JP2021052553A - Power control device - Google Patents

Abstract

To make sure that power is supplied to an electric device when a user wants to use the electric device.SOLUTION: A power control device that controls power supply of an electric device system, which includes an electric device 110 that performs a predetermined function and/or a predetermined process, and an electric device power supply unit 120 that supplies power to the electric device 110 includes a power supply control unit 130 that turns on/off power supply from the electric device power supply unit 120 to the electric device 110, and a control power supply unit 140 including an environmental power generation element 141, and a booster circuit 142 that boosts a voltage generated by the environmental power generation element 141 to a voltage by which the power supply control unit 130 can operate, and the power supply control unit 130 switches the power supply to the electric device 110 from off to on when the operable voltage is given from the control power supply unit 140.SELECTED DRAWING: Figure 1

Description

The present invention relates to a power supply control device that controls the power supply of various electric devices.

In recent years, a power generation system using electromotive force generated by thermoelectric power as a power source has been developed as energy harvesting. In this case, a Peltier element or the like is used for thermoelectric power generation. When the Peltier element is used, a weak voltage of several tens of mV is generated from the body temperature transmitted from the human body. For example, when power is generated from the temperature difference between the body temperature and the device, or the temperature difference between the body temperature and the outside air temperature, it cannot be expected to secure a large amount of power generation.

Patent Document 1 discloses an electronic device that drives a fingerprint sensor using the heat of a finger. In the invention of Patent Document 1, since it cannot be expected to secure a large amount of power generation as described above, it is described that the peripheral circuit is reduced in voltage to realize a sufficient amount of power generation.

Further, Patent Document 2 discloses a sensor network that generates energy harvesting and has an active mode and a sleep mode. In this sensor network, measurement using a sensor and processing of wirelessly transmitting the measurement result are performed in the active mode, and voltage monitoring obtained by energy harvesting is performed in the sleep mode. When it is detected that the result of the voltage monitoring exceeds a predetermined threshold value, the mode shifts to the active mode.

Japanese Unexamined Patent Publication No. 2004-272719 Japanese Unexamined Patent Publication No. 2018-190053

As described above, in the invention of Patent Document 1, although energy harvesting is used to save power, there is a drawback that the power generated by the energy harvesting is constantly consumed. Further, since the invention of Patent Document 2 has a sleep mode, it has an advantage that the same electric power is not always consumed, but it can be used so that electric power is supplied to the electric equipment when it is desired to be used. Instead, it is expected to be able to perform sharp power control.

The present invention has been made in view of the above circumstances, and an object of the present invention is to provide a power supply control device capable of supplying electric power to an electric device when it is desired to use the electric device. Is.

The power supply control device of the present embodiment is a power supply control device that controls the power supply of an electric device system including an electric device that performs a predetermined function and / or a predetermined process and an electric device power supply unit that supplies power to the electric device. The power supply control unit that turns on / off the power supply from the electric device power supply unit to the electric device, the environmental power generation element, and the voltage generated by the environmental power generation element are boosted to a voltage at which the power supply control unit can operate. A control power supply unit including a booster circuit is provided, and the power supply control unit turns on the power supply to the electric device from off to on when an operable voltage is applied from the control power supply unit. It is characterized by switching to and controlling.

The block diagram of the power supply control device which concerns on 1st Embodiment of this invention. The block diagram of the power supply control device which concerns on 2nd Embodiment of this invention. The figure which shows the voltage which is boosted by the booster circuit which is the main part of the power supply control device which concerns on 2nd Embodiment of this invention. FIG. 6 is a configuration diagram of a main part of a power supply control device according to a second embodiment of the present invention, and is a configuration diagram of a biometric authentication device in which a portion of a capacitive fingerprint sensor is a cross-sectional view. The block diagram of the authentication part in the biometric authentication device of the power supply control device which concerns on 2nd Embodiment of this invention. The flowchart which shows the operation of the power-source control apparatus which concerns on 2nd Embodiment of this invention.

The power supply control device according to the embodiment of the present invention will be described below with reference to the accompanying drawings. In each figure, the same components are designated by the same reference numerals, and duplicate description will be omitted. FIG. 1 shows a configuration diagram of a power supply control device according to the first embodiment of the present invention. The power supply control device 10 according to the present embodiment is provided in the electric device system 100. The electric device system 100 includes an electric device 110 that performs a predetermined function and / or a predetermined process, and an electric device power supply unit 120 that supplies power to the electric device 110. Specifically, the electric device system 100 can be a home appliance such as a television or a vacuum cleaner, an electronic device such as a personal computer, or a device that operates with an electric power source at some time such as an automobile. The electric device 110 is most of the main parts that realize the functions of home appliances such as TVs and vacuum cleaners, electronic devices such as personal computers, and automobiles, and is a component part excluding the power supply part. Then, the power supply unit constitutes the electric device power supply unit 120, and supplies electric power to the electric device 110.

In the present embodiment, the electrical equipment system 100 is provided with a power supply control unit 130 and a control power supply unit 140. The power supply control unit 130 turns on / off the power supply from the electric device power supply unit 120 to the electric device 110. In this embodiment, the power supply control unit 130 is provided in the power supply path from the electric device power supply unit 120 to the electric device 110. The switch 132 is opened and closed to turn the power supply on and off. The switch 132 is turned on (closed) and self-holds on (closed) when a current flows from the electric device power supply unit 120. In order to turn off the switch 132, an operation of a manual operation unit (not shown) is used.

The control power supply unit 140 includes an energy harvesting element 141 and a booster circuit 142 that boosts the voltage generated by the energy harvesting element 141 to a voltage at which the power supply control unit 130 can operate. The power supply control unit 130 operates by the electric power output from the booster circuit 142, and can operate when the voltage of this electric power is equal to or more than a predetermined value.

The energy harvesting element 141 is preferably an element that generates power by heat (body temperature) or pressure (pressing force) so that power can be generated when a person turns on and uses the power of the electric device 110. is there. When the electric device 110 is a television, a personal computer, or the like, for example, the energy harvesting element 141 is directly placed on a portion of the housing surface where a finger or a hand is placed at an appropriate position, or a panel is placed and the panel is placed. A configuration in which the energy harvesting element 141 is arranged behind the surface can be adopted. Further, when the electric device 110 is a home electric appliance such as a vacuum cleaner, a configuration can be adopted in which the energy harvesting element 141 is directly or indirectly arranged on a portion to be gripped by a hand such as a grip or the like via a panel or the like.

The electrical equipment system 100 configured as described above operates as follows. In order to activate the electric device 110, the operator puts his or her hand or finger on the portion where the energy harvesting element 141 is arranged. Then, the energy harvesting element 141 generates power, and a predetermined potential is generated. This predetermined potential is boosted to a voltage at which the power supply control unit 130 can operate by the booster circuit 142. The DC / DC converter described in Japanese Patent Application No. 2019-2965 can be adopted for the booster circuit 142.

Since the output of the booster circuit 142 is given to the power supply control unit 130 and is a voltage at which the power supply control unit 130 can operate, the power supply control unit 130 starts operation and turns on (closes) the switch 132. ). As a result, electric power is supplied to the electric device 110 from the electric device power supply unit 120, and the electric device 110 is put into an operating state. As described above, according to the first embodiment, the electric power is supplied to the electric device 110 when the electric device 110 is desired to be used, and the problem that the electric power of the energy harvesting is constantly consumed can be avoided.

FIG. 2 shows an electrical equipment system 200 having the power supply control device 30 of the second embodiment. The electrical equipment system 200 includes a biometric authentication device 250. The electric device system 200 includes an electric device 210 that performs a predetermined function and / or a predetermined process, and an electric device power supply unit 220 that supplies power to the electric device 210. Specifically, the electric device system 200 may be a home appliance such as a television or a vacuum cleaner, or an electronic device such as a personal computer, as in the first embodiment, but is a personal computer that can be used only by a predetermined individual. It can be a computer, an ATM (automatic cash deposit / payment machine), or a device that operates with an electric power source at some time such as an automobile. The electric device 210 is most of the main parts that realize the functions of the personal computer, the ATM, and the automobile, and is a component part excluding the power supply part. Then, the power supply unit constitutes the electric device power supply unit 220, and outputs the electric power of the electric device 210.

In the present embodiment, the electrical equipment system 200 is provided with a power supply control unit 230 and a control power supply unit 240. The power supply control unit 230 turns off the power supply to the electric device 210 when an operable voltage is given from the control power supply unit 240 and the biometric authentication device 250 outputs the use permission signal. It controls switching from to on.

In this embodiment, the switch 232 provided in the power supply path from the electric device power supply unit 220 to the electric device 210 is opened and closed to turn the power supply on and off. The switch 232 is turned on (closed) and self-holds on (closed) when a current flows from the electric device power supply unit 220. In order to turn off the switch 232, the power supply control unit 230 opens the switch 232 by operating a manual operation unit (not shown) or when the time during which the use permission signal cannot be obtained reaches a predetermined time. You may turn off the power supply.

The control power supply unit 240 includes an energy harvesting element 241 and a booster circuit 242 that boosts the voltage generated by the energy harvesting element 241 to a voltage that can be operated by the power supply supplied from the control power supply unit. The power supply control unit 230 operates by the electric power output from the booster circuit 242, and can operate when the voltage of this electric power is equal to or more than a predetermined value. The DC / DC converter described in Japanese Patent Application No. 2019-2965 can be adopted for the booster circuit 242.

In the present embodiment, since the biometric authentication device 250 and the power supply control unit 230 are operated by the power supply supplied from the control power supply unit 240, the voltage at which the biometric authentication device 250 can operate is set as the output voltage C, and the power supply is described. When the voltage at which the supply control unit 230 can operate is set to the output voltage A, the booster circuit 242 creates the output voltage A shown in FIG. 3 by boosting and gives it to the biometric authentication device 250, and shows it by boosting in FIG. The output voltage A can be created and given to the power supply control unit 230. In the example of FIG. 3, output voltage A> output voltage B> output voltage C, and the output voltage B can be output by boosting the output voltage B, but the output voltage B is not used. be able to. Alternatively, two booster circuits may be used, which are a booster circuit capable of boosting the output voltage C and outputting the output voltage C and a booster circuit capable of boosting the output voltage A and outputting the output voltage A. That is, the control power supply unit 240 is generated by the first booster circuit that boosts the voltage generated by the environmental power generation element 241 to a voltage at which the power supply control unit 230 can operate, and the environmental power generation element 241. The configuration may include a second booster circuit that boosts the voltage to a voltage at which the biometric authentication device 250 can operate.

The biometric authentication device 250 operates by the power supply supplied from the control power supply unit 240 as described above, performs a biometric authentication function, and outputs a usage permission signal when biometric authentication of a specific person is performed. The biometric authentication device 250 may include a capacitive fingerprint sensor 251 as shown in FIG. The capacitive fingerprint sensor 251 of the biometric authentication device 250 has a panel portion 252 that contacts the pad of a finger 61, and detects an electric charge by a plurality of electrodes 253 provided directly below the panel portion 252. That is, the distance from the counter electrode in the plurality of electrodes 253 to the finger surface differs due to the unevenness generated by the fingerprint on the pad of the finger 61, and the magnitude of the amount of charge generated between the panel portion 252 and the electrode corresponds to the above distance. And will be different. Fingerprint detection is performed by detecting this amount of electric charge. Thus, the fingerprint of the pad of the finger 61 in contact with the surface of the panel portion 252 is read, and biometric authentication is performed using the read fingerprint data.

The biometric authentication device 250 has the authentication unit 258 shown in FIG. 4, and has, for example, the configuration shown in FIG. That is, the CPU 20 that performs fingerprint authentication using the program and data stored in the main memory 21 has a configuration in which each unit is collectively controlled. An external storage interface 23, a sensor interface 24, a display interface 25, and a network interface 26 are connected to the CPU 20 via a bus 22.

An external storage device 33 is connected to the external storage interface 23. The external storage device 33 stores fingerprint data of a person who is permitted to use the electric device 210, a fingerprint authentication program, and the like. A capacitive fingerprint sensor 34 is connected to the sensor interface 24. A display device 35 is connected to the display interface 25. The display device 35 has a small display such as an LED, and the authentication result such as "The use of this device is permitted" or "The use of this device is not possible" is displayed. A network line 36 is connected to the network interface 26, and the use of the electric device 210 is permitted periodically or irregularly from a server or the like that manages the electric device system 200 via the network line 36. The contents of the external storage device 33 are updated by downloading the update data of the human fingerprint data and the update program of the fingerprint authentication program.

Since the electrical equipment system 200 configured as described above performs processing according to the flowchart shown in FIG. 6, the operation will be described based on this flowchart. The control power supply unit 240 (particularly, the energy harvesting element 241) waits for the finger 61 to touch the panel unit 252 (STEP1), and detects whether the finger 61 has touched it (STEP2). If NO in STEP2, it returns to STEP1. If YES in STEP2, power is generated by the energy harvesting element 241 and boosted by the booster circuit 242 to supply power to the biometric authentication device 250 (STEP3). Further, in STEP3, the biometric authentication device 250 authenticates, and in the next STEP4, it detects whether the authentication is successful.

When branching to NO in STEP4, a display such as "This device cannot be used" is displayed on the display device 35 (STEP5), and the process ends. When branching to YES in STEP4, an operable voltage is given from the control unit power supply unit 240, and the biometric authentication device 250 outputs the use permission signal. Therefore, the power supply control unit 230 uses the electric device. By switching and controlling the power supply to the 210 from off to on, the electric device 210 is put into a usable state (STEP 6). In this STEP 6, the display device 35 may display a message such as "The use of this device is permitted." After STEP6, the electric device 210 is used, and when the electric device 210 can be turned off (STEP7), the process ends.

As described above, in the present embodiment, since the operation for obtaining the license to use the electric device 210 by biometric authentication leads to the power supply processing to the biometric authentication device 250, no power is consumed at all when not in use and the cost is low. It is possible to operate a highly secure system.

10, 30 Power control unit 20 CPU
21 Main memory 22 Bus 23 External storage interface 24 Sensor interface 25 Display interface 26 Network interface 33 External storage device 35 Display device 36 Network line 61 Finger 100 Electrical equipment system 110 Electrical equipment 120 Electrical equipment power supply 130 Power supply control 132 Switch 140 Control power supply 141 Environmental power generation element 142 Booster circuit 200 Electrical equipment system 210 Electrical equipment 220 Electrical equipment power supply unit 230 Power supply control unit 232 Switch 240 Control power supply unit 241 Environmental power generation element 242 Booster circuit 250 Biometric authentication device 251 Capacitance Type fingerprint sensor 252 panel part 253 electrode 258 certification part

Claims (5)

In a power supply control device that controls the power supply of an electric device system including an electric device that performs a predetermined function and / or a predetermined process and an electric device power supply unit that supplies power to the electric device.
A power supply control unit that turns on / off the power supply from the electric device power supply unit to the electric device, and a power supply control unit.
A control power supply unit including an energy harvesting element and a booster circuit that boosts the voltage generated by the energy harvesting element to a voltage at which the power supply control unit can operate.
Equipped with
The power supply control unit is a power supply control device, characterized in that, when an operable voltage is applied from the control power supply unit, the power supply to the electric device is switched and controlled from off to on. It has a biometric authentication device that operates by the power supply supplied from the control power supply unit, performs a biometric authentication function, and outputs a usage permission signal when biometric authentication of a specific person is performed.
The power supply control unit switches the power supply to the electric device from off to on when an operable voltage is applied from the control power supply unit and the biometric authentication device outputs the use permission signal. The power supply control device according to claim 1, wherein switching control is performed. The control power supply unit has a first booster circuit that boosts the voltage generated by the environmental power generation element to a voltage at which the power supply control unit can operate, and the biometric authentication of the voltage generated by the environmental power generation element. The power supply control device according to claim 2, further comprising a second booster circuit that boosts the device to a voltage at which it can operate. The biometric authentication device has a panel portion that comes into contact with the pad of the finger, and biometric authentication is performed by the fingerprint of the pad of the finger that comes into contact with the panel portion.
The power supply control device according to claim 2 or 3, wherein the energy harvesting element is a thermoelectric power generation element and generates heat by obtaining heat from a finger in contact with the panel portion. The power supply control device according to claim 4, wherein the biometric authentication device includes a capacitive fingerprint sensor.

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