In the above-described embodiment shown in FIG. 4, the configuration of the imaging device or the like provided on the input side of the camera drive unit 4 ′ is not limited to the same case as in FIG. 1. For example, when the signal transmission distance is short, the power supply separator 2 and the camera drive unit 4 'may be connected by a single coaxial cable without providing the SDI repeater.

  Further, the DC power of 24V DC, the DC power of DC 5V, and the AC power of AC 100V used in the embodiment shown in FIG. 4 described above are merely examples, and power of other voltage values may be used. Further, an AC / DC converter having no overcurrent protection function may be used instead of the AC / DC converter 12 'with overcurrent protection function. In addition, a DC / DC converter may be used instead of the AC / DC converter, and an inverter that converts DC power into AC power may be used instead of the AC / DC converter as long as it conforms to the specifications of the imaging device 1. Good.

  Further, the camera drive unit 4 ′ used in the above-described embodiment shown in FIG. 4 is a camera drive unit for 4 channels, but the number of channels is merely an example, and other channel numbers may be used.

  In the embodiment shown in FIG. 4 described above, the power supply apparatus according to the present invention is applied to the camera drive unit. However, the present invention is not limited thereto, and the power supply apparatus according to the present invention can be connected to a high-frequency device. The present invention can be applied to all electronic devices equipped with a power supply device, including various electronic devices.

  In the embodiment shown in FIG. 4 described above, the microcomputer 29 has a function as a latch circuit for ch1 to ch4 in order to prevent unintentional recovery after overcurrent protection is applied. However, if it is not necessary to prevent unintentional recovery after overcurrent protection is applied, the configuration may not be provided.

  That is, even if there is an abnormality in the high-frequency device but there is no significant change in the value of the current flowing through the power supply line for superimposition, the power carried by the power supply line for superimposition is transferred to the high-frequency signal transmission line. The power supply device that can stop the supply to the high-frequency device in a superimposed manner may be at least the following configuration.

Its configuration is
A power supply line;
A high-frequency signal transmission line for transmitting a high-frequency signal;
A power supply device including signal detection means provided on the high-frequency signal transmission line, and supplying the power carried by the power supply line to the outside superimposed on the high-frequency signal transmission line,
Current detection means for detecting a current flowing through the power supply line and generating a current detection signal according to the value of the detected current;
First energization switch means for turning on / off energization of the power supply line in response to an output signal of the current detection means;
Second energization switch means,
The signal detection means has a function of determining whether or not a predetermined high-frequency signal can be input, and when a predetermined high-frequency signal can be input, outputs a normal signal from a signal detection output terminal, The second energization switch means is configured to turn on / off energization of the power supply line according to whether a normal signal is output from the signal detection output terminal.

  The first energization switch means and the second energization switch means are preferably one switch. Thereby, the number of parts can be reduced.

  Also, when overcurrent protection is applied by the first energization switch means, and when a normal signal is output from the signal detection output terminal and overcurrent protection is not applied by the first energization switch means. It is desirable to provide notification means for distinguishing between the case where no normal signal is output from the signal detection output terminal and overcurrent protection by the first energization switch means is not applied. Thereby, the user can grasp | ascertain the condition of a power supply device easily.

  The first energization switch means and the second energization switch means are turned on, and a certain period of time has elapsed since the power carried by the power supply line is superimposed on the high-frequency signal transmission line and started to be supplied to the outside. After the elapse of time, the first energization switch means turns on / off the energization of the power supply line in accordance with the output signal of the current detection means, and the second energization switch means normally operates from the signal detection output terminal. It is desirable to turn on / off the power supply line depending on whether a signal is output. Thereby, it is possible to prevent the power supply line from being cut off due to an inrush current at the start of energization or non-reaching of a high frequency signal to the power supply device at the start of energization.

  Further, the power supply device having any one of the above configurations and the power supply device having any one of the above configurations and an SDI device that outputs an SDI signal are provided, and the high-frequency signal transmission line provided in the power supply device is an SDI signal. It is also possible to construct an SDI signal transmission system that transmits

DESCRIPTION OF SYMBOLS 1 Imaging device 2 Power supply separator 3 SDI repeater 4, 4 'Camera drive unit 5 Signal cable 6, 7 Coaxial cable 8 Power cable 9, 9A Power supply insertion part 10, 10' Signal conversion part 11 Fuse 12, 12 'Overcurrent protection AC / DC converter with function 13, 13A Resistance for current detection 14, 14A Polyswitch (registered trademark)
15, 15A relay switch 16, 16A differential amplifier 17 set reset flip-flop 18, 18A relay coil 19, 19A-19D green LED
20, 20A-20D Red LED
21 Power supply output terminal 22 SDI input terminal 23 SDI output terminal 24, 44 DC blocking capacitor 25, 27, 93, 96 Connection point 26, 94 High frequency blocking coil 28, 95 High frequency grounding capacitor 29 Microcomputer 30A Signal detection unit 31A Buffer amplifier 91 Coaxial cable connection terminal F1 to F4 ch1 to ch4 front end

Claims (5)

A power supply line;
Current detection means for detecting a current flowing through the power supply line and generating a current detection signal according to the value of the detected current;
Latch means for latching the current detection signal;
First energization switch means for turning on / off energization of the power supply line in response to an output signal of the latch means ;
A high-frequency signal transmission line for transmitting a high-frequency signal;
Signal detection means provided on the high-frequency signal transmission line;
Second energization switch means,
A power supply apparatus that superimposes the power carried by the power supply line on the high-frequency signal transmission line and supplies the power to the outside,
While the latch means latches the current detection signal, the first energization switch means turns off the power supply line ,
The signal detection means has a function of determining whether or not a predetermined high-frequency signal can be input, and when a predetermined high-frequency signal can be input, outputs a normal signal from a signal detection output terminal, The power supply apparatus according to claim 2, wherein the second energization switch means turns on / off energization of the power supply line according to whether a normal signal is output from the signal detection output terminal . A PTC element provided on the power supply line;
A power supply IC that outputs power of a predetermined voltage value to the power supply line;
A fuse provided on the input side of the power supply IC,
The power supply device according to claim 1, wherein the power supply IC has an overcurrent protection function. The overcurrent protection by the first energizing switch means is protected with a smaller current than the overcurrent protection by the PTC element, the overcurrent protection by the overcurrent protection function of the power supply IC, and the overcurrent protection by the fuse. Item 3. The power supply device according to Item 2.   The power supply device according to any one of claims 1 to 3, further comprising notification means for notifying an output state of the latch means. The power supply device according to any one of claims 1 to 4,
SDI equipment that outputs SDI signals,
An SDI signal transmission system, wherein a high-frequency signal transmission line provided in the power supply device transmits an SDI signal.

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