JP2014050228A - Charging converter - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a charging converter.SOLUTION: The charging converter has a first protocol interface and a second protocol interface which are mounted in the main body. The main body further has a switching circuit. Each of the first protocol interface and the second protocol interface has a power pin, a ground pin, and two data pins. The power pin of the first protocol interface is connected to the power pin of the second protocol interface. The data pin of the second protocol interface is connected to the data pin of the first protocol interface through a switching circuit. The switching circuit has a function which switches a synchronization mode or a quick charge mode. When the synchronization mode is selected, power channel and data channel are simultaneously set between the first protocol interface and the second protocol interface. When the quick charge mode is selected, only the power channel is set and charging speed is accelerated.

Description

  The present invention relates to a charging converter, and more particularly to a charging converter that can be switched between a data transfer / charging mode and a quick charging mode.

Mobile phones are already one of the most indispensable means of communication for modern people. In view of the potential of the huge market, all major major mobile phone manufacturers are making every effort to develop new types of mobile phones that will inspire consumers to purchase. As a result of such competition, waste of resources is occurring.
Regarding the replacement rate of mobile phones, a fairly high percentage of users replace mobile phones in a very short time. However, all the charging sockets that can be used by mobile phones from all major major mobile phone manufacturers had their own specifications. Also, charging sockets used in different models of mobile phones manufactured by the same manufacturer may not be replaceable. Under such circumstances, a new mobile phone to be shipped usually needs to be provided with a unique charger dedicated to the mobile phone, and the old mobile phone charger is inevitably not used.
Due to the high replacement rate of mobile phones, the discarded number of mobile phone chargers is surprising. According to statistics published by the GSM (registered trademark) association (GSMA), 5.1 tons of chargers are repeatedly manufactured every year against the global market demand, which is a serious waste of resources. To address this wasteful resource issue, GSMA will standardize Micro USB (Universal Serial Bus) as a universal universal specification for charging interfaces by the end of 2012 on February 17, 2009. Announced, the European Union also passed the charger specifications at the end of 2010, selected the micro USB interface as the universal charging socket specification for mobile phones, and started its operation in 2012.
That is, every new mobile phone on the market must have a charging socket that is compatible with Micro USB. The standardization of charging sockets is beneficial in effectively solving the problem of wasting resources, and standby power consumed by each new mobile phone charger is 50% lower than that of existing chargers. Because it is estimated, there are two birds with one stone.

It is known to those skilled in the art that the USB interface is originally used as a technical specification for the input / output interface of a computer. Therefore, in addition to the power pin (VBUS), the micro USB interface also has two data pins (D− and D +). Regarding the interaction between a computer and a standard peripheral device with a USB interface, the computer not only performs data communication with the USB peripheral device, but also supplies power to the USB peripheral device. When data transmission and charging are performed at the same time (referred to herein as a synchronous mode), data transmission is preferentially performed. As a result, the charging current is 500 mA, and the charging speed is relatively slow. On the other hand, when only charging is performed without data transmission (herein referred to as a quick charging mode), the charging current increases to a range of 700 to 800 mA.
Since the charging current of the latest U3-USB interface can reach up to 900 mA, the charging speed is accelerated. However, when a mobile phone is connected to a charger or computer via a micro USB interface, the current micro USB interface will always be in synchronous mode unless specifically designed. For a user who only wants to charge a mobile phone, unless a specially designed charger is used, it is inevitable to wait for a long time to charge.

  As mentioned above, since the mobile phone charger applies micro USB as the standard interface for the charging socket, mobile phones with USB specification can only charge in synchronous mode, but specially designed Unless a charger is used, charging takes time.

  The present invention provides a mode switching function that is connected between a charged device and a charging device and allows a user to select a synchronous mode or a quick charging mode according to a request, and can be operated more flexibly and conveniently. The object is to provide a converter.

  In order to achieve the above object, the charging converter has a main body, a first protocol interface, a second protocol interface, and a switch.

  The main body has a switching circuit therein.

  The first protocol interface is a USB-based interface mounted on the main body, and includes a power pin, a ground pin, and two data pins.

  The second protocol interface is mounted on the main body and includes a power pin, a ground pin, and two data pins. The power pin is connected to the power pin of the first protocol interface. The ground pin is connected to the ground pin of the first protocol interface. The data pin is connected to the two data pins of the first protocol interface through the switching circuit.

  The switch is mounted on the main body, connected to the switching circuit of the main body, and selectively switches between a synchronous mode and a quick charge mode via the switching circuit. The power pin and the data pin of the first protocol interface are respectively connected to the power pin and the data pin of the second protocol interface in the synchronous mode, and the power pin of the first protocol interface is In the fast charge mode, the power pin of the second protocol interface is connected.

  The charging converter can be connected in series between the charged device and the charging device. The charging converter can select the synchronous mode or the quick charging mode via the switching circuit before connection. When the quick charge mode is selected, a data channel between the charging device and the charged device is not set. Therefore, the charging device can rapidly charge the charged device with a higher charging current. The charged device may be a mobile phone, and the charging device may be a computer or a charger.

The advantages of the charging converter of the present invention are as follows.
1. The user can conveniently select a synchronous mode or a quick charge mode based on the user's request.
2. When the user selects the quick charging mode, a higher charging current is available and the charging time is shortened.
3. Charged devices apply to all kinds of chargers with a USB output interface and do not require a dedicated charger.

  Other objects, advantages and novel features of the invention will become more apparent from the following detailed description when taken in conjunction with the accompanying drawings.

FIG. 1 is a perspective view of a first embodiment of a charging converter according to the present invention. FIG. 2 is a circuit diagram of the charging converter of FIG. 3A is an operation circuit diagram of the charging converter of FIG. 3B is an operation circuit diagram of the charging converter of FIG. FIG. 4 is another circuit diagram of the charging converter of FIG. FIG. 5 is a perspective view of a second embodiment of the charging converter according to the present invention. FIG. 6 is a perspective view of a third embodiment of the charging converter according to the present invention.

  Referring to FIG. 1, the first embodiment of the charging converter according to the present invention includes a main body 10, a first protocol interface 11, a second protocol interface 12, and a switch 13.

  The first protocol interface 11 is a USB-based interface mounted on the first end of the main body 10. The second protocol interface 12 is mounted on the second end of the main body 10 facing the first end. The switch 13 is mounted on one surface of the main body 10 and is connected to a switching circuit mounted in the main body 10.

In the present embodiment, the first protocol interface 11 is a micro B type USB socket for a micro B type USB plug inserted therein. The micro B type USB socket has a power pin (VBUS), a ground pin (GND), and two data pins (D + and D−).
The second protocol interface 12 is a 30-pin connector, and in particular, is a communication interface used in iPhone (registered trademark) and iPad (registered trademark) manufactured by Apple. The 30-pin connector has at least a power pin (BATV), a ground pin (GND), and two USB data pins (D + and D-). The switch 13 is a mechanical switch that cooperates with a switching circuit inside the main body 10, and determines the connection state of the USB data pins (D + and D−) of the second protocol interface 12.

Referring to FIG. 2, the power pin VBUS of the first protocol interface 11 is connected to the power pin BATV of the second protocol interface 12. The switching circuit 30 may be implemented as two voltage divider circuits. One of the voltage divider circuits includes two voltage divider resistors R1 and R2 connected in series, and has a connection node connected to one end of each of the two voltage divider resistors R1 and R2. The other end of one voltage divider resistor R1 is connected to the power pin BATV of the second protocol interface 12. The other end of the other voltage divider resistor R2 is connected to the ground.
The other voltage divider circuit includes two voltage divider resistors R3 and R4 connected in series, and has a connection node connected to one end of each of the two voltage divider resistors R3 and R4. The other end of one voltage divider resistor R3 is connected to the power pin BATV of the second protocol interface 12. The other end of the other voltage divider resistor R4 is connected to the ground.

  The switch 13 is a bidirectional switch having two common points and four switch points S1, S2, S3, S4. One of the common points is connected to one of the data pins D− of the second protocol interface 12 and corresponds to the switch points S2 and S4, and the other common point is connected to the other data pin D + and the switch point S1. , S3. The two switch points S2 and S1 are connected to the data pins D + and D− of the first protocol interface 11. The switch points S3 and S4 are connected to connection nodes of the two voltage divider circuits of the switching circuit 30, respectively.

  Referring to FIG. 3A, when the user switches the switch 13 to enter the synchronous mode, the two data pins D + and D− of the second protocol interface 12 are passed through the two common points and the two switch points S2 and S1. Are connected to the two data pins D + and D− of the first protocol interface 11, respectively. In the synchronous mode, the first protocol interface 11 and the second protocol interface 12 are connected to the charging device and the charged device, respectively. The power channel and the data channel are simultaneously formed between the charging device and the charged device. Data transmission also occurs while the charging device charges the device to be charged. The charging voltage is approximately 500 mA.

When the user wants to charge only, the switch 13 is switched to enter the quick charging mode of the first protocol interface 11 and the second protocol interface 12 connected to the charging device and the charged device, respectively.
Referring to FIG. 3B, in the fast charge mode, the two data pins D +, D− of the second protocol interface 12 are two for the data pins D +, D− of the charged device to obtain a specific voltage. The common node and the two switch points S4 and S3 are connected to the connection nodes of the two voltage divider circuits of the switching circuit 30, respectively. Since the data pins D + and D− of the first protocol interface 11 are disconnected from the data pins D + and D− of the second protocol interface 12, a power channel is provided between the charging device and the charged device. Only formed. While the charging device charges the device to be charged, the charging voltage is in the range of approximately 700 to 1000 mA depending on the type of charging device.

  As described above, the user can select either the synchronous mode or the quick charge mode according to the user's request by using the charging converter of the present invention. If there is only a charge request, the quick charge mode is selected and the charge time is shortened because it has a higher charge current to charge. On the other hand, a charger that satisfies the power requirements of the charging device (for example, at least voltage 5V / current 1A) works with the charging converter of the present invention to charge the device to be charged without requiring a dedicated charger. can do.

  Referring to FIG. 4, the switching circuit 30 in the main body 10 includes a micro control unit (MCU) so that the data pins of the first protocol interface 11 and the second protocol interface 12 are all connected to the MCU. It may be. The MCU controls the connection of the data pins of the first protocol interface 11 and the second protocol interface 12 by switching the switch 13 to enter the quick charge mode or the synchronous mode. Similarly, a switching command can be issued from the computer to the charging converter to select either the quick charge mode or the synchronous mode.

  Referring to FIG. 5, the second embodiment of the charging converter according to the present invention is different from the first embodiment in that the first protocol interface 11 mounted on one end of the main body 10 is a USB plug. Different. The second protocol interface 12 remains a 30 pin connector.

  Referring to FIG. 6, in the third embodiment of the charging converter according to the present invention, the first protocol interface 11 is a USB plug connected to the main body 10 via a cable, and the second protocol interface 12 differs from the first embodiment in that 12 is a micro-B USB plug. The USB plug can be directly connected to a USB socket of a computer, and the micro B type USB plug can be connected to a charging socket of a mobile phone constituted by a micro B type USB socket.

  While many features and advantages of the invention have been described in the foregoing specification, together with details of the structure and features of the invention, the disclosure is illustrative only. Changes may be made within the principles of the invention to the fullest extent indicated by the broad general meaning of the terms used in the appended claims, with regard to details, particularly with respect to shape, size and arrangement of parts. .

DESCRIPTION OF SYMBOLS 10 Main body 11 1st protocol interface 12 2nd protocol interface 13 Switch 30 Switching circuit

Claims (6)

A main body having a switching circuit therein;
A first protocol interface mounted on the main body and based on USB (Universal Serial Bus), having a power pin, a ground pin, and two data pins;
A power pin mounted on the main body and connected to the power pin of the first protocol interface, a ground pin connected to the ground pin of the first protocol interface, and the first via the switching circuit A second protocol interface having two data pins connected to the two data pins of the protocol interface;
A switch mounted on the main body, connected to the switching circuit of the main body, and selectively switching a synchronous mode or a quick charge mode via the switching circuit,
The power pin and the data pin of the first protocol interface are respectively connected to the power pin and the data pin of the second protocol interface in the synchronous mode, and the power pin of the first protocol interface is The charging converter is connected to the power pin of the second protocol interface in the quick charge mode.   The charging converter according to claim 1, wherein the first protocol interface is a female micro-B USB interface.   The charging converter according to claim 1, wherein the first protocol interface is a male USB interface.   4. The charging converter according to claim 2, wherein the second protocol interface is a 30-pin connector. The switching circuit is
One of the two voltage divider resistors connected in series has a connection node connected to one end of each of the two voltage divider resistors, and the other end of the one voltage divider resistor is connected to the second voltage divider resistor. The other end of the other voltage divider resistor is connected to the ground, and the other is composed of two voltage divider resistors connected in series. Each having one connection node connected to one end, the other end of one of the voltage divider resistors is connected to the power pin of the second protocol interface, and the other end of the other voltage divider resistor is Two voltage divider circuits connected to ground;
Four switch points connected respectively to the data pins of the first protocol interface and the other two to the connection nodes of the two voltage divider circuits of the switching circuit;
One is connected to one of the data pins of the second protocol interface and corresponds to two of the switch points, the other is connected to the other data pin of the second protocol interface, and the switch points 5. The charging converter according to claim 1, further comprising two common points corresponding to the other two.   The switching circuit includes a micro control unit (MCU), and all of the data pins of the first protocol interface and the second protocol interface are connected to the MCU. Item 5. The charging converter according to any one of Item 4.

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