JP6661105B1 - Power control device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a power supply control function that operates only when the device is carried without modifying the existing device. A power supply control device of the present invention is a power supply control device for accommodating a battery in a battery box of an external device together with a battery. A small microcomputer that performs an initialization process and a power supply control unit that controls the power supplied from the battery to the external device according to the detection result of the acceleration sensor are provided. [Selection diagram] Fig. 1

Description

        The present invention relates to a power supply control device added to an existing device.

        In the case of a device that is mainly operated by a battery, there is a technology that detects a use state of the device using an acceleration sensor in order to suppress power consumption, and shifts to a power saving mode when the device is not used.

      In the device disclosed in Patent Document 1, a power control function of stopping power from a power supply unit by a motion detection switch is incorporated.

      In the device disclosed in Patent Literature 2, it is possible to control the power supply of existing equipment by wireless communication from outside without changing the existing circuit.

JP 2016-127600 A JP-A-2019-62693

      However, there is a problem that a circuit must be changed when adding a function that detects movement of an existing device and operates only when the device is in use. An object of the present invention is to provide a power supply control device capable of controlling power supply to an external device by detecting an acceleration without making a circuit change to an existing external device in order to solve the above-described problem. In addition, when the external device is not used, that is, when no acceleration is applied to the external device, the power supply to the external device is cut off, and the external device is used, that is, the external device is subjected to the acceleration. It is an object to provide a function of supplying power to an external device in a state.

      Further, in the device disclosed in Patent Document 2, it is possible to control the power supply of the external device without changing the circuit of the existing external device, but it is assumed that the device is realized with the same size as a coin-type battery. Not a technology.

      The present invention has been made in order to solve the above-described problems, and the power supply control device of the present invention is housed together with a battery in a battery box of an existing external device, so that the circuit of the external device can be changed. Without adding, power is supplied when the external device is possessed and used, that is, when the power supply control device detects some kind of acceleration, motion is detected, and the external device can be determined to be moving. The above object is achieved by adding a function of interrupting power supply when the external device can be determined to be stationary.

      The acceleration sensor according to claim 2 has a function of outputting a motion detection signal when acceleration equal to or higher than a threshold is detected while operating with power saving, in addition to the acceleration measurement function. By using an acceleration sensor having this function, low power consumption and miniaturization can be realized. Further, the acceleration sensor communicates with the microcomputer, but a small microcomputer having no serial communication circuit is used to realize I2C communication and SPI communication by emulating serial communication by software. Thus, the power supply control device can be downsized.

      The acceleration sensor according to the second aspect can independently detect a motion after the completion of the initialization processing by the microcomputer. Therefore, there is no need for the microcomputer to perform complicated calculations for motion detection, and there is no need to constantly monitor the acceleration sensor. Thus, the microcomputer can be put into a sleep state after the initialization processing of the acceleration sensor is completed. Therefore, current consumption can be suppressed, so that a thin battery having a smaller capacity than a normally used battery can be used.

      The power supply control unit according to claim 3 controls power supply from the battery to the external device based on a motion detection signal output from the acceleration sensor. That is, when the external device receives a motion detection signal that is output when any acceleration is detected, power is supplied to the external device, and when a state in which no acceleration is detected is measured for a predetermined time or longer, the motion detection signal is not output. Therefore, power supply to the external device is cut off.

      When the external device is a smart key of a vehicle, the power control device is housed in a battery box of the smart key together with a thin coin-type battery. When the smart key is carried, power is supplied to the smart key by the power supply control device, and the smart key operates as a vehicle key. If the smart key is left unattended, a stationary state exceeding a certain level is detected, the power supply to the smart key is stopped, and a radio wave for releasing the key is not output. Disappears.

      According to the present invention, the present power supply control device is housed in the battery box of the existing external device, so that the power supply control function by motion detection without changing the existing circuit, that is, when the external device is not used The function of controlling the power supply to the external device can be added by turning off the main power of the external device and supplying the main power of the external device to the existing circuit when using the external device. Even if a battery thinner than a conventional battery is used, the battery is not significantly consumed.

FIG. 2 is a block diagram illustrating a configuration of a power supply control device according to the present invention. FIG. 2 is a diagram illustrating an internal structure of the power supply control device according to the first embodiment. FIG. 4 is a diagram for explaining a usage example of the power supply control device according to the first embodiment. It is a figure showing an embodiment when applied to a smart key of a vehicle. It is a figure showing an embodiment when a power supply control device concerning a 2nd embodiment is applied to a battery box. FIG. 5A illustrates an appearance of the second embodiment, and FIG. 5B illustrates a usage example of the second embodiment.

      Hereinafter, embodiments of the present invention will be described with reference to the drawings. FIG. 1 is a diagram illustrating an example of a schematic configuration of a power supply control device according to the present embodiment. As shown in FIG. 1, in a device including a battery box 1, a battery 2, and an existing circuit 3, a power control device according to the present embodiment including a power control unit 4, an acceleration sensor 5, and a microcomputer 6 in the battery box 1. Is accommodated. Power is supplied from the existing battery 2 to the power control device, power is supplied to the acceleration sensor 5 and the microcomputer 6, and the power control unit is controlled by the motion detection function of the acceleration sensor 5.

      The acceleration sensor 5 communicates with a microcomputer by a serial communication method such as I2C communication or SPI communication. In this case, the microcomputer must include a serial communication circuit. However, by realizing serial communication by emulation by software, it is possible to use a small-sized and power-saving microcomputer that does not include a serial communication function, so that the power supply control device can be downsized.

      FIG. 2 is a view showing the structure and appearance of a power supply control device according to the first embodiment of the coin-type battery type according to the first embodiment of the present invention. The coin-type battery type power supply control device 12 (hereinafter, referred to as a power supply control device 12) according to the first embodiment has a shape and external dimensions conforming to a coin-type battery standard. The power supply control device 12 includes a top plate 7, a case 8, a circuit board 10, and a bottom plate 11, and the description here is based on the coin-type battery standard CR1616.

The power supply control device 12 has, for example, the same dimensions as the coin-type battery standard CR1616. The top plate 7 is 16 mm, the height of the power supply control device 12 is 1.6 mm, and the height of the power supply control device positive terminal 9 does not exceed 1.6 mm from the top plate 7.
The top plate 7 and the bottom plate 11 are connected to a power control unit of the circuit board 10, and the top plate 7 contacts the negative electrode of the coin-type battery, and the bottom plate 11 contacts the negative electrode of the existing battery box 1. The power control device positive terminal 9 is in contact with the positive electrode of the coin-type battery that is superposed on the power control device 12.

      The power supply control device 12 uses a small microcomputer to keep the size within the coin-type battery standard. Usually, since the acceleration sensor communicates with the microcomputer by a serial communication method such as I2C communication or SPI communication, the microcomputer side also needs a serial communication function. However, if a microcomputer having a communication function is used, the power supply control device cannot be accommodated in the battery box of the existing external device. Therefore, in the present invention, a small-sized and low-power-consumption microcomputer having no communication function is used. As a means of using a small microcomputer without a serial communication function, the power supply control device 12 realizes I2C communication and SPI communication by emulating serial communication with software.

      FIG. 3 shows a configuration in a case where it is housed in a battery box 13 of an external device. Normally, only the coin-type battery is stored in the battery box 13, but in the present invention, the power supply control device 12 including the coin-type battery is stored in the battery box of the external device. Therefore, it is necessary to use a thin coin-type battery in place of the conventional coin-type battery. Regarding how thin the battery should be, it is necessary to use a battery that is thinner by the actual size (thickness) of the power supply controller 12. For example, when a coin-type battery CR1632 is used as a power supply for an existing external device, if the thickness of the coin-type battery is 3.2 mm and the size (thickness) of the power supply control device 12 is within 1.6 mm, For example, CR1616 (thickness 1.6 mm) is used for the coin-type battery, and the size (thickness) is the same as CR1632 by stacking the coin-type battery and the power supply control device 12, and it can be stored in the battery box 13. Will be possible.

      The power supply control device positive terminal 9 contacts the positive electrode of the coin-type battery 16 and the bottom plate 11 contacts the negative electrode of the battery box 13 to secure power and start. The existing circuit 3 is normally supplied with power by contacting the battery box positive terminal 14 and the battery box negative terminal 15, but the power is controlled by the power control unit of the circuit board 10 by contacting the top plate 7 of the power control device 12. Is done.

      The acceleration sensor 5 used in the power supply control device 12 has a motion detection function for determining whether the external device is moving or stationary, and has an active state (a state in which an acceleration exceeding a threshold value is present) and an inactive state (when the threshold value is higher). A logic for detecting a state where the external device is moving or stationary based on the state of the acceleration applied to the external device and outputting a motion detection signal is provided.

      The power consumption of the acceleration sensor 5 in the standby state is extremely small (less than 2 μA), and the battery consumption is small even when the acceleration sensor 5 is operated for a long time. The microcomputer 6 shifts to the sleep state after performing the initialization processing of the acceleration sensor 5. This makes it possible to continue the motion detection function with low power consumption.

      FIG. 4 is a diagram showing an embodiment in which the power supply control device 12 is applied to a smart key of a vehicle which is an example of an external device. When the power supply control device 12 is housed in the battery box 13 of the smart key 17 in the keyless entry system of the vehicle together with the coin-type battery 16, while the smart key 17 as the external device is not used, that is, the stationary state is continuously detected. During this time, the smart key 17 is not powered. When the user holds the smart key 17 to open the door of the vehicle, the power is supplied to the smart key 17 by the motion detection function of the power supply control device 12. By doing so, the smart key 17 operates only when necessary, and the smart key 17 can be stopped when the smart key 17 is not used. That is, a third party cannot use the radio waves of the smart key 17 when the smart key 17 is not possessed.

      FIGS. 5A and 5B are diagrams illustrating an example of a configuration in a case where the power supply control device according to the second embodiment of the present invention is used for a battery box of dry batteries. FIG. 5A shows the appearance of the second embodiment, in which a power supply control device positive terminal 19 is connected by a conductor 18 instead of the power supply control device positive terminal 9 in FIG. FIG. 5B is a diagram showing an example of use of the second embodiment. The power supply control device 12 shown in FIG. 5A is housed in a battery box 20 together with a dry battery 23. The power control device 12 is inserted on the negative electrode 24 side of the battery box 20 and contacts the negative electrode terminal 21 of the battery box and the negative electrode of the dry battery 23. The power supply controller positive terminal 19 is inserted on the positive electrode 25 side of the battery box 20 and contacts the battery box positive terminal 22 and the positive electrode of the dry battery 23. By accommodating in this manner, the power supply control device 12 is supplied with power from the existing battery 23 and can control power supply to existing external devices.

DESCRIPTION OF SYMBOLS 1 Existing battery box 2 Battery 3 Existing device circuit 4 Power supply control unit 5 Acceleration sensor 6 Microcomputer 7 Top plate (negative electrode terminal)
8 Case 9 Power supply control device positive terminal 10 Circuit board 11 Bottom plate (negative terminal)
12 Power Control Device 13 Battery Box 14 Battery Box Positive Terminal 15 Battery Box Negative Terminal 16 Coin Battery 17 Smart Key 18 Conductor 19 Power Control Device Positive Terminal 20 Battery Box 21 Battery Box Negative Terminal 22 Battery Box Positive Terminal 23 Dry Battery 24 Battery Box Negative electrode 25 Battery box positive electrode

Claims (4)

      A power supply control device housed together with a battery in a battery box of an external device, a low-power-consumption acceleration sensor that detects acceleration applied to the external device, and a small-sized microcomputer that performs initialization processing of the acceleration sensor; A power control unit configured to control power supplied from the battery to the external device in accordance with a detection result of the acceleration sensor.       The acceleration sensor has a motion detection function and performs serial communication with the microcomputer.The microcomputer is a small microcomputer without a serial communication function, and emulates serial communication by software processing. 2. The power supply control device according to claim 1, wherein the power supply control device communicates with the acceleration sensor.       The power supply control unit supplies power from the battery to the external device when the acceleration sensor detects acceleration, and shuts off power supply from the battery to the external device when the acceleration sensor does not detect acceleration. The power supply control device according to claim 2, further comprising a circuit. The power supply control device according to claim 3, wherein the external device is a smart key of a vehicle, and the power supply control device is housed in a battery box of the smart key together with a thin coin-type battery.