JP2016139295A - Electronic apparatus, power adapter, and charging system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an electronic apparatus which can protect a USB connector when abnormal electric current is formed in the USB connector, and to provide a power adapter and a charging system.SOLUTION: A first USB connector 5 includes: a metal connector case 21 connectable to a plug case 81; a first terminal 61 connectable to a power line 87; and a second terminal 90 connectable to a ground line 89. A fuse F1 is provided between the connector case 21 and a grand power source.SELECTED DRAWING: Figure 14

Description

  Embodiments of the present disclosure relate to an electronic device, a power adapter, and a charging system.

  Conventionally, a method of charging an electronic device such as a portable terminal using a charging cable is known.

  For example, Patent Document 1 (Japanese Patent Laid-Open No. 2010-282633) discloses a power supply in a power supply by a peripheral bus such as a USB (Universal Serial Bus) supported by a charging cable connecting a host device and an electronic device. Recognizing an adapter and determining available power from a power source via a peripheral bus is disclosed.

JP 2010-282633 A

  However, when seawater or juice adheres to the USB connector, an abnormal current accounting is formed in the USB connector, and the USB connector may generate heat or ignite.

  Therefore, an object of the present disclosure is to provide an electronic device, a power adapter, and a charging system that can protect a USB connector when an abnormal current is formed in the USB connector.

  The electronic device of one embodiment is an electronic device that can be connected to a charging cable. The charging cable includes a power line, a ground line, a metal first plug case provided at one end, a metal second plug case provided at the other end, and a first plug case and a second plug case. And a shield member that shields the power line and the ground line, and the second plug case is connectable to the power adapter. The electronic device includes a first connector that can be connected to a charging cable. The first connector includes a metal outer case connectable to the first plug case, a first terminal connectable to the power line, and a second terminal connectable to the ground line. The electronic device includes an overcurrent protection element provided between the outer case and the ground power source.

  According to an embodiment, the USB connector can be protected when an abnormal current is formed in the USB connector.

It is a figure showing the structure of a charging system. It is a figure showing the structure of a portable terminal. It is a figure showing the external appearance of a portable terminal. It is a figure showing the structure of a power adapter. It is a figure showing the external appearance of a power adapter. It is a figure showing the shape of the USB connector of a portable terminal. It is a figure showing the shape of the USB connector of a power adapter. It is a figure showing the shape of a USB cable. FIG. 6 is a simplified circuit diagram related to power transmission between a USB connector of a mobile terminal, a USB cable, and a USB connector of a power adapter. It is a simple circuit diagram of the system 1 for protecting a 1st USB connector. It is a simple circuit diagram of the system 2 for protecting a 1st USB connector. It is a simple circuit diagram of the system 3 for protecting a 1st USB connector. It is a figure showing the screen notified to a user. FIG. 13 is a more detailed view of the simplified circuit diagram of FIG. 12.

Hereinafter, embodiments of the present invention will be described with reference to the drawings.
In the present embodiment, the USB connector and the USB cable comply with the micro USB standard.

FIG. 1 is a diagram showing a configuration of charging system 800.
The charging system 800 includes a mobile terminal 1, a power adapter 50, and a USB cable 80. The portable terminal 1 and the power adapter 50 can be connected by a USB cable 80. The power from the power adapter 50 connected to the commercial power source 600 is transmitted to the mobile terminal 1 through the USB cable 80, so that the mobile terminal 1 can be charged.

  FIG. 2 is a diagram illustrating a configuration of the mobile terminal 1 which is an example of the electronic apparatus. FIG. 3 is a diagram illustrating the appearance of the mobile terminal 1.

  With reference to FIG. 2, this portable terminal 1 includes a receiver 7, a camera 8, a microphone 98, a proximity distance sensor 6, a touch panel 12, a liquid crystal display 13, a button group 15, a battery 16, and a control. Unit 17, USB terminal unit 18, wireless communication unit 31, and antenna 32. The USB terminal unit 18 includes a USB control unit 19 and a first USB connector 5.

The button group 15 accepts user instruction operations for various processes.
The battery 16 supplies power to the components in the mobile terminal 1.

The control unit 17 controls the entire mobile terminal 1.
The USB control unit 19 controls USB communication.

The first USB connector 5 can be connected to the USB cable 80.
The radio communication unit 31 communicates with the radio base station through the antenna 32.

The liquid crystal display 13 displays a screen output from the control unit 17.
The touch panel 12 receives input from the user.

  The receiver 7 outputs the other party's voice or music data voice output from the control unit 17.

The camera 8 photographs a subject.
The microphone 98 receives the voice of the other party and outputs it to the control unit 17.

  The proximity distance sensor 6 detects the presence of a nearby object without contact. The proximity distance sensor 6 detects that the liquid crystal display 13 is brought close to the face, for example.

  As shown in FIG. 3, the first USB connector 5 is disposed at the lower part of the housing 2 of the mobile terminal 1.

  The receiver 7, the camera 8, and the proximity distance sensor 6 are disposed on the upper part of the front surface of the housing 2 of the mobile terminal 1. The liquid crystal display 13 and the touch panel 12 are arranged in the center of the front surface of the housing 2 of the mobile terminal 1. A touch panel 12 is disposed on the liquid crystal display 13.

  The buttons 15 </ b> A, 15 </ b> B, and 15 </ b> C are disposed on the lower part of the front surface of the housing 2 of the mobile terminal 1. The button 15 </ b> D is arranged on the upper side of the side surface of the housing 2 of the mobile terminal 1. The button 15 </ b> C is disposed on the side of the side surface of the housing 2 of the mobile terminal 1. The button 15A is a home button. The button 15B is a back button. The button 15C is a menu button. The button 15D is a power on / off button. The button 15E is a volume up button. The button 15F is a volume down button. The first USB connector 5 is disposed below the side surface of the casing of the mobile terminal 1. The microphone 98 is disposed in the lower part of the front surface of the housing 2 of the mobile terminal 1.

  FIG. 4 is a diagram showing the configuration of the power adapter 50. FIG. 5 is a diagram illustrating the appearance of the power adapter 50.

  As shown in FIG. 4, the power adapter 50 includes a power plug 59, an AC / DC converter 54, a control unit 553, and a USB terminal unit 55. The USB terminal unit 55 includes a USB control unit 56 and a second USB connector 51.

The power plug 59 can be inserted into a household AC power outlet 121.
The AC / DC converter 54 converts the AC voltage input through the AC power outlet 121 and the power plug 59 into a DC voltage.

The USB control unit 56 controls USB communication.
The second USB connector 51 can be connected to the USB cable 80.

The control unit 553 controls the AC / DC converter 54 and the USB terminal unit 55.
FIG. 6 is a diagram illustrating the shape of the first USB connector 5 of the mobile terminal 1.

  As shown in FIG. 6, the first USB connector 5 includes a metal connector case 20 and a connector body 22 disposed in the connector case 20.

  The connector case 20 functions as a fitting between the USB connector 5 and the USB cable 80, strengthening the strength of the USB connector 5 by mounting on the board, suppressing noise radiation, and a lightning arrester for ESD (Electrostatic Discharge).

  The connector body 22 includes a plurality of conductive terminals 61 to 64. The plurality of terminals 61 to 64 are connected to the wiring patterns 251 to 254 on the circuit board 21 on the rear side of the first USB connector 5, respectively.

  The power supply terminal 61 is connected to the power wiring pattern 251. The positive signal terminal 62 is connected to the positive signal wiring pattern 252. The negative signal terminal 63 is connected to the negative signal wiring pattern 253. The ground terminal 64 is connected to the ground wiring pattern 254.

  The power wiring pattern 251 is a power feeding wiring pattern, and is connected to the positive power supply voltage VBUS. The positive signal wiring pattern 252 is a wiring pattern for signal transmission, and transmits the positive side D + of the differential signal output from the USB control unit 19. The negative signal wiring pattern 253 is a wiring pattern for signal transmission, and the negative side D− of the differential signal output from the USB control unit 19 is transmitted. The ground wiring pattern 254 is a power feeding wiring pattern and is connected to a ground power supply.

  Among the plurality of terminals 61 to 64, the power supply terminal 61 is closer to the connector case 20 than the other terminals.

  The connector case 20 is connected to the ground wiring pattern 254 through the wiring pattern 255. With such a configuration, the connector body 22 is shielded from external noise and electromagnetic waves.

FIG. 7 is a diagram illustrating the shape of the second USB connector 51 of the power adapter 50.
As shown in FIG. 7, the second USB connector 51 includes a metal connector case 52 and a connector main body 53 disposed in the connector case 52. The connector main body 53 includes a plurality of conductive terminals 71 to 74. The plurality of terminals 71 to 74 are connected to the wiring patterns 151 to 154 on the circuit board 54 on the rear side of the second USB connector 51, respectively.

  The power supply terminal 71 is connected to the power wiring pattern 151. The positive signal terminal 72 is connected to the positive signal wiring pattern 152. The negative signal terminal 73 is connected to the negative signal wiring pattern 153. The ground terminal 74 is connected to the ground wiring pattern 154.

  The power wiring pattern 151 is a power supply wiring pattern, and is connected to the positive power supply voltage VBUS. The positive signal wiring pattern 152 is a signal transmission wiring pattern, and the positive side D + of the differential signal output from the USB control unit 56 is transmitted. The negative signal wiring pattern 153 is a wiring pattern for signal transmission, and the negative side D− of the differential signal output from the USB control unit 56 is transmitted. The ground wiring pattern 154 is a power supply wiring pattern and is connected to a ground power supply.

  Among the plurality of terminals 71 to 74, the power terminal 71 is closer to the connector case 51 than the other terminals.

  The connector case 51 is connected to the ground wiring pattern 154 through the wiring pattern 155. With such a configuration, the connector main body 53 is shielded from external noise and electromagnetic waves.

FIG. 8 is a diagram showing the shape of the USB cable 80.
As shown in FIG. 8, the USB cable 80 includes a plug unit 500 that can be connected to the mobile terminal 1, a cable unit 510, and a plug unit 520 that can be connected to the power adapter 50.

  The plug part 500 includes a metal plug case 81, a plug body 82 installed in the plug case 81, and an insulating film part 83 connected to one end side of the plug case 81.

  The plug part 520 includes a metal plug case 92, a plug main body 93 installed in the plug case 92, and an insulating film part 91 connected to one end side of the plug case 92.

  The cable portion 510 includes a shield tube 86 that is a metal shield member, an insulating tube 85, a positive signal line 88, a negative signal line 89, a power line 87, and a ground line 90.

  The metal shield tube 86 is electrically connected to the plug case 81 and the plug 92.

The insulating tube 85 insulates the shield tube 86.
The positive signal line 88, the negative signal line 89, the power line 87, and the ground line 90 are disposed in the shield tube 86.

  The shield tube 86 is electrically connected to the connector case 20 of the first USB connector 5 of the mobile terminal 1 via the plug case 81 and is kept at the ground (GND) reference potential. The shield tube 86 is electrically connected to the connector case 52 of the second USB connector 51 of the power adapter 50 via the plug case 92 and is kept at the ground (GND) reference potential. With such a configuration, the positive signal line 88 and the negative signal line 89 are shielded from noise and electromagnetic waves.

  Hereinafter, a mechanism in which an overcurrent is generated when seawater or juice or the like adheres to the first USB connector 5 of the mobile terminal 1 and a mechanism that can be considered to protect the USB connector from the overcurrent will be described.

  FIG. 9 is a simplified circuit diagram relating to power transmission between the first USB connector 5 of the portable terminal, the USB cable 80, and the second USB connector 51 of the power adapter 50.

  In the figure, CASE_GND is a wiring pattern 255 of the portable terminal 1, a connector case 20 of the first USB connector 5, a shield tube 86 of the USB cable 80, a connector case 52 of the second USB connector 51 of the power adapter 50, and a wiring pattern. 155 represents a connected line.

  VBUS includes a power wiring pattern 251 of the portable terminal 1, a power terminal 61 of the first USB connector 5 of the portable terminal 1, a power line 87 of the USB cable 80, a power terminal 71 of the second USB connector 51 of the power adapter 50, a power source. The line to which the power wiring pattern 151 of the adapter 50 is connected is shown.

  The GND includes a ground wiring pattern 254 of the mobile terminal 1, a ground terminal 64 of the first USB connector 5 of the mobile terminal 1, a ground line 90 of the USB cable 80, a ground terminal 74 of the second USB connector 51 of the power adapter 50, This represents a line to which the ground wiring pattern 154 of the power adapter 50 is connected.

  As shown in FIG. 9, CASE_GND is connected to GND on the portable terminal 1 side and the power adapter 50 side.

  When seawater or juice or the like adheres to the first USB connector 5 of the mobile terminal 1, an abnormal path is formed between the power supply terminal 61 of the first USB connector 5 of the mobile terminal 1 and the connector case 20. As a result, as shown in the figure, VBUS and CAEE_GND are connected via a resistor, and an overcurrent flows through the path VBUS → CASE → GND → GND. As a result, the first USB connector 5 may generate heat or ignite.

  In order to protect the first USB connector 5, two schemes of FIG. 10 and FIG. 11 can be considered first.

  FIG. 10 is a simplified circuit diagram of method 1 for protecting the first USB connector 5. As shown in FIG. 10, a fuse is inserted as an overcurrent protection element into the power line 87 of the USB cable 80. When an overcurrent occurs, the fuse is melted and the power line 87 is cut off.

  However, in the method of FIG. 10, if the fuse is blown, there is a possibility that the portable terminal 1 cannot be charged again. In this case, the user cannot know why the mobile terminal 1 has become unchargeable. Unless a USB cable with a fuse or polyswitch inserted in the power line 87 is used, overcurrent cannot be prevented.

FIG. 11 is a simplified circuit diagram of method 2 for protecting the first USB connector 5.
As shown in FIG. 11, when a thermistor (temperature sensor) is installed in the immediate vicinity of the first USB connector 5 and an overcurrent occurs and the temperature of the USB connector rises, the user is notified that an abnormal state has occurred. .

  However, in FIG. 11, since the overcurrent state cannot be resolved, the mobile terminal 1 cannot be charged. Since the overcurrent state cannot be resolved, there is a risk of heat generation and ignition if the user leaves it alone. Temperature monitoring and control using a thermistor is necessary, and current consumption may increase.

  Each of the methods shown in FIGS. 10 and 11 has advantages and disadvantages, and should be used properly according to the situation.

  FIG. 12 is a simplified circuit diagram for protecting the first USB connector 5 by a method different from that shown in FIGS. FIG. 12 is a simplified circuit diagram of method 3.

  On the mobile terminal 1 side, a fuse F1 is inserted into CASE_GND. Specifically, a fuse F <b> 1 is inserted as an overcurrent protection element on the wiring pattern 255 that connects the connector case 20 and the ground wiring pattern 254. Also on the power adapter 50 side, a fuse F2 is inserted into CASE_GND. Specifically, a fuse F2 is inserted as an overcurrent protection element on the wiring pattern 155 that connects the connector case 51 and the ground wiring pattern 154.

  When an overcurrent occurs in CASE_GND due to the formation of an abnormal path, fuses F1 and F2 are blown, and CASE_GND is disconnected from GND. As a result, the overcurrent is eliminated, and there is no fear of heat generation or ignition of the first USB connector 5. Furthermore, since the normal charging path is maintained, the mobile terminal 1 can be charged.

  A node ND1 between the connector case 20 and the fuse F1 is connected to the control unit 17 via the resistor R1. The wiring between the control unit 17 and the resistor R1 is connected to the power supply voltage VDD.

  When the fuses F1 and F2 are normal, the node ND1 is connected to GND, so the voltage at the node ND1 is approximately 0V.

  When an overcurrent occurs in CASE_GND and the fuses F1 and F2 are blown, the connection between the nodes ND and GND is cut off, and the voltage at the node ND1 becomes the power supply voltage VDD. Therefore, as shown in FIG. 13, when the voltage at the node ND1 is equal to or higher than the predetermined threshold voltage VH, the control unit 17 attaches seawater or juice to the first USB connector 5 to form an abnormal path. Tell the user that

FIG. 14 is a more detailed view of the simplified circuit diagram of FIG.
As shown in FIG. 14, the shield tube 86 is connected to the plug case 81 and the plug case 92.

  The terminals 41 to 44 of the plug case 81 are connected to the power line 87, the positive signal line 88, the negative signal line 89, and the ground line 90. The terminals 141 to 144 of the plug case 92 are connected to the power line 87, the positive signal line 88, the negative signal line 89, and the ground line 90.

  The terminals 41 to 44 of the plug case 81 are connected to the terminals 61 to 64 of the connector case 21, respectively. The terminal 41 is connected to the battery 16. The terminal 44 is connected to the ground through the wiring 255. A fuse F <b> 1 is disposed between the node ND <b> 2 on the wiring 255 and the connector case 20. A node ND1 between the connector case 20 and the fuse F1 is connected to the control unit 17 via a resistor R1. The resistor R1 is connected to the power supply voltage VDD.

  Terminals 141 to 144 of plug case 92 are connected to terminals 71 to 74 of connector case 52, respectively. Terminal 141 is connected to AC / DC converter 54. The terminal 144 is connected to the ground through the wiring 155. A fuse F2 is arranged between the node ND3 on the wiring 155 and the connector case 51.

  As described above, according to method 3, when an abnormal current is formed in the USB connector, the fuse between the connector case and the ground is melted to prevent the USB connector from being heated or ignited. can do. Further, since the normal charging path is maintained, the mobile terminal can be charged. Furthermore, it is possible to notify the user that an abnormal current has occurred and the connection between the connector case and the ground has been cut off.

  In addition, according to the method 3, since the connection between the connector case and the ground is cut, the role of the connector case loses the suppression of noise radiation and the role of the ESD lightning rod, but charging of the mobile terminal, data It does not cause a fatal loss in the transfer.

(Modification)
The present embodiment is not limited to the above-described embodiment, and includes, for example, the following modifications.

(1) Polyswitch In the above embodiment, the fuse is used as the overcurrent protection element, but the present invention is not limited to this. For example, a poly switch may be used instead of the fuse.

(2) Charging cable Although the USB cable is used as the charging cable in the above embodiment, the present invention is not limited to this. A power line, a ground line, a metal first plug case provided at one end, a second plug case provided at the other end, and the first plug case and the second plug case; A charging cable including a shield member that shields the ground wire can be used.

  The embodiment disclosed this time should be considered as illustrative in all points and not restrictive. The scope of the present invention is defined by the terms of the claims, rather than the description above, and is intended to include any modifications within the scope and meaning equivalent to the terms of the claims.

  DESCRIPTION OF SYMBOLS 1 Mobile terminal, 2 housing | casing, 5 1st USB connector, 6 Proximity sensor, 7 Receiver, 8 Camera, 12 Touch panel, 13 Liquid crystal display, 15 button group, 15A Home button, 15B Back button, 15C Menu button, 15D Power ON / OFF button, 15E Volume up button, 15F Volume down button, 16 Battery, 17, 18, 55 USB terminal unit, 19, 56 USB control unit, 20, 52 Connector case, 22, 53 Connector body, 31 Wireless communication Part, 32 antennas, 41 to 44, 141 to 144 terminals, 50 power adapter, 51 USB connector, 54 AC / DC converter, 59 power plug, 61, 71 power terminal, 62, 72 positive signal terminal, 63, 73 negative signal Terminal, 64, 74 ground terminal, 0 USB cable, 81, 92 plug case, 82, 93 plug body, 83, 91 insulation film part, 85 insulation tube, 86 shield tube, 87 power line, 88 positive signal line, 89 negative signal line, 90 ground line, 98 microphone, 121 AC power outlet, 151,251 power wiring pattern, 152,252 positive signal wiring pattern, 153,253 negative signal wiring pattern, 154,254 ground wiring pattern, 155,255 wiring pattern, 500,520 plug part, 510 cable unit, 553 control unit, 800 charging system.

Claims (14)

An electronic device that can be connected to a charging cable,
The charging cable includes a power line, a ground line, a metal first plug case provided at one end, a metal second plug case provided at the other end, and the first plug case and the second plug case. And a shield member that shields the power line and the ground line, and the second plug case is connectable to a power adapter,
The electronic device is
A first connector connectable to the charging cable;
The first connector is:
A metal outer case connectable to the first plug case;
A first terminal connectable to the power line;
A second terminal connectable to the ground line,
An electronic device comprising an overcurrent protection element provided between the outer case and a ground power source. A power source connected to a node between the outer case and the overcurrent protection element;
The electronic device according to claim 1, further comprising: a control unit that notifies that the connection between the outer case and the ground is disconnected when the voltage of the node is equal to or higher than a threshold value. The charging cable further includes a positive signal transmission line constituting a differential signal and a negative signal transmission line constituting a differential signal,
The first connector is:
A third terminal connectable to the positive signal transmission line;
The electronic device according to claim 1, further comprising a fourth terminal connectable to the negative signal transmission line.   The electronic device according to claim 3, wherein the first terminal is closer to the exterior case than the second terminal, the third terminal, and the fourth terminal. The charging cable is a USB cable;
The electronic device according to claim 4, wherein the first connector is a USB connector.   The electronic device according to claim 1, wherein the overcurrent protection element is a fuse.   The electronic device according to claim 1, wherein the overcurrent protection element is a polyswitch. A power adapter that can be connected to a charging cable,
The charging cable includes a power line, a ground line, a metal first plug case provided at one end, a metal second plug case provided at the other end, and the first plug case and the second plug case. And a shield member that shields the power line and the ground line, and the first plug case is connectable to an electronic device.
The power adapter is
A second connector connectable to the charging cable;
The second connector is
A metal outer case connectable to the second plug case;
A first terminal connectable to the power line;
A second terminal connectable to the ground line,
A power adapter comprising an overcurrent protection element provided between the outer case and a ground power source. The charging cable further includes a positive signal transmission line constituting a differential signal and a negative signal transmission line constituting a differential signal,
The second connector is
A third terminal connectable to the positive signal transmission line;
The power adapter according to claim 8, further comprising a fourth terminal connectable to the negative signal transmission line.   The power adapter according to claim 9, wherein the first terminal is closer to the exterior case than the second terminal, the third terminal, and the fourth terminal. The charging cable is a USB cable;
The power adapter according to claim 10, wherein the second connector is a USB connector.   The power adapter according to claim 8, wherein the overcurrent protection element is a fuse.   The power adapter according to claim 8, wherein the overcurrent protection element is a polyswitch. A charging system including an electronic device connectable to a charging cable and a power adapter,
The charging cable includes a power line, a ground line, a metal first plug case provided at one end, a metal second plug case provided at the other end, and the first plug case and the second plug case. A shield member connected to the plug case and shielding the power line and the ground line,
The electronic device is
A first connector connectable to the charging cable;
The first connector is:
A metal outer case connectable to the first plug case;
A first terminal connectable to the power line;
A second terminal connectable to the ground line,
An overcurrent protection element provided between the outer case and a ground power source;
The power adapter is
A second connector connectable to the charging cable;
The second connector is
A metal outer case connectable to the second plug case;
A first terminal connectable to the power line;
A second terminal connectable to the ground line,
A charging system comprising an overcurrent protection element provided between the outer case and a ground power source.

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