巴西专利BR112014017612B1 LOADING CHARGER, LOADING TERMINAL, LOADING SYSTEM AND CONTROL METHOD FOR LOADING

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专利摘要:
charger, charging terminal, charging system and control method for charging. the present disclosure discloses a charger, a charging terminal, a charging system and a control method for charging. by using a charger's first data signal port to obtain a feedback signal from the charging terminal, the voltage drop across a usb wire between the terminal and the charger will be eliminated, so a voltage 5 ± 5% v charging capacity can be obtained from the charging terminal. thus, a high-voltage battery can be quickly charged with a constant current.
公开号:BR112014017612B1
申请号:R112014017612-4
申请日:2014-05-08
公开日:2021-08-24
发明作者:Wei Sun；Hongtu Cui；Guoquan Zhang；Ji Yu
申请人:Xiaomi Inc；
IPC主号:

专利说明:

[001] This application is based on and claims priority benefit of Chinese Patent Application No. 201310462373.6, filed September 30, 2013, the entire contents of which are incorporated herein by reference. TECHNICAL FIELD
[002] The present disclosure generally relates to a field of terminal charging technology, and more particularly, to a charger, a charging terminal, a charging system and a control method for charging. FUNDAMENTALS
[003] An output voltage of a charger specified by a national standard is 5 ± 5%V and 4.74V-5.25V. A Universal Serial Bus (USB) wire for connecting a mobile phone to a charger itself has a resistance of, generally 0.20 for an excellent USB wire, and 0.3-0.40 for an ordinary one. So, in a case where a charging current is 1A, a voltage drop across a USB wire will be more than or equal to 0.2V. voltage on a PCB, an input voltage to a mobile phone charging management chip will be less than 4.7V. That is, the voltage actually emitted from the charger to the mobile phone charge management chip does not meet the standard specified by the international standard.
[004] Generally, under charging management with an efficiency of 99%, a 4.2V mobile phone battery can be charged to 4.2V in a fast charging phase (1A of a charging current), in the However, for a 4.35V high voltage battery, it cannot be charged to 4.35V in the fast charging phase because the input voltage to the charging management chip cannot reach about 4.85V. SUMMARY
[005] A charger, a charging terminal, a charging system and a charging control method are provided by embodiments of the present disclosure, which are configured to eliminate the voltage drop across a USB wire between the terminal and the charger , such that a charging voltage of 5 ± 5% V can be obtained at the terminal charging management chip's voltage input port.
[006] In one aspect, a charger is provided by the present disclosure, which includes: a power supply device, a first charging port, a first charge control device, and a first switching device;
[007] the power supply device is configured to emit a DC charging current by rectifying and reducing voltage of an input AC charging current; the power supply device includes at least one voltage output port and a feedback receiving port; the voltage output port is configured to output DC charging current; the feedback receiving port is configured to receive a feedback signal to adjust the output DC charging current;
[008] the first charging port is configured to connect with a charging terminal, to output the output DC charging current to the charging terminal; the first loading port includes at least a first power supply port and a first data signal port; the first power supply port which is connected with the voltage output port, is configured to output the DC charging current;
[009] the first switching device that is provided between the return receiving port and the first loading port, is configured to control the return receiving port to be connected with the first power supply port or the first port of data signal according to the first charge control device.
[010] Some of the advantages of the present disclosure may include: by using the charger's first data signal port to obtain the return signal from the charging terminal, the voltage drop across the USB wire between the terminal and the charger will be eliminated, such that a charging voltage of 5 ± 5% V can be obtained from the charging terminal. Thus, a high voltage battery can be quickly charged with a constant current.
[011] The charger has a proximal return state and a distal return state;
[012] when the charger is in the proximal return state, the first switching device controls the return receiving port to be connected with the first power supply port according to the first charge control device;
[013] when the charger is in the distal return state, the first switching device controls the return receiving port to be connected with the first data signal port according to the first charge control device.
[014] Once at a start of a charging operation, the charging terminal needs to determine the type of a charger through a connection state with the first data signal port of the charger, at this time, the charger cannot get the feedback signal through the data signal port, but only get the feedback signal through the first power supply port of the charger. When the charging terminal is informed about the charger type, the data signal port between the charging terminal and the charger is free, so the feedback signal can be transmitted through the charging terminal's data signal ports and the charger. Some of the advantages of the present disclosure may include: by defining two states for the charger, by the time the charger's normal charging operation is ensured, the voltage drop across the USB wire between the terminal and the charger will be eliminated, such that a charging voltage of 5 ± 5% V can be obtained from the charging terminal. Thus, the high voltage battery can be quickly charged with a constant current.
[015] The first data signal port includes a D+ port and a D- port;
[016] When the charger is in the distal return state, the first switching device controls the return receiving port to be connected with the D+ port or the D- port according to the first charge control device.
[017] Some of the advantages of the present disclosure may include: by using the D+ port or the D- port of the charger to transmit the return signal from the charge management chip from the terminal to the charger, the voltage drop across the USB wire between the terminal and the charger will be eliminated, so that a charging voltage of 5 ± 5%V can be obtained at the voltage input port of the terminal's charge management chip. Thus, the high voltage battery can be quickly charged with a constant current.
[018] The first charge control device is configured to control the charger to be in the proximal return state when a charge operation is initiated, and control the charger to be in the distal return state when an operation duration time of charging exceeds a preset time delay.
[019] Some of the advantages of the present disclosure may include: by monitoring the duration of the charging operation, whether the charger is in the proximal return state or the distal return state can be determined in order to receive the return signal from different ports. By getting the feedback signal from the charging terminal ports, the voltage drop across the USB wire between the terminal and the charger will be eliminated, so that a charging voltage of 5 ± 5% V can be obtained at the voltage input port of the terminal charge management chip. Thus, the high voltage battery can be quickly charged with a constant current.
[020] The first charging port is either a USB interface or a Micro USB interface.
[021] If the first charging port is a USB interface or a Micro USB interface, the feedback signal can be obtained from the charging terminal by solving the above modalities, to eliminate the voltage drop across the USB wire between the terminal and the charger, such that a charging voltage of 5 ± 5% V can be obtained at the voltage input port of the charging management chip of the terminal. Thus, the high voltage battery can be quickly charged with a constant current.
[022] In another aspect, a charging terminal is provided by the present disclosure, which includes: a charging management chip, a second charging port, a second switching device, and a second charging control device;
[023] the charge management chip is configured to receive an input DC charge current to charge the charge terminal; the charge management chip includes at least one voltage input port and one chip data port; the voltage input port is configured to input DC charging current;
[024] the second charging port is configured to connect with the charger to receive the DC charging current that is input from the charger; the second charging port includes at least a second power supply port and a second data signal port; the second power supply port is connected with the voltage input port, it is configured to output the DC charging current to the charging management chip;
[025] the second switching device which is provided between the charge management chip and the second charge port, is configured to control the second data signal port to be connected with the voltage input port or the charge port. chip data according to the second charge control device.
[026] Some of the advantages of the present disclosure may include: by using the charging terminal's second data signal port to transmit the return signal to the charger, the voltage drop across a USB wire between the terminal and the charger will be eliminated, such that a charging voltage of 5 ± 5% V can be obtained at the terminal charging management chip's voltage input port. Thus, the high voltage battery can be quickly charged with a constant current.
[027] The loading terminal has a proximal return state and a distal return state;
[028] when the loading terminal is in the proximal feedback state, the second switching device controls the second data signal port to be connected with the chip data port according to the second loading control device;
[029] When the charging terminal is in the distal return state, the second switching device controls the second data signal port to be connected with the voltage input port according to the second charging control device.
[030] Once at a start of a charging operation, the charging terminal needs to determine the type of a charger through the connection state of its second data signal port with the first data signal port of the charger, At this time, the charger cannot send the feedback signal through the data signal port, and the charger can only get the feedback signal through the first power supply port of the charger. When the charging terminal is informed about the charger type, the data signal port between the charging terminal and the charger is free, so the feedback signal can be transmitted through the charging terminal's data signal ports and the charger. Some of the advantages of the present disclosure may include: by defining two states for the charging terminal, by the time the charger's normal charging operation is ensured, the voltage drop across the USB wire between the terminal and the charger will be eliminated , such that a charging voltage of 5 ± 5% V can be obtained from the charging terminal. Thus, the high voltage battery can be quickly charged with a constant current.
[031] The second data signal port includes a D+ port and a D- port;
[032] when the load terminal is in the proximal return state, the second switching device controls the D+ gate or the D- gate to be connected with the chip data port according to the second load control device;
[033] When the charge terminal is in the distal return state, the second switching device controls the D+ port or the D- port to be connected with the voltage input port according to the second charge control device.
[034] Some of the advantages of the present disclosure may include: by using the terminal's D+ or D-port to transmit the feedback signal from the terminal's charge management chip to the charger, the voltage drop across the USB wire between the terminal and the charger will be eliminated, so that a charging voltage of 5 ± 5%V can be obtained at the voltage input port of the terminal's charge management chip. Thus, the high voltage battery can be quickly charged with a constant current.
[035] The second charge control device is configured to control the charge terminal to be in the proximal return state when a charge operation is initiated, and control the charge terminal to be in the distal return state when a time of duration of the loading operation exceeds a preset time delay.
[036] Some of the advantages of the present disclosure may include: by monitoring the duration of the loading operation, whether the loading terminal is in the proximal return state or the distal return state can be determined in order to transmit the signal return to the charger. By getting the feedback signal from the charging terminal, the voltage drop across the USB wire between the terminal and the charger will be eliminated, so that a charging voltage of 5 ± 5% V can be obtained at the charging port. voltage input from the terminal's charge management chip. Thus, the high voltage battery can be quickly charged with a constant current.
[037] The second charging port is either a USB interface or a Micro USB interface.
[038] If the second charging port is a USB interface or a Micro USB interface, the feedback signal can be obtained from the charging terminal by solving the above modalities, to eliminate the voltage drop across the USB wire between the terminal and the charger, such that a charging voltage of 5 ± 5% V can be obtained at the voltage input port of the charging management chip of the terminal. Thus, the high voltage battery can be quickly charged with a constant current.
[039] In another aspect, a charging system is provided by the present disclosure, which includes: a charger and a charging terminal; the charger is connected with the charging terminal, so the charger charges the charging terminal;
[040] the charger includes a power supply device, a first charging port, a first charge control device and a first switching device;
[041] the power supply device is configured to emit a DC charging current by rectifying and reducing voltage of an input AC charging current; the power supply device includes at least one voltage output port and a feedback receiving port; the voltage output port is configured to output DC charging current; the feedback receiving port is configured to receive a feedback signal to adjust the output DC charging current;
[042] the first charging port is configured to connect with a charging terminal, to output the output DC charging current to the charging terminal; the first loading port includes at least a first power supply port and a first data signal port; the first power supply port which is connected with the voltage output port, is configured to output the DC charging current;
[043] the first switching device that is provided between the return receiving port and the first loading port, is configured to control the return receiving port to be connected with the first power supply port or the first port data signal according to the first charge control device;
[044] the charging terminal includes: a charging management chip, a second charging port, a second charging control device and a second switching device;
[045] the charging management chip is configured to receive the input DC charging current to charge the charging terminal; the charge management chip includes at least one voltage input port and one chip data port; the voltage input port is configured to input DC charging current;
[046] the second charging port is configured to connect with the charger to receive the DC charging current that is input from the charger; the second charging port includes at least a second power supply port and a second data signal port; the second power supply port is connected with the voltage input port, it is configured to output the DC charging current to the charging management chip;
[047] the second switching device which is provided between the charge management chip and the second charge port, is configured to control the second data signal port to be connected with the voltage input port or the charge port. chip data according to the second charge control device.
[048] The loading system has a proximal return state and a distal return state;
[049] when the charging system is in the proximal return state, the first switching device controls the return receiving port to be connected with the first power supply port according to the first charge control device; and the second switching device controls the second data signal port to be connected with the chip data port according to the second charge control device;
[050] when the loading system is in the distal feedback state, the first switching device controls the feedback receiving port to be connected with the first data signal port according to the first loading control device; and the second switching device controls the second data signal port to be connected with the voltage input port according to the second charge control device.
[051] Each of the first data signal port and the second data signal port includes a D+ port and a D- port;
[052] when the charging system is in the proximal return state, the second switching device controls the D+ gate to be connected with the chip data port according to the second charging control device;
[053] when the load terminal is in the distal feedback state, the first switching device controls the feedback receiving port to be connected with the D+ port according to the first load control device; and the second switching device controls the D+ gate to be connected with the voltage input port according to the second charge control device;
[054] or,
[055] when the charging system is in the proximal return state, the second switching device controls the D-gate to be connected with the chip data port according to the second charging control device;
[056] when the loading terminal is in the distal feedback state, the first switching device controls the feedback receiving port to be connected with the D-port according to the first loading control device; and the second switching device controls the gate D- to be connected with the voltage input gate according to the second charge control device.
[057] The first charge control device is configured to control the charger to be in the proximal return state when a charge operation is initiated, and control the charger to be in the distal return state when an operation duration time of charging exceeds a preset time delay;
[058] the second charge control device is configured to control the charge terminal to be in the proximal return state when the charge operation is started, and control the charge terminal to be in the distal return state when the time of duration of loading operation exceeds a given time delay;
[059] The preset time delay for the first charge control device and the second charge control device are the same.
[060] The first charging port is a USB interface or a Micro USB interface; and the second charging port is a USB interface or a Micro USB interface.
[061] In another aspect, a control method for loading is provided, which is implemented based on the above loading system. The control method for loading includes:
[062] when a loading operation is initiated, controlling the loading system to be in the proximal return state; and when the charging system is in the proximal return state, controlling the receiving return port to be connected with the first power supply port according to the first charging control device by the first switching device of the charger; and controlling the second data signal port to be connected with the chip data port according to the second charge control device by the second charge terminal switching device;
[063] determine whether a loading operation duration time exceeds a given time delay;
[064] when charging operation duration time exceeds preset time delay, control charging system to be in the distal return state; and when the loading system is in the distal feedback state, controlling the feedback receiving port to be connected with the first data signal port according to the first loading control device by the first switching device, and controlling the second data signal port to be connected with the voltage input port according to the second charge control device by the second switching device. Each of the first and second data signal ports includes a D+ port and a D- port;
[065] when the charging system is in the proximal return state, the second switching device controls the D+ gate to be connected with the chip data port according to the second charging control device;
[066] when the loading terminal is in the distal feedback state, the first switching device controls the feedback receiving port to be connected with the D+ port according to the first loading control device; and the second switching device controls the D+ gate to be connected with the voltage input port according to the second charge control device;
[067] or,
[068] when the charging system is in the proximal return state, the second switching device controls the D-gate to be connected with the chip data port according to the second charging control device;
[069] when the loading terminal is in the distal feedback state, the first switching device controls the feedback receiving port to be connected with the D-port according to the first loading control device; and the second switching device controls the gate D- to be connected with the voltage input gate according to the second charge control device.
[070] It should be noted that, the above general description and the following detailed description are merely exemplary, and do not limit disclosure.
[071] The solution of the present disclosure will be described in greater detail with reference to the accompanying drawings and modalities. BRIEF DESCRIPTION OF THE DRAWINGS
[072] The accompanying drawings that constitute a part of the description are provided for a better understanding of the present disclosure, and serve to explain the present disclosure in conjunction with embodiments of the present disclosure, but are not a limitation to the present disclosure, in which:
[073] Figure 1 is an exemplary block diagram showing a loader;
[074] Figure 2 is an exemplary block diagram showing a loading terminal;
[075] Figure 3 is an exemplary block diagram showing a loading system;
[076] Figure 4 is an exemplary flowchart showing a control method for loading;
[077] Figure 5 is another exemplary block diagram showing a loading system;
[078] Figure 6 is another exemplary block diagram showing a loading system.
[079] Explicit embodiments of the present disclosure that have been illustrated in the accompanying drawings above will be described in more detail below. These accompanying drawings and literal description are in no way intended to limit the scope of the idea of the present disclosure, but to explain the concept of the present disclosure to those skilled in the art with reference to particular embodiments. DETAILED DESCRIPTION
[080] In order to make the objectives, technical solutions and advantages clearer, the present disclosure will be described in more detail with reference to the modalities and the attached drawings. Here, the illustrative embodiments of the present disclosure and description thereof are not intended to limit the present disclosure, but to explain the present disclosure.
[081] A charger, a charging terminal, a charging system and a charging control method are provided by embodiments of the present disclosure, which will be described in detail with reference to the accompanying drawings designated below.
[082] In one embodiment as shown in Figure 1, a charger 10 includes a power supply device 11, a first charging port 12, a first switching device 13 and a first charge control device 14,
[083] The power supply device 11 is configured to emit a DC charging current by rectifying and reducing voltage from an incoming AC charging current. The power supply device 11 includes at least one voltage output port 111 and a return receiving port 112. The voltage output port 111 is configured to output the DC charging current. The feedback receiving port 112 is configured to receive a feedback signal to adjust the output DC charging current.
[084] The first charging port 12 is configured to connect with a charging terminal, to output the output DC charging current to the charging terminal. The first loading port 12 includes at least a first power supply port 121 and a first data signal port 122. The first power supply port 121, which is connected with the voltage output port 111, is configured to transmit the DC charging current.
[085] The first switching device 13, which is provided between the receiving return port 112 and the first loading port 12, is configured to control the receiving return port 112 to be connected with the first receiving source port. feed 121 or the first data signal port 122 according to the first charge control device 14.
[086] In this mode, by using the charger's first data signal port to obtain the return signal from the charging terminal, a voltage drop across a USB wire between the terminal and the charger will be eliminated, from so that a charging voltage of 5 ± 5% V can be obtained from the charging terminal. Thus, a high voltage battery can be quickly charged with a constant current.
[087] Loader 10 has a proximal return state and a distal return state. When the charger is in the proximal return state, the first switching device 13 controls the return receiving port 112 to be connected with the first power supply port 121 according to the first charge control device 14. When the loader is in the distal feedback state the first switching device 13 controls the feedback receiving port 112 to be connected with the first data signal port 122 according to the first loading control device 14.
[088] Once at a start of a charging operation, the charging terminal needs to determine the type of a charger through a connection state with the first data signal port of the charger, at this time, the charger cannot get the feedback signal through the data signal port, but only get the feedback signal through the first power supply port of the charger. When the charging terminal is informed of the charger type, the charging terminal and charger data signal ports are free, thus the feedback signal can be transmitted through the charging terminal data signal ports and the charger. In this mode, by defining two states for the charger, at the moment when the charger's normal charging operation is ensured, the voltage drop across the USB wire between the terminal and the charger will be eliminated, so that a charging voltage 5 ± 5% V can be obtained from the charging terminal. Thus, the high voltage battery can be quickly charged with a constant current.
[089] The first data signal port 122 includes a D+ port and a D- port. When the charger 10 is in the distal return state, the first switching device 13 controls the return receiving port 112 to be connected with the D+ port or the D- port according to the first charge control device 14.
[090] In this mode, by using the D+ port or the D- port of the charger to transmit the return signal from a charging management chip from the terminal to the charger, the voltage drop through the USB wire between the terminal and the charger is eliminated, such that a charging voltage of 5 ± 5% V can be obtained at a voltage input port of the terminal charge management chip. Thus, the high voltage battery can be quickly charged with a constant current.
[091] The first charge control device 14 is configured to control the charger 10 to be in the proximal return state when the charge operation is initiated, and control the charger 10 to be in the distal return state when a time duration loading operation exceeds a preset time delay.
[092] In this mode, by monitoring the duration of the charging operation, whether the charger is in the proximal return state or in the distal return state can be determined, such that the return signal can be received from different ports. By getting the feedback signal from the charging terminal, the voltage drop across the USB wire between the terminal and the charger will be eliminated, so that a charging voltage of 5 ± 5% V can be obtained at the charging port. voltage input from the terminal's charge management chip. Thus, the high voltage battery can be quickly charged with a constant current.
[093] In this mode, the first charging port 12 is a USB interface or a Micro USB interface.
[094] If the first charging port is the USB interface or the Micro USB interface, the feedback signal can be obtained from the charging terminal by solving the above modalities, to eliminate the voltage drop across the USB wire between the terminal and the charger, such that a charging voltage of 5 ± 5% V can be obtained at the voltage input port of the charging management chip of the terminal. Thus, the high voltage battery can be quickly charged with a constant current.
[095] In another embodiment, as shown in Figure 2, a charging terminal 20 includes a charging management chip 21, a second charging port 22, a second switching device 23 and a second charging control device 24 .
[096] Charging management chip 21 is configured to receive an input DC charging current to charge the charging terminal. Charge management chip 21 includes at least one input voltage port 211, which is configured to input DC charging current, and a chip data port 212.
[097] The second charging port 22 is configured to connect with the charger 10 to receive the DC charging current that is input from the charger 10. The second charging port 22 includes at least one second power supply port 221 and a second data signal port 222. The second power supply port 221, which is connected with the voltage input port 211, is configured to output the DC load current to the load management chip 21.
[098] The second switching device 23 which is provided between the charge management chip 21 and the second charge port 22, is configured to control the second data signal port 222 to be connected with the voltage input port 211 or the chip data port 212 according to the second charge control device 24.
[099] In this mode, by using the second data signal port of the charging terminal to transmit a return signal to the charger, a voltage drop across the USB wire between the terminal and the charger will be eliminated, so that a charging voltage of 5 ± 5% V can be obtained from the voltage input port of the terminal's charging management chip. Thus, a high voltage battery can be quickly charged with a constant current.
[100] The charging terminal 20 has a proximal return state and a distal return state. When the load terminal 20 is in the proximal return state, the second switching device 23 controls the second data signal port 222 to be connected with the chip data port 212 according to the second load control device 24 When the charging terminal 20 is in the distal return state, the second switching device 23 controls the second data signal port 222 to be connected with the voltage input port 211 according to the second charging control device 24.
[101] Once at a start of a charging operation, the charging terminal needs to determine the type of a charger by means of the connection state of its second data signal port with the first data signal port of the charger, at this time, the charging terminal may not send the feedback signal through the data signal port, and the charger can only get the feedback signal through the first power supply port of the charger. When the charging terminal is informed of the charger type, the charging terminal and charger data signal ports are free, thus the feedback signal can be transmitted through the charging terminal data signal ports and the charger. In this mode, by defining two states for the charging terminal, at the moment when reception of the normal charging operation is assured, the voltage drop across the USB wire between the terminal and the charger will be eliminated, so that a voltage charging voltage of 5 ± 5% V can be obtained from the charging terminal. Thus, the high voltage battery can be quickly charged with a constant current.
[102] The second data signal port 222 includes a D+ port and a D- port. When the load terminal 20 is in the proximal return state, the second switching device 23 controls the D+ gate or the D- gate to be connected with the chip data port 212 according to the second load control device 24 When the charging terminal 20 is in the distal return state, the second switching device 23 controls the D+ port or the D- port to be connected with the voltage input port 211 according to the second charging control device 24.
[103] In this mode, by using the D+ port or the D- port of the terminal to transmit the return signal from the terminal charge management chip to the charger, the voltage drop through the USB wire between the terminal and the charger be eliminated, such that a charging voltage of 5 ± 5% V can be obtained at the voltage input port of the terminal charge management chip. Thus, the high voltage battery can be quickly charged with a constant current.
[104] The second load control device 24 is configured to control the load terminal 20 to be in the proximal return state when the load operation is initiated, and control the load terminal 20 to be in the distal return state when a loading operation duration time exceeds a preset time delay.
[105] In this mode, by monitoring the duration of the charging operation, whether the charging terminal is in the proximal return state or in the distal return state can be determined, so as to transmit the return signal to the charger. By getting the feedback signal from the charging terminal port, the voltage drop across the USB wire between the terminal and the charger will be eliminated, so that a charging voltage of 5 ± 5% V can be obtained at the voltage input port of the terminal charge management chip. Thus, the high voltage battery can be quickly charged with a constant current.
[106] The second charging port 22 is either a USB interface or a Micro USB interface.
[107] If the second charging port is the USB interface or the Micro USB interface, the feedback signal can be obtained from the charging terminal by solving the above modalities, to eliminate the voltage drop across the USB wire between the terminal and the charger, such that a charging voltage of 5 ± 5% V can be obtained at the voltage input port of the charging management chip of the terminal. Thus, the high voltage battery can be quickly charged with a constant current.
[108] In another embodiment, as shown in Figure 3, a charging system 30 is provided by the present disclosure, which includes a charger 10 and a charging terminal 20. The charger 10 is connected with the charging terminal 20, by the that charger 10 charges charging terminal 20.
[109] The charger 10 includes a power supply device 11, a first charging port 12, a first switching device 13 and a first charge control device 14.
[110] The power supply device 11 is configured to emit a DC charging current by rectifying and reducing voltage from an incoming AC charging current. The power supply device 11 includes at least one voltage output port 111 and a return receiving port 112. The voltage output port 111 is configured to output the DC charging current. The feedback receiving port 112 is configured to receive a feedback signal to adjust the output DC charging current.
[111] The first charging port 12 is configured to connect with a charging terminal to output the output DC charging current to the charging terminal. The first loading port 12 includes at least a first power supply port 121 and a first data signal port 122. The first power supply port 121, which is connected with the voltage output port 111, is configured to transmit the DC charging current.
[112] The first switching device 13, which is provided between the receiving return port 112 and the first loading port 12, is configured to control the receiving return port 112 to be connected with the first receiving source port. feed 121 or the first data signal port 122 according to the first charge control device 14.
[113] The charging terminal 20 includes a charging management chip 21, a second charging port 22, a second switching device 23 and a second charging control device 24.
[114] Charging management chip 21 is configured to receive the input DC charging current to charge the charging terminal. Charge management chip 21 includes at least one input voltage port 211, which is configured to input DC charging current, and a chip data port 212.
[115] The second charging port 22 is configured to connect with the charger 10 to receive the DC charging current that is input from the charger 10. The second charging port 22 includes at least one second power supply port 221 and a second data signal port 222. The second power supply port 221 which is connected with the voltage input port 211 is configured to output the DC charging current to the charge management chip 21.
[116] The second switching device 23 which is provided between the charge management chip 21 and the second charge port 22, is configured to control the second data signal port 222 to be connected with the voltage input port 211 or the chip data port 212 according to the second charge control device 24.
[117] The charging system 30 has a proximal return state and a distal return state.
[118] When the charging system 30 is in the proximal return state, the first switching device 13 controls the return receiving port 112 to be connected with the first power supply port 121 according to the first control device load 14, and the second switching device 23 controls the second data signal port 222 to be connected with the chip data port 212 according to the second load control device 24.
[119] When the loading system 30 is in the distal feedback state, the first switching device 13 controls the feedback receiving port 112 to be connected with the first data signal port 122 according to the first control device of charging 14, and the second switching device 23 controls the second data signal port 222 to be connected with the voltage input port 211 according to the second charging control device 24.
[120] The first data signal port 122 and the second data signal port 222 each include a D+ port and a D- port.
[121] When the loading system 30 is in the proximal feedback state, the second switching device 23 controls the D+ port to be connected with the chip data port 212 according to the second loading control device 24;
[122] when the loading terminal 20 is in the distal feedback state, the first switching device 13 controls the feedback receiving port 112 to be connected with the D+ port according to the first loading control device 14; and the second switching device 23 controls the D+ gate to be connected with the voltage input port 211 according to the second charge control device 24;
[123] or,
[124] when the loading system 30 is in the proximal feedback state, the second switching device controls the D-gate to be connected with the chip data port according to the second loading control device;
[125] when the load terminal 20 is in the distal feedback state, the first switching device 13 controls the feedback receiving port 112 to be connected with the D+ port or the D- port according to the first control device loading 14; and the second switching device 23 controls the D+ gate or the D- gate to be connected with the voltage input port 211 according to the second charging control device 24.
[126] The first charge control device 14 is configured to control the charger 10 to be in the proximal return state when a charge operation is initiated, and control the charger 10 to be in the distal return state when a time duration loading operation exceeds a preset time delay. The second load control device 24 is configured to control the load terminal 20 to be in the proximal return state when the load operation is initiated, and control the load terminal 20 to be in the distal return state when the time of duration of the loading operation exceeds a preset time delay. The preset time delays for the first charge control device 14 and the second charge control device 24 are the same.
[127] The first charging port is a USB interface or a Micro USB interface; and the second charging port is a USB interface or a Micro USB interface.
[128] The first charging port of the charger and the second charging port of the charging terminal can be the same type of port or different types of ports, ie the two ends of the USB wire between the charger and the charging terminal they can be the same type of door or different types of doors.
[129] In another embodiment, a control method for loading is provided by the present disclosure, based on the above loading system, and as shown in Figure 4, the loading control method includes the following steps.
[130] In step S401, when a loading operation is initiated, the loading system is controlled to be in the proximal return state; and when the charging system is in the proximal return state, the first switching device of the charger controls the receiving return port to be connected with the first power supply port according to the first charging control device; and the second charging terminal switching device controls the second data signal port to be connected with the chip data port according to the second charging control device.
[131] In step S402, it is determined whether a loading operation duration time exceeds a given time delay.
[132] In step S403, when the loading operation duration time exceeds the preset time delay, the loading system is controlled to be in the distal return state; and when the loading system is in the distal feedback state, the first switching device controls the feedback receiving port to be connected with the first data signal port according to the first loading control device and the second device Switch controls the second data signal port to be connected with the voltage input port according to the second charge control device.
[133] Each of the first and second data signal ports includes a D+ port and a D- port. When the charging system is in the proximal return state, the second switching device controls the D+ port to be connected with the chip data port according to the second charging control device; and when the loading terminal is in the distal feedback state, the first switching device controls the feedback receiving port to be connected with the D+ port according to the first loading control device; and the second switching device controls the D+ port to be connected with the voltage input port according to the second charge control device.
[134] Or, when the charging system is in the proximal return state, the second switching device controls the D-gate to be connected with the chip data port according to the second charging control device; and when the load terminal is in the distal feedback state, the first switching device controls the feedback receiving port to be connected with port D- according to the first load control device; and the second switching device controls the gate D- to be connected with the voltage input gate according to the second charge control device.
[135] In the following, the present disclosure will be described in detail, respectively, with reference to a case where each of the first and second data signal ports is a D+ port, and a case where each of the first and second data signal ports is a D-port.
[136] (I) In the case where each of the first and second data signal ports is a D+ port, the return signal is transmitted between the charger and the charge terminal via the D+ ports.
[137] In this mode, as shown in Figure 5, the first switching device of the charger can be a Single Pole Dual Throw (SPDT) switch 53. An A end of the SPDT switch 53 is connected with a return receiving port 512 of a power supply module 51, and a B end of the SPDT 53 can be connected to a first power supply port 521 of the first charging port or to a D+ port 522 of the charger according to a control of a first device load control device 54. When the load operation is initiated, the first load control device 54 controls the B end of the SPDT 53 to be connected to the first power supply port 521 of the first load port. After the charging operation lasts for a certain period, the first charge control device 54 controls the B end of the SPDT 53 to be connected to the D+ 522 port of the charger.
[138] The second load terminal switching device can also be a SPDT 57 switch. An A end of the SPDT 57 is connected to the D+ 562 port of the second load port, and a B end of the SPDT 57 can be connected to a voltage input port 551 or to a chip data port 552 of a charge management chip 55 according to a control of the second charge control device 58. When the charge operation is started, the second charge management device charge control 58 controls the B end of the SPDT switch 57 to be connected to the 552 chip data port of the charge management chip 55. After the charge operation lasts for a certain period, the second charge control device 58 controls the B end of the SPDT 57 switch to be connected to the 551 voltage input port of the 55 charge management chip.
[139] In this mode, the feedback is no longer directly connected to the voltage output port of the charger, but to the SPDT 53 switch, and the other end of the SPDT 53 switch can be connected, respectively, to the first power source port. 521 power supply or the 522 D+ port according to the control.
[140] The SPDT 57 switch is also added to the charging terminal. One end of the SPDT 57 switch is connected to the D+ 562 port of the charging terminal (to be consistent with the charger), and the other end of the SPDT 57 switch can be connected to the 551 voltage input port or the data port of chip 552 of charge management chip 55.
[141] In this mode, by transmitting the return signal through the connection between the charger's D+ ports and the charging terminal, in order to allow the return signal to reflect the voltage drop through the USB wire between the charger and the terminal charger, the voltage drop across the USB wire between the terminal and the charger will be eliminated, so a charging voltage of 5 ± 5% V can be obtained at the charging management chip's voltage input port. terminal. Thus, the high voltage battery can be quickly charged with a constant current.
[142] (II) In the case where each of the first and second data signal ports is a D-port, the return signal is transmitted between the charger and the charge terminal via the D-ports.
[143] As shown in Figure 6, the first switching device of the charger may be a SPDT 63 switch. One end A of the SPDT 63 switch is connected with a return receive port 612 of a power supply module 61, and a B end of the SPDT switch 63 can be connected to a first power supply port 621 of the first charge port or to a charger port D-622 according to a control of the first charge control device 64. When operating When loading is initiated, the first loading control device 64 controls the B end of the SPDT 63 to be connected to the first power supply port 621 of the first loading port. After the charging operation lasts for a certain period, the control device 64 controls the B end of the SPDT 63 switch to be connected to the charger's port D-622.
[144] The second load terminal switching device can also be an SPDT 67 switch. An A end of the SPDT 67 switch is connected to a D-662 port of the second load port, and a B end of the SPDT 67 can be connected to a voltage input port 651 or a chip data port 652 of a charge management chip 65 according to a control of the second charge control device 68. When the charge operation is started, the second charge control device 68 controls the B end of the SPDT switch 67 to be connected to the chip data port 652 of the charge management chip 65. After the charge operation lasts for a certain period, the second charge control device 68 controls the B end of the SPDT 67 switch to be connected to the 651 voltage input port of the 65 charge management chip.
[145] In this mode, the feedback is no longer directly connected to the voltage output port of the charger, but to the SPDT 63 switch, and the other end of the SPDT 63 switch can be connected, respectively, to the first power supply port 621 or port D-622 according to the control.
[146] The SPDT 67 switch is also added to the charging terminal. One end of the SPDT67 switch is connected to the charging terminal's D-662 port (to be consistent with the charger), and the other end of the SPDT 67 switch can be connected to the 651 voltage input port or the chip data port 652 of charge management chip 65.
[147] In this mode, by transmitting the return signal through the connection between the charger's D-ports and the charging terminal, in order to allow the return signal to reflect the voltage drop through the USB wire between the charger and the charging terminal, the voltage drop across the USB wire between the terminal and the charger will be eliminated, so a charging voltage of 5 ± 5% V can be obtained at the charging management chip's voltage input port of the terminal. Thus, the high voltage battery can be quickly charged with a constant current.
[148] While exemplary embodiments of the present disclosure have been illustrated in the above example, it should be noted that, various changes and modifications can be made without departing from the scope of the present disclosure, which is defined by the claims. The functions, steps and/or operations of the method claims in accordance with the described embodiments of the present disclosure may not necessarily be performed in a particular order. Furthermore, although elements of the present disclosure may be described or prescribed in a single form, multiple forms may also be designed, unless the single form is explicitly prescribed.
[149] The objectives, technical solutions and beneficial effects of the present disclosure have been explained in more detail with the specific modalities described. It should be noted that, the above are merely specific embodiments of the present disclosure, and are not used to limit the scope of the present disclosure. Any alteration, equivalent substitution, modification and the like within the spirit and principle of this disclosure shall be embraced within the scope of protection of this disclosure.

权利要求:
Claims (14)
[0001]
1. Charger (10), comprising: a power supply device (11), a first charging port (12), a first charge control device (14) and a first switching device (13); The power supply device is configured to emit a DC charging current by rectifying and reducing the voltage of an input AC charging current, the power supply device comprising at least one voltage output port (111) and a receiving port output (112), the voltage output port is configured to output the DC charging current, and the return receiving port is configured to receive a return signal to adjust the output DC charging current; the first port The charging terminal is configured to connect with a charging terminal (20) to output the output DC charging current to the charging terminal, the first charging port comprises at least one first. The power supply port (121) and a first data signal port (122), and the first power supply port, which is connected with the voltage output port, is configured to output the DC charging current. the first switching device (13), which is provided between the receiving return port (112) and the first loading port (12), is configured to control the receiving return port to be connected with the first port of power supply (121) or the first data signal port (122) according to the first charge control device (14), the charger (10) being characterized in that the charger has a first state of return and a second return state; when the charger is in the first return state, the first switching device controls the return receiving port to be connected with the first power supply port according to the first return control device.charging; when the charger is in the second return state, the first switching device controls the return receiving port to be connected with the first data signal port according to the first charge control device.
[0002]
2. Charger (10) according to claim 1, characterized in that the first data signal port comprises a D+ port and a D- port; when the charger is in the second return state, the first device Switch controls the return receiving port to be connected with the D+ port or the D- port according to the first charge control device.
[0003]
3. Charger (10) according to claim 1, characterized in that the first charge control device (14) is configured to control the charger to be in the first return state when a charge operation is initiated , and to control the charger to be in the second distal return state when a charging operation duration time exceeds a given time delay.
[0004]
4. Charger (10) according to claim 1, characterized in that the first charging port (12) is a USB interface or a Micro USB interface.
[0005]
5. Charging terminal (20), comprising: a charging management chip (21), a second charging port (22), a second switching device (23) and a second charging control device (24), wherein: the charge management chip (21) is configured to receive an input DC charge current to charge the charge terminal, the charge management chip comprises at least one voltage input port (211) and a chip data port (212), and voltage input port is configured to input DC charging current; second charging port (22) is configured to connect with a charger (10) to receive charging current DC that is input from the charger, the second charging port comprises at least a second power supply port (221) and a second data signal port (222), and the second power supply port, which is connected with the voltage input port (211), it is configured to output the DC charging current to the charge management chip (21); the second switching device (23), which is provided between the charge management chip (21) and the second loading port (22), is configured to control the second data signal port (222) to be connected with the voltage input port (211) or the chip data port (212) according to the second loading control device (24), the loading terminal (20) being characterized in that it has a first return state and a second return state, in which: when the loading terminal is in the first return state, the second switching device (23) controls the second data signal port (222) to be connected with the chip data port (212) according to the second load control device (24) ; and when the charging terminal is in the second return state, the second switching device (23) controls the second data signal port (222) to be connected with the voltage input port (211) according to the second device. Charge Control Panel (24).
[0006]
6. Charging terminal (20) according to claim 5, characterized in that the second data signal port (222) comprises a D+ port and a D- port; when the charging terminal is in the first return state, the second switching device (23) controls the D+ port or the D- port to be connected with the chip data port (212) according to the second load control device (24); charging terminal is in the second return state, the second switching device controls the D+ port or the D- port to be connected with the voltage input port (211) according to the second charging control device.
[0007]
7. Loading terminal (20) according to claim 5, characterized in that the second loading control device (24) is configured to control the loading terminal (20) to be in the first return state when a load operation is initiated, and control the load terminal to be in the second return state when a load operation duration time exceeds a preset time delay.
[0008]
8. Charging terminal (20) according to claim 5, characterized in that the second charging port (22) is a USB interface or a Micro USB interface.
[0009]
9. Charging system (30) comprising: a charger (10) and a charging terminal (20), wherein the charger is connected with the charging terminal, the charger being adapted to charge the charging terminal, wherein: the charger comprises a power supply device (11), a first charging port (12), a first charging control device (14) and a first switching device (13); the power supply device (11 ) is configured to emit a DC charging current by rectifying and reducing voltage of an incoming AC charging current, the power supply device comprises at least one voltage output port (111) and a return receiving port (112 ), the voltage output port is configured to output the DC charging current, and the return receiving port is configured to receive a return signal to adjust the output DC charging current; the first port the charging terminal (12) is configured to connect with the charging terminal to output the output DC charging current to the charging terminal, the first charging port comprises at least a first power supply port (121) and a the first data signal port (122), and the first power supply port, which is connected with the voltage output port (111), is configured to output the DC charging current; the first switching device (13 ), which is provided between the return receiving port (112) and the first loading port (12), is configured to control the return receiving port to be connected with the first power supply port (121) or with the first data signal port (122) according to the first charging control device (14); the charging terminal comprising: a charging management chip (21), a second charging port (22), one second charging control device (23) and a second switching device (24); the charging management chip (21) is configured to receive the input DC charging current to charge the charging terminal, the charging management chip. charging comprises at least one voltage input port (211) and a chip data port (212), and the voltage input port is configured to input DC charging current; the second charging port (22) is configured to connect with the charger to receive the DC charging current that is input from the charger, the second charging port comprises at least a second power supply port (211) and a second data signal port (232) , the second power supply port, which is connected with the voltage input port (211), is configured to output the DC charging current to the charging management chip (21); The switching device (23), which is provided between the load management chip (21) and the second load port (22), is configured to control the second data signal port (222) to be connected with the port. input voltage (211) or with the chip data port (212) according to the second charging control device (24); the charging system (30) being characterized in that it has a first state of return and a second distal return state, wherein: when the loading system is in the first proximal return state, the first switching device (13) controls the return receiving port (112) to be connected with the first port of the power supply (121) according to the first charge control device (14), and the second switching device (23) controls the second data signal port (222) to be connected with the data port of chip (212) according to the second device loading control port (24); when the loading system is in the second feedback state, the first switching device (13) controls the feedback receiving port (112) to be connected with the first data signal port. (122) according to the first charge control device (14), and the second switching device (23) controls the second data signal port (222) to be connected with the voltage input port (211) according to the second charge control device (24).
[0010]
10. Charging system (30) according to claim 9, characterized in that each of the first data signal port (122) and the second data signal port (222) comprise a D+ port and a D- port, wherein: when the charging system is in the first return state, the second switching device (23) controls the D+ port to be connected with the chip data port (212) according to the second loading control device (24); when the loading terminal is in the second return state, the first switching device (13) controls the return receiving port (112) to be connected with the D+ port in accordance with the first charge control device (14), and the second switching device (23) controls the D+ gate to be connected with the voltage input port (211) according to the second charge control device (24); or, when the charging system is in the first return state, the second switching device (23) controls the D-gate to be connected with the chip data port (212) according to the second charging control device (24); and when the load terminal is in the second return state, the first switching device (13) controls the return receiving port (112) to be connected with the D-gate according to the first load control device (14 ), and the second switching device controls the D-gate to be connected with the voltage input port (211) according to the second charge control device.
[0011]
11. Charging system (30) according to claim 9, characterized in that the first charging control device (14) is configured to control the charger (10) to be in the first return state when an operation charging is initiated, and controlling the charger to be in the second return state when a charging operation duration time exceeds a set time delay; the second charge control device (24) is configured to control the charging terminal (20) to be in the first return state when the load operation is initiated, and control the load terminal to be in the second return state when the duration time of the load operation exceeds a predefined time delay; and the preset time delays for the first charge control device (14) and the second charge control device (24) are the same.
[0012]
12. Charging system according to claim 9, characterized in that the first charging port (12) is a USB interface or a Micro USB interface, and the second charging port (22) is a USB interface or a Micro USB interface.
[0013]
13. Loading control method, implemented based on the loading system as defined in claim 9, characterized in that it comprises: when a loading operation is initiated, controlling (S401) the loading system to be in the first state of return, and when the charging system is in the first return state, control the return receiving port to be connected with the first power supply port according to the first charge control device by the first switching device of the charger ; and controlling the second data signal port to be connected with the chip data port according to the second charging control device by the second charging terminal switching device; determining (S402) whether or not a duration time of the charging operation exceeds a determined time delay; when the duration time of the charging operation exceeds the preset time delay, control (S403) the charging system to be in the second return state, and when the charging system is in the second feedback state, controlling the feedback receiving port to be connected with the first data signal port according to the first charge control device by the first switching device, and controlling the second data signal port to be connected with the voltage input port according to the second charge control device by the second switching device.
[0014]
14. Charging control method according to claim 13, characterized in that each of the first and second data signal ports comprises a D+ port and a D- port; when the charging system is in the first return state, control the D+ port to be connected with chip data port according to the second charge control device by the second switching device; when the charging system is in the second return state, control the charge port receiving feedback to be connected with the D+ port according to the first charge control device of the first switching device, and controlling the D+ port to be connected with the voltage input port according to the second charge control device. charging by the second switching device; or, when the charging system is in the first return state, controlling the D-gate to be connected with the chip data port according to the second charging control device by the second switching device; when the loading system is in the second feedback state, controlling the feedback receiving port to be connected with the D-gate according to the first loading control device by the first switching device; and controlling the D-gate to be connected with the voltage input port according to the second charge control device by the second switching device.

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同族专利:

公开号 | 公开日

JP2015534444A|2015-11-26|

KR101719262B1|2017-03-23|

MX343305B|2016-11-01|

EP2854253A1|2015-04-01|

BR112014017612A2|2017-06-20|

EP2854253B1|2016-09-21|

US20150091499A1|2015-04-02|

WO2015043190A1|2015-04-02|

JP5942042B2|2016-06-29|

CN103475068B|2016-03-23|

CN103475068A|2013-12-25|

US9647475B2|2017-05-09|

KR20150048086A|2015-05-06|

RU2606640C1|2017-01-10|

MX2014008741A|2015-05-29|

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法律状态:
2018-11-13| B06F| Objections, documents and/or translations needed after an examination request according [chapter 6.6 patent gazette]|

2020-02-18| B06U| Preliminary requirement: requests with searches performed by other patent offices: procedure suspended [chapter 6.21 patent gazette]|

2021-07-06| B09A| Decision: intention to grant [chapter 9.1 patent gazette]|

2021-08-24| B16A| Patent or certificate of addition of invention granted [chapter 16.1 patent gazette]|Free format text: PRAZO DE VALIDADE: 20 (VINTE) ANOS CONTADOS A PARTIR DE 08/05/2014, OBSERVADAS AS CONDICOES LEGAIS. |

优先权:

申请号 | 申请日 | 专利标题

CN201310462373.6|2013-09-30|

CN201310462373.6A|CN103475068B|2013-09-30|2013-09-30|A kind of charger, charging terminal, charging system and charge control method|

PCT/CN2014/077004|WO2015043190A1|2013-09-30|2014-05-08|Charger, charging terminal, charging system and charging control method|

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