JP2010130339A - Electronic apparatus, and device for controlling power of the same - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To easily control the start and stop of power feed to an electronic apparatus through a communication cable. <P>SOLUTION: This electronic apparatus 2 includes a power control part 20 having a detection resistor 231 and receiving power feed from a power feed device 1 through a communication cable 3, wherein the power feed is started by detecting the detection resistor 231 through the communication cable 3 by the power feed device 1, and stopped by carrying a current above a threshold value to the communication cable 3. In the electronic apparatus 2, the power control part 20 includes: a power supply means 230 to supply power by receiving the power feed; a connection control means 220 to electrically connect the communication cable 3 to the detection resistor 231 when receiving an operation for starting the power feed, and keep the electrical connection by the power supplied from the power supply means 230; and a cutoff control means 240 to carry the current above the threshold value to the communication cable 3 by the power supplied from the power supply means 230 based on a predetermined condition. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention relates to an electronic device that receives power supply via a communication cable and a power supply control device thereof, and more particularly to a technique for controlling the start and stop of power supply.

  In recent years, ecology has attracted attention, and power consumption of electronic devices has been reduced.

  For example, in the technique described in Patent Document 1, power is supplied to components other than the normal mode for supplying power to all components, the network interface, the key operation detection unit, and the timer unit for counting a predetermined time. The power saving mode to be stopped is provided in the IP telephone which is an electronic device. Thereby, when the IP telephone is not used, for example, waiting for an incoming call, the power consumption of the IP telephone can be reduced by shifting to the low power consumption mode. Also, when an incoming IP packet is received at the network interface, when a key operation input such as outgoing call is detected by the key operation detection unit, or when a predetermined time measurement is completed by the timer unit, the IP telephone is By returning from the power saving mode to the normal mode, even when the mode is shifted to the power saving mode, the IP telephone can be operated immediately.

In the technique described in Patent Document 2, a sensor unit such as an optical sensor, an infrared sensor, or a temperature sensor is provided in the electronic device, and the power source of the electronic device is automatically selected according to the surroundings of the electronic device sensed by the sensor unit. By performing management, the power consumption of the electronic device can be reduced.
Japanese Patent Laying-Open No. 2005-101921 JP 2005-004522 A

  Recently, there are electronic devices that can receive power supply via a communication cable such as a LAN cable. Note that a power supply method for supplying power to an electronic device via a communication cable is defined by IEEE 802.3af, and is expected to be applied to an electronic device such as an IP telephone, a wireless LAN access point, and a surveillance camera.

  According to IEEE 802.3af, a LAN power supply device that supplies power to an electronic device via a communication cable detects 25 kΩ provided in the electronic device via the communication cable when the electronic device is connected via the communication cable. When resistance is detected, power supply to the electronic device is started. In addition, when the LAN power supply device starts supplying power to the electronic device, the connection with the electronic device via the communication cable is disconnected and the detection resistance cannot be detected, or the communication cable has a current of 500 mA or more. The power supply to the electronic device is continued except when it seems that an abnormality has occurred in the electronic device such as flowing for 1 ms or more. Therefore, normally, an electronic device that receives power supply by the power supply method defined in IEEE 802.3af is always in a state of being activated by receiving power supply from the LAN power supply device.

  However, for example, when considering an IP telephone as an electronic device that receives power supply via a communication cable, an IP telephone placed in a call center, a conference room, or the like is used for a certain period of time. There is no need to power and activate the IP phone. In addition, companies that assign an IP phone to each individual employee need only power up and activate the IP phone only when the employee is at the company. There is no need to keep it. For this reason, for companies using IP telephones with hundreds or thousands of IP telephones, continuing to supply power to the IP telephones via the communication cable during times when the IP telephones are not used is a significant loss of power consumption. Become.

  As a technique described in Patent Document 1, a means for providing a power saving mode to an IP telephone is conceivable. However, in recent years, IP telephones have become more multifunctional, and power consumption in the power saving mode tends to increase. From an ecological point of view, there is a problem in constantly supplying unnecessary power.

  Although a method of disconnecting the communication cable from the IP telephone and cutting off the power supply from the LAN power supply device is also conceivable, it is necessary for the user of the IP telephone to connect and disconnect the communication cable every time. Therefore, there are difficulties in implementation.

  An object of the present invention is to provide an electronic device that can easily control start and stop of power feeding via a communication cable, and a power supply control device thereof.

In order to achieve the above object, the electronic apparatus of the present invention
A power control unit including a detection resistor and receiving power from a power supply device via a communication cable, wherein the power supply is started when the power supply device detects the detection resistance via the communication cable; In an electronic device that is stopped when a current exceeding the threshold flows through the cable,
The power control unit
Power supply means for receiving power and supplying power;
Connection control means for conducting between the communication cable and the detection resistor when receiving an operation for starting the power supply, and maintaining the conduction by power supplied from the power supply means;
And a cutting control means for flowing a current equal to or greater than the threshold to the communication cable by electric power supplied from the power supply means based on a predetermined condition.

In order to achieve the above object, the power supply control device of the present invention provides:
A detection resistor is provided, and is supplied with power from a power supply device via a communication cable, and the power supply is started when the power supply device detects the detection resistance via the communication cable, and a current equal to or greater than a threshold value is supplied to the communication cable. In the power supply control device, which is stopped by flowing
Power supply means for receiving power and supplying power;
Connection control means for conducting between the communication cable and the detection resistor when receiving an operation for starting the power supply, and maintaining the conduction by power supplied from the power supply means;
And a cutting control means for flowing a current equal to or greater than the threshold to the communication cable by electric power supplied from the power supply means based on a predetermined condition.

  As described above, according to the present invention, when the connection control unit accepts an operation for starting power feeding, the connection control unit conducts between the communication cable and the detection resistor and conducts the conduction by the power supplied from the power supply unit. maintain. Therefore, by performing an operation for starting power feeding, the power feeding device can detect the detection resistance via the communication cable, and power feeding from the power feeding device that has detected the detection resistance is started.

  Further, according to the present invention, the disconnection control means causes a current equal to or greater than the threshold to flow through the communication cable by the power supplied from the power supply means based on a predetermined condition. For this reason, when a predetermined condition is satisfied, a current equal to or greater than the threshold value flows in the communication cable, and thus the power feeding device stops power feeding. In addition, since the power supply is stopped, the connection control unit cannot maintain the continuity between the communication cable and the detection resistor, and the detection resistor cannot be detected from the power supply device, so that an operation for starting the power supply is performed again. Until then, the power supply from the power supply apparatus is stopped.

  Therefore, it is possible to easily control the start and stop of power supply to the electronic device via the communication cable.

  The best mode for carrying out the present invention will be described below with reference to the drawings.

  FIG. 1 is a diagram showing a configuration of an embodiment of an electronic apparatus of the present invention.

  As shown in FIG. 1, the electronic device 2 of the present embodiment has a power supply control unit 20 and a control unit 21. Here, only the power supply control unit 21 and the control unit 20 are described as the components of the electronic device 2, but the electronic device 2 also has other components according to its intended use. .

  The power supply control unit 20 includes a communication unit 210, a connection control unit 220, a power supply unit 230, and a disconnection control unit 240. Power is supplied from the LAN power supply device 1 that is a power supply device via the LAN cable 3 that is a communication cable. The power is supplied to the other components of the electronic device 2 such as the control unit 21. Note that the LAN power supply device 1 has a PSE (Power Source Equipment Equipment) circuit 11, and the PSE circuit 11 is connected to the power supply control unit 20 via the LAN cable 3 based on a power supply method defined by IEEE 802.3af. Supply power. Specifically, when the PSE circuit 11 detects a 25 kΩ detection resistor 231 provided in the power supply unit 230 connected to the LAN cable 3 via the communication unit 210, the PSE circuit 11 starts to supply power to the electronic device 2. Further, the PSE circuit 11 stops the power supply to the power supply control unit 20 when a current of 500 mA or more which is a threshold value flows through the LAN cable 3 for 1 ms or more.

  The communication unit 210 is connected to the PSE circuit 11 of the LAN power supply device 1 via the LAN cable 3.

  The power supply unit 230 includes a detection resistor 231, is connected to the LAN cable 3 via the communication unit 210, and supplies power to the other components of the electronic device 2 such as the control unit 21 by power supply from the PSE circuit 11. To do.

  The connection control unit 220 includes a switch 221 that receives an operation for starting power supply, and is connected to the LAN cable 3 in series with the power supply unit 230 via the communication unit 210. When the operation for starting power feeding is received by the switch 221, the connection control unit 220 makes the LAN cable 3 and the detection resistor 231 provided in the power supply unit 230 conductive. As a result, the PSE circuit 11 can detect the detection resistor 231 via the LAN cable 3, power supply to the power supply control unit 2 is started, and power is supplied from the power supply unit 230 to each component of the electronic device 2. The Further, the connection control unit 220 maintains continuity between the LAN cable 3 and the detection resistor 231 by the power supplied from the power supply unit 230 even after the operation for starting the power supply is completed.

  The disconnection control unit 240 is connected to the LAN cable 3 in parallel with the power supply unit 230 via the communication unit 210, and a predetermined condition, for example, a control signal from the control unit 21, changes in illuminance or temperature around the electronic device 2, and the like. Based on the above, a current of 500 mA or more which is a threshold value is supplied to the LAN cable 3 by the power supplied from the power supply unit 230. When the cutting control unit 240 supplies a current of 500 mA or more to the LAN cable 3, the current protection circuit in the PSE circuit 11 operates, and the PSE circuit 11 stops supplying power to the power supply control unit 20. In addition, when the power supply is stopped, the connection control unit 220 cannot maintain the continuity between the LAN cable 3 and the detection resistor 231, and disconnects the connection between the LAN cable 3 and the detection resistor 231. As a result, the detection resistor 231 cannot be detected from the PSE circuit 11, and power is not supplied from the PSE circuit 11 to the power supply control unit 20 until the continuity between the LAN cable 3 and the detection resistor 231 is established again.

  As described above, in the electronic device 2 of the present embodiment, when the connection control unit 220 accepts an operation for starting power feeding, the connection between the LAN cable 3 and the detection resistor 231 is established, and the power supply unit The continuity is maintained by the power supplied from 230. Therefore, by performing an operation for starting power supply, the PSE circuit 11 of the LAN power supply apparatus 1 can detect the detection resistor 231 via the LAN cable 3, and the PSE circuit that has detected the detection resistor 231. Power supply from 11 to the power supply control unit 20 is started.

  Further, according to the present invention, the disconnection control unit 240 allows a current equal to or greater than the threshold value to flow through the LAN cable 3 with the power supplied from the power supply unit 230 based on a predetermined condition. For this reason, when a predetermined condition is satisfied, a current equal to or greater than the threshold value flows in the LAN cable 3, so that the PSE circuit 11 stops power feeding. In addition, since the power supply is stopped, the connection control unit 220 cannot maintain the continuity between the LAN cable 3 and the detection resistor 231, and the detection resistor 231 cannot be detected from the PSE circuit 11. Until the operation is performed, the power supply from the PSE circuit 11 to the power supply control unit 20 is stopped.

  Therefore, it is possible to easily control start and stop of power supply to the electronic device 2 via the LAN cable 2.

  Next, the best mode for carrying out the present invention will be described using specific examples.

  In the following, an embodiment in which the electronic device shown in FIG. 1 is embodied as an IP telephone will be described.

Example 1
FIG. 2 is a diagram illustrating the configuration of the electronic device 2 illustrated in FIG. 1 according to the first embodiment.

  As shown in FIG. 2, the IP telephone 2 according to the present embodiment includes a power control unit 20, a control unit 21, and a user interface (IF) 22 that is an input unit. The power controller 20 includes a LAN connector 211, a LANIF circuit 212, a switch 221, a first transistor (Tr1) 222, a second transistor (Tr2) 242, a third transistor (Tr3) 241, and a first resistor (R1) 243. A second resistor (R2) 244 which is a current adjusting resistor, a PD (Power Device) circuit 232, a detection resistor 231, a power supply circuit 233, and a reset IC 245.

  The communication unit 210 shown in FIG. 1 includes a LAN connector 211 and a LANIF circuit 212, the power supply unit 230 includes a PD circuit 232, a detection resistor 231 and a power supply circuit 233, and the connection control unit 220 includes a switch 221 and a second circuit. The disconnect control unit 240 includes a second transistor 242, a third transistor 241, a first resistor 243, a second resistor 244, and a reset IC 245.

  The LAN connector 211 is connected to the PSE circuit 11 of the LAN power supply device 1 via the LAN cable 3.

  The LANIF circuit 212 connects the PD circuit 232 to the LAN cable 3 connected to the LAN connector 211.

  The PD circuit 232 includes a detection resistor 231 and is connected to the LAN cable 3 connected to the LAN connector 211 via the LANIF circuit 212. The PD circuit 232 outputs a voltage of 48 V to the power supply circuit 233 when receiving power from the PSE circuit 11.

  The switch 221 is connected in series with the PD circuit 232 to the LAN cable 3 connected to the LAN connector 211 via the LANIF circuit 212. In the released state, the switch 221 disconnects the connection between the LAN cable 3 and the detection resistor 231, and accepts an operation for starting power feeding, specifically an operation such as pressing the LAN cable 3. And the detection resistor 231 are conducted. As a result, the PSE circuit 11 can detect the detection resistor 231 connected to the LAN cable 3 and starts supplying power to the power supply control unit 20.

  The first transistor 222 is connected in parallel with the switch 221 between the LANIF circuit 212 and the PD circuit 232, and the PD circuit 232 is connected to the base. When power supply from the PSE circuit 11 is started and a voltage of 48 V is output from the PD circuit 232, the first transistor 222 is applied to the base and turned on, and the first transistor 222 is turned on via the LANIF circuit 212. The connection between the LAN cable 3 connected to the connector 211 and the detection resistor 231 is conducted, and the conduction is maintained while the output voltage is applied to the base. The first transistor 222 is in an OFF state when the output voltage of the PD circuit 232 is not applied to the base, and disconnects the connection between the LAN cable 3 and the detection resistor 231.

  The power supply circuit 233 transforms the voltage output from the PD circuit 232 and outputs the voltage Vcpu necessary for driving the control unit 21 and the like.

  The user IF 22 receives various operations for controlling the IP telephone 2 by the user. The user IF 22 can be a button, a touch panel, or the like.

  The control unit 21 is driven by Vcpu output from the power supply circuit 233 and controls other components of the IP telephone 2. Specifically, when Vcpu is applied and driven, the controller 211 outputs a high-level voltage control signal that is a constant voltage to the base of the third transistor 241. In addition, when an operation for stopping power feeding is received by the user IF 22, the control unit 21 sets the voltage of the control signal to a low level voltage lower than the high level voltage.

  The third transistor 241 is connected between the ground and the base of the second transistor 242, and becomes ON when the voltage of the control signal output from the control unit 21 to the base is a high level voltage, and the ground and the second transistor Conduction between the base of 242 is established. In addition, when the voltage of the control signal output to the base is a low level voltage, the third transistor 241 is turned off and cuts off the connection between the ground and the base of the second transistor 242.

  The second resistor 244 is connected in parallel with the detection resistor 231 to the LAN cable 3 connected to the LAN connector 211 via the LANIF circuit 212. When the second resistor 244 receives power from the PSE circuit 11, the second resistor 244 flows a current of 500 mA or more as a threshold value through the LAN cable 3.

  The second transistor 242 is connected in series with the second resistor 244 to the LAN cable 3 connected to the LAN connector 211. The base of the second transistor 242 is connected to the power supply circuit 233 via the first resistor 243 and the reset IC 245. The second transistor 242 switches between an ON state and an OFF state according to the magnitude of the voltage applied to the base. When the second transistor 242 is ON, the second transistor 242 conducts between the LAN cable 3 and the second resistor 244, and when it is OFF, The connection between the LAN cable 3 and the second resistor 244 is disconnected. Note that the magnitude of the voltage applied to the base of the second transistor 242 changes depending on the state of the third transistor. When the third transistor is in the OFF state, all the voltages output from the power supply circuit 233 are based on the base. Since the voltage is applied, the second transistor is turned on. On the other hand, when the third transistor is in the ON state, since the base and the ground are connected, the voltage applied to the base is reduced, and the second transistor is in the OFF state.

  The reset IC 245 is input so that the control signal is output from the control unit 21 to the base of the third transistor 241 and then the output voltage of the power supply circuit 233 is applied to the base of the second transistor 242 and the third transistor 241. The output voltage of the power supply circuit 233 is delayed and output.

  The first resistor 243 is a resistor for adjusting the magnitude of the voltage applied to the base of the second transistor 242 and the third transistor 241.

  The operation of the IP telephone 2 according to the present embodiment shown in FIG. 2 will be described below.

  First, an operation for starting the IP telephone 2 shown in FIG. 2 will be described.

  First, the LAN cable 3 is connected to the LAN connector 211, and the power supply control unit 20 and the PSE circuit 11 are connected. At this time, since both the switch 221 and the first transistor 222 are disconnected from the LAN cable 3 and the detection resistor 231, the PSE circuit 11 cannot detect the detection resistor 231, and the power supply control unit 20. Do not supply power.

  Next, when the switch 221 is pressed as an operation for starting power feeding, the switch 221 conducts between the LAN cable 3 connected to the LAN connector 211 and the detection resistor 231 via the LANIF circuit 212. Let As a result, the PSE circuit 11 can detect the detection resistor 231 and starts supplying power to the power supply control unit 20. Note that the switch 221 does not hold the state, and enters the OPEN state when the operation for starting the power supply is completed and the pressing is released.

  Next, when the power supply from the PSE circuit 11 is started, the PD circuit 232 outputs a voltage of 48 V to the power supply circuit 233. This voltage is also applied to the base of the first transistor 222, whereby the first transistor 222 is turned on, so that conduction between the LAN cable 3 and the detection resistor 231 is maintained even after the switch 221 is released. . In addition, IEEE802. Based on the definition of af, it is necessary to set the resistance of the first transistor so that the combined resistance of the 25 k ohm detection resistor 231 and the first transistor 222 does not exceed 26.25 kΩ.

  Next, when a voltage of 48 V is output from the PD circuit 232, the power supply circuit 233 outputs the voltage Vcpu necessary to transform the voltage and drive the control unit 21 and the like.

  Next, the control unit 21 such as a CPU is activated by Vcpu output from the power supply circuit 233 and sets the voltage of the control signal output to the base of the third transistor 241 to a high level voltage.

  Further, when the Vcpu output from the power supply circuit 233 is input, the reset IC 245 outputs the input Vcpu until a high-level voltage control signal is output from the control unit 21 to the base of the third transistor 241. To delay. Vcpu delayed and output from the reset IC 245 is adjusted to an appropriate voltage by the first resistor 243 and then applied to the base of the second transistor 242.

  Thereafter, the third transistor 241 is turned on when a control signal of a high level voltage is input to the base, and the ground and the base of the second transistor 242 are made conductive. For this reason, the voltage applied to the base of the second transistor 242 decreases, the second transistor 242 remains in the OFF state, and power supply from the PSE circuit 11 to the power supply control unit 20 is continued.

  Next, an operation for stopping the IP telephone 2 shown in FIG. 2 will be described.

  First, when receiving an operation for stopping power supply, the user IF 22 outputs a power supply stop command instructing to stop power supply to the control unit 21. Note that the operation for stopping the power supply performed by the user IF 22 includes pressing a button assigned to the power supply stop provided in the user IF 22, selecting an item for stopping power supply on the screen, and stopping power supply on the screen of the touch panel. It is assumed that the icon is pressed.

  In response to this, the control unit 21 sets the voltage of the control signal output to the base of the third transistor 241 to a low level voltage.

  Next, the third transistor 241 is turned off when the voltage of the control signal output from the control unit 21 is set to the low level voltage, and disconnects the conduction between the ground and the base of the second transistor 242. . As a result, the voltage applied to the base of the second transistor 242 increases, and the second transistor 242 is turned on.

  Next, since the second transistor 242 is turned on, the second resistor 244 and the LAN cable 3 become conductive, and the power supplied from the PSE circuit 11 is supplied to the second resistor 244. As a result, a current of 500 mA, which is a current equal to or higher than the threshold, flows through the LAN cable 3. Note that the magnitude of the resistance of the second resistor 244 needs to be set so that a current of 500 mA or more flows due to the power supplied from the PSE circuit 11.

  Next, the PSE circuit 11 stops the power supply to the power supply control unit 20 when a current of 500 mA flows through the LAN cable 3 for 1 ms or more based on the regulation of IEEE802.3af.

  Next, when the power supply from the PSE circuit 11 to the power supply control unit 20 is stopped, the voltage of 48 V is not output from the PD circuit 232, so the first transistor is turned off. As a result, the connection between the LAN cable 3 and the detection resistor 231 is disconnected.

  Thereafter, the PSE circuit 11 periodically outputs a detection voltage to the power supply control unit 20 via the LAN cable 3 in order to detect the detection resistor 231, but the connection between the LAN cable 3 and the detection resistor 231 is disconnected. Therefore, the detection resistor 231 cannot be detected, and the power supply is stopped.

  As described above, in the IP telephone 2 according to the present embodiment, the start and stop of power supply to the IP telephone 2 can be easily controlled by a user operation.

(Example 2)
FIG. 3 is a diagram illustrating a configuration of a second embodiment of the electronic device 2 illustrated in FIG. 1.

  As shown in FIG. 3, the IP telephone 2 of the present embodiment has a sensor unit 23 in addition to the components of the IP telephone 2 of the first embodiment shown in FIG.

  The sensor unit 23 measures the illuminance and temperature around the IP telephone 2 shown in FIG. 3, and outputs a power supply stop command to the control unit 20 based on the measured illuminance and temperature. Therefore, power supply from the PSE circuit 11 to the power supply control unit 20 can be automatically stopped according to a change in the environment around the IP telephone 2.

  When the optical sensor for measuring the illuminance around the IP telephone 2 shown in FIG. 3 is used as the sensor unit 23, the sensor unit 23 instructs the control unit 20 to stop power supply when the ambient illuminance is equal to or lower than a predetermined set illuminance. Is output. By doing in this way, for example, the power supply can be automatically stopped at night or when the light goes off and the surroundings of the IP telephone 2 become dark. The sensor unit 23 may be configured to output a power supply stop command to the control unit 20 when the ambient illuminance is greater than or equal to a predetermined set illuminance.

  When the temperature sensor for measuring the ambient temperature of the IP telephone 2 shown in FIG. 3 is used as the sensor unit 23, the sensor unit 23 supplies power to the control unit 20 when the ambient temperature is equal to or higher than a predetermined set temperature. Output a stop command. In this way, for example, when an abnormality occurs in the IP telephone 2 and the temperature rises, power supply to the IP telephone 2 can be automatically stopped. Further, in the summer, when the user leaves the room where the IP telephone 2 is installed and the cooler is stopped and the ambient temperature rises, the power supply to the IP telephone 2 can be automatically stopped. The sensor unit 23 may be configured to output a power supply stop command to the control unit 20 when the ambient temperature is equal to or lower than a predetermined set temperature. In this case, in the winter, when the user leaves the room and heating is stopped, and the ambient temperature decreases, the power supply to the IP telephone 2 can be automatically stopped. Moreover, it is good also as a structure which sets the temperature range and outputs the electric power supply stop command to the control part 20 when the sensor part 23 deviates from the temperature range.

  As described above, in the IP telephone 2 according to the present embodiment, by providing the sensor unit 23, the power supply to the IP telephone 2 can be automatically stopped according to a change in the environment around the IP telephone 2.

(Example 3)
FIG. 4 is a diagram illustrating a configuration of a third embodiment of the electronic apparatus 2 illustrated in FIG. 1.

  As shown in FIG. 4, the IP telephone 2 of this embodiment has a timer unit 24 in addition to the components of the IP telephone 2 of the second embodiment shown in FIG.

  The timer unit 24 measures time and outputs a power supply stop command to the control unit 20 when a predetermined set time set via the user IF unit 22 is measured. Thereby, the power supply to the IP telephone 2 can be automatically stopped at a specified time. For this reason, the timer unit 24 is used to automatically stop power supply to the IP telephone 2 by specifying the time, day of the week, date, etc. by providing the IP telephone 2 with a clock function and a calendar function for measuring the date and time. Can do.

Example 4
FIG. 5 is a diagram illustrating a configuration of a fourth embodiment of the electronic device 2 illustrated in FIG. 1.

  As shown in FIG. 5, the IP telephone 2 of the present embodiment is connected to the PC 4 which is another electronic device via the LAN cable 5 in addition to the components of the IP telephone 2 of the third embodiment shown in FIG. LAN connector 25 and LANIF circuit 26 are provided. The communication means of the present invention includes a LAN connector 25 and a LANIF circuit 26.

  The LANIF circuit 26 communicates with the PC 4 via the LAN cable 5 connected to the LAN connector 25.

  When the control signal is received by the LANIF circuit 26 via the LAN cable 5 connected to the LAN connector 25, the control unit 21 sets the voltage of the control signal to the low level voltage. Set to.

  Thereby, the power supply to the IP telephone 2 can be stopped by remote operation from the PC 4 which is another electronic device via the LAN cable 5. Further, by configuring the PC 4 to automatically output to the IP telephone 2 a signal for instructing to stop power supply when stopping, the power supply to the IP telephone 2 is stopped when the PC 4 is stopped, and the IP telephone 2 is also adjusted. Can be stopped.

(Example 5)
FIG. 6 is a diagram illustrating a configuration of a fifth embodiment of the electronic device 2 illustrated in FIG. 1. Note that components of the IP telephone other than the power supply control unit 20 are omitted.

  As shown in FIG. 6, the IP telephone set 2 of this embodiment is different from the IP telephone sets 2 of Embodiments 1 to 4 shown in FIGS. The difference is that the phototransistor (PTr) 246 is provided and the reset IC 245 is not provided.

  The phototransistor 246 is turned off when the illuminance around the IP telephone 2 shown in FIG. 6 is equal to or lower than the predetermined illuminance, and the connection between the ground and the base of the second transistor 242 is cut off. When the illuminance is larger than the predetermined illuminance, it is turned on, and the ground and the base of the second transistor 242 are made conductive.

  By using the phototransistor 264 in this manner, the control signal from the control unit 21 shown in FIGS. 1 to 5 is not required, and power is automatically supplied to the IP telephone 2 according to the illuminance around the IP telephone 2. Can be stopped. Therefore, components such as the control unit 21, the user IF 22, the sensor unit 23, the timer unit 24, the LAN connector 25, and the LANIF circuit 26 shown in FIG. 5 are not necessary. Further, since the control signal from the control unit 21 is not required, the reset IC 245 for delaying the output of the input power supply circuit 233 until the control signal is output from the user IF control unit 21 is also unnecessary. .

  Further, since a control signal from the control unit 21 is not required, the power supply control unit 20 can be provided outside the electronic device as a power supply control device.

  The IP telephone 2 shown in the first to fifth embodiments described above is an example of the electronic device of the present invention. The present invention is applicable to all electronic devices that receive power from the LAN power supply device 1, such as surveillance cameras and wireless LANs. It can be applied to an access point or the like.

It is a figure which shows the structure of one Embodiment of the electronic device of this invention. It is a figure which shows the structure of Example 1 of the electronic device shown in FIG. It is a figure which shows the structure of Example 2 of the electronic device shown in FIG. It is a figure which shows the structure of Example 3 of the electronic device shown in FIG. It is a figure which shows the structure of Example 4 of the electronic device shown in FIG. It is a figure which shows the structure of Example 5 of the electronic device shown in FIG.

Explanation of symbols

1 LAN power supply device 2 Electronic equipment (IP telephone)
3,5 LAN cable 4 PC
11 PSE circuit 20 Power supply control unit 21 Control unit 22 User IF
DESCRIPTION OF SYMBOLS 23 Sensor part 24 Timer part 25, 211 LAN connector 26,212 LANIF circuit 210 Communication means 220 Connection control means 221 Switch 222 1st transistor 230 Power supply means 231 Detection resistance 232 PD circuit 233 Power supply circuit 240 Disconnection control means 241 3rd transistor 242 Second transistor 243 First resistor 244 Second resistor 245 Reset IC
246 Phototransistor

Claims (14)

A power control unit including a detection resistor and receiving power from a power supply device via a communication cable, wherein the power supply is started when the power supply device detects the detection resistance via the communication cable; In an electronic device that is stopped when a current exceeding the threshold flows through the cable,
The power control unit
Power supply means for receiving power and supplying power;
Connection control means for conducting between the communication cable and the detection resistor when receiving an operation for starting the power supply, and maintaining the conduction by power supplied from the power supply means;
An electronic apparatus comprising: cutting control means for causing a current equal to or greater than the threshold value to flow through the communication cable by electric power supplied from the power supply means based on a predetermined condition. The electronic device according to claim 1,
The connection control means includes
When the operation for starting the power supply is accepted, the communication cable and the detection resistor are made conductive, and when the operation for starting the power supply is completed, the connection between the communication cable and the detection resistor is disconnected. A switch to
Connected in parallel with the switch, and when power is supplied from the power supply means, the communication cable and the detection resistor are brought into conduction, and when the supply of power from the power supply means is stopped, the communication cable and the detection resistance And a first transistor that disconnects the connection between the electronic device and the electronic device. The electronic device according to claim 2,
An input unit for receiving an operation for stopping power feeding;
When power is supplied from the power supply means, a control signal with a constant voltage is output to the disconnection control means, and when an operation for stopping the power feeding is accepted at the input unit, the voltage of the control signal is A control unit that sets the voltage lower than a certain voltage;
The disconnection control unit is an electronic device that causes a current equal to or greater than the threshold to flow through the communication cable, with the predetermined condition that a voltage of the control signal is set to a voltage lower than the constant voltage. The electronic device according to claim 3,
An optical sensor that measures the illuminance around the electronic device and outputs a power supply stop command that instructs the power supply to be stopped when the measured illuminance is equal to or lower than a predetermined set illuminance,
In response to the power supply stop command, the control unit sets the voltage of the control signal to a voltage lower than the certain voltage. The electronic device according to claim 3,
An optical sensor that measures the illuminance around the electronic device and outputs a power supply stop command that instructs the power supply to be stopped when the measured illuminance is equal to or higher than a predetermined set illuminance,
In response to the power supply stop command, the control unit sets the voltage of the control signal to a voltage lower than the certain voltage. The electronic device according to claim 4 or 5,
The electronic device further includes a temperature sensor that measures the ambient temperature of the electronic device and outputs the power supply stop command to the control unit when the measured temperature is equal to or lower than a predetermined set temperature. The electronic device according to claim 4 or 5,
An electronic apparatus further comprising a temperature sensor that measures a temperature around the electronic apparatus and outputs the power supply stop command to the control unit when the measured temperature is equal to or higher than a predetermined set temperature. The electronic device according to claim 6 or 7,
An electronic apparatus further comprising a timer unit that measures time and outputs the power supply stop command to the control unit when a predetermined set time is measured. The electronic device according to claim 8,
It further has communication means for connecting to other electronic devices via a communication cable,
The control unit sets the voltage of the control signal to a voltage lower than the constant voltage when a signal instructing to stop the power supply output from the other electronic device is received by the communication unit. Electronics. The electronic device according to any one of claims 2 to 9,
The cutting control means includes
A current adjusting resistor connected in parallel with the power supply means to the communication cable, and receiving the power supply via the communication cable, a current adjusting resistor that causes the current above the threshold to flow through the communication cable;
A second transistor connected in series with the current adjustment resistor to the communication cable, and controlling conduction and disconnection between the communication cable and the current adjustment resistor in accordance with power supplied from the power supply means;
By connecting between the ground and the base of the second transistor, and controlling the conduction and disconnection of the connection between the second transistor and the ground according to the voltage of the control signal output from the control unit. A third transistor for controlling the amount of power supplied from the power supply means to the second transistor;
Connected between the power supply means and the base of the second transistor, the power output from the power supply means is supplied to the second transistor until the control signal is output from the control means to the third transistor. An electronic device having a reset IC that delays the operation. The electronic device according to claim 2,
The cutting control means includes
A current adjusting resistor connected in parallel with the power supply means to the communication cable, and receiving the power supply via the communication cable, a current adjusting resistor that causes the current above the threshold to flow through the communication cable;
A second transistor connected in series with the current adjustment resistor to the communication cable, and controlling conduction and disconnection between the communication cable and the current adjustment resistor in accordance with power supplied from the power supply means;
The power supply means is connected between the ground and the base of the second transistor, and controls conduction and disconnection of the connection between the second transistor and the ground according to the illuminance around the electronic device. An electronic device comprising: a phototransistor that controls the amount of power supplied to the second transistor. A detection resistor is provided, and is supplied with power from a power supply device via a communication cable, and the power supply is started when the power supply device detects the detection resistance via the communication cable, and a current equal to or greater than a threshold value is supplied to the communication cable. In the power supply control device, which is stopped by flowing
Power supply means for receiving power and supplying power;
Connection control means for conducting between the communication cable and the detection resistor when receiving an operation for starting the power supply, and maintaining the conduction by power supplied from the power supply means;
A power supply control device comprising: a cutting control means for causing a current equal to or greater than the threshold value to flow through the communication cable by electric power supplied from the power supply means based on a predetermined condition. The power supply control device according to claim 12,
The connection control means includes
When the operation for starting the power supply is accepted, the communication cable and the detection resistor are made conductive, and when the operation for starting the power supply is completed, the connection between the communication cable and the detection resistor is disconnected. A switch to
Connected in parallel with the switch, and when power is supplied from the power supply means, the communication cable and the detection resistor are brought into conduction, and when the supply of power from the power supply means is stopped, the communication cable and the detection resistance And a first transistor that disconnects the connection between the power supply control device and the power supply control device. The power supply control device according to claim 13,
The cutting control means includes
A current adjusting resistor connected in parallel with the power supply means to the communication cable, and receiving the power supply via the communication cable, a current adjusting resistor that causes the current above the threshold to flow through the communication cable;
A second transistor connected in series with the current adjustment resistor to the communication cable, and controlling conduction and disconnection between the communication cable and the current adjustment resistor in accordance with power supplied from the power supply means;
The power supply means is connected between the ground and the base of the second transistor, and controls conduction and disconnection of the connection between the second transistor and the ground according to the illuminance around the electronic device. And a phototransistor that controls the amount of power supplied to the second transistor.

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