KR101753144B1 - Connector system in which the pin array changes depending on the size of the current - Google Patents

Abstract

The present invention relates to a connector system in which the arrangement of pins is changed according to the magnitude of current.
A controller that manages and controls the connector; a user interface that is configured for an administrator to smoothly manage and control the connector and the controller, the manager having a controller for operating and controlling the controller, An error alarm unit for detecting and detecting an error occurring in the connector and the controller, a monitor unit including a parameter setting unit as a component of the monitor unit, a power supply control unit for generating and connecting power to the power supply control unit, And a power input unit configured to supply power to the controller and to receive a corresponding power from a user interface; a communication input / output unit that performs communication, control, and measurement of the connector and transmits and receives a signal generated by the connector; The arrangement of the pins of the connector corresponding to the current input to the connector And a memory unit for converting the arrangement of the pins determined by the operation unit into a signal and transferring the signal to the connector, and a sensor for preventing overheating of the power source and overheating of the power source used in the connector and the controller, An output section for controlling the connector and the connector and outputting the power supplied to the connector to each of the electronic apparatuses and an overcurrent preventing section for preventing the current flowing into the connector from flowing more than necessary, To a connector system in which the arrangement of the pins is changed according to the magnitude of the current.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a connector system in which an arrangement of pins is changed according to a magnitude of a current,

The present invention relates to a connector system in which the function of a pin is changed according to the magnitude of a current. More particularly, the present invention relates to a connector system in which a connector composed of 19 pins can be continuously used irrespective of the magnitude of a current by organically changing the arrangement of pins according to the current required in a terminal such as a heater.

2. Description of the Related Art [0002] In general, various electric devices such as audio, embedded navigation, TV, and the like used in automobiles are connected to each other by various units for controlling the same through a connector. .

In addition, the connector can be configured differently according to the type and function of the electric parts such as 5-pin, 8-pin, 15-pin, 19-pin, 20-pin, 25-pin and 30-pin, A connector made of 19 pins is used.

Accordingly, Korean Patent Laid-Open Publication No. 2014-0091431 discloses a plug housing having a plurality of receptacle terminal portions, a plurality of posts coupled to the receptacle terminal portions, a socket portion to which the plug housing is coupled, The connector module includes a positioning member which is fixedly coupled to the housing, and on the upper surface of the plug housing, when the shaft portion of the positioning member is engaged, a positioning module receiving member formed therein is formed so as to prevent the positioning member from protruding outside the plug housing There is a bar.

However, according to the above-described prior art documents, the connector module has frequent troubles, and it has been troublesome to replace the connector all the time or change the terminal part differently according to the size of the electric current required for the electric part.

(Patent 0001) Korean Patent Publication No. 2014-0091431

According to the present invention for solving the problems of the related art, a connector composed of 19 pins can be continuously used irrespective of the size of a current, the arrangement of the pins being organically changed according to a current required in a terminal such as a heater, And a connector system in which the function of the pin is changed according to the size of the connector.

Further, according to the present invention, since the arrangement of the pins of the connector is changed organically according to the size of the power source, it can be changed to a circuit optimized for the size of the power source, the power loss is very small, The purpose is to provide.

According to an aspect of the present invention, there is provided a connector comprising: a connector for electrically connecting electrical components; a controller for managing and controlling the connector; and a manager configured to smoothly manage and control the connector and the controller, An error alarm unit for detecting and detecting an error occurring in the connector and the controller, a power supply control unit for controlling power supply to the components of the monitor unit A power supply unit configured to generate power and supply power to the connector and the controller, and a power input unit to receive a corresponding power from the user interface; And transmits a signal generated by the connector And a memory unit for converting the arrangement of the pins determined by the operation unit into a signal and transmitting the signal to the connector. The memory unit includes a communication input / output unit for inputting a signal to the connector, An output unit for controlling the connector and the power source to be used in the connector and the controller to prevent overheating and overheating of the apparatus, And an overcurrent prevention unit for preventing a current flowing into the connector from flowing more than necessary.

The power supply unit may further include a DC rectification unit for guiding the power generated by the power input unit to a voltage, and an overvoltage prevention unit for preventing the voltage generated by the DC rectification unit from being induced to a predetermined voltage or higher.

The sensor unit may further include a sensor input unit for transmitting information sensed by the sensor unit to the monitor unit, an electric power meter for measuring electric power used in the connector and the controller, A power sensing unit for closing the circuit, and an overheat sensing unit for sensing thermal energy generated in the connector and the controller.

Further, the connector is characterized in that the pins of the connector are rearranged in accordance with the sizes of the power sources 5A, 15A and 30A.

In addition, the connector is composed of six input pins and twelve output pins when the size of the power source is 5A, and the arrangement of the pins is rearranged so that power is supplied to the six electronic devices.

The connector is composed of eight input pins and eight output pins when the size of the power source is 15A, and the arrangement of the pins is rearranged so that power is supplied to the four electronic devices.

The connector is composed of eight input pins and eight output pins when the size of the power source is 30A, and the arrangement of the pins is rearranged so that power is supplied to the two electronic devices.

The connector may further include a TC sensor for measuring a temperature inside the connector.

According to the embodiment of the present invention, the connector composed of 19 pins can be continuously used regardless of the size of the power source by organically changing the arrangement of the pins according to the current required in the terminal such as the heater.

Further, according to the embodiment of the present invention, since the arrangement of the pins of the connector is organically changed according to the size of the power source, it is possible to change to a circuit optimized for the size of the power source, the power loss is very small, Can be used.

1 is a pin layout diagram of a connector of a connector system in which the arrangement of pins is changed according to the magnitude of a current according to an embodiment of the present invention,
2 is an overall block diagram of a connector system in which the arrangement of pins is changed according to the magnitude of the current according to the embodiment of the present invention,
FIGS. 3 to 5 are connector block diagrams in which the arrangement of the pins is changed according to 5A, 15A, and 30A of the connector system in which the arrangement of the pins is changed according to the magnitude of the current according to the embodiment of the present invention.
6 is a flowchart of a method of changing the arrangement of fins according to the magnitude of current according to an embodiment of the present invention.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. Prior to this, terms and words used in the present specification and claims should not be construed as limited to ordinary or dictionary terms, and the inventor should appropriately interpret the concepts of the terms appropriately It should be interpreted in accordance with the meaning and concept consistent with the technical idea of the present invention based on the principle that it can be defined. Therefore, the embodiments described in the present specification and the configurations shown in the drawings are only the most preferred embodiments of the present invention, and not all of the technical ideas of the present invention are described. Therefore, It should be understood that various equivalents and modifications are possible.

FIG. 1 is a pin layout diagram of a connector of a connector system in which the arrangement of pins is changed according to the magnitude of a current according to an embodiment of the present invention. FIG. 3 is a block diagram of a connector system according to an embodiment of the present invention; FIG. 5 is a block diagram of a connector block in which the arrangement of pins is changed according to 5A, 15A, and 30A of a connector system, And Fig. 6 is a flowchart of a method of changing the arrangement of fins according to the magnitude of the current according to the embodiment of the present invention.

1 or 2, the connector system in which the arrangement of the pins is changed according to the magnitude of the current is provided with a monitor unit 310 in which an administrator controls and manages the controller 200, A microprocessor unit 350 that performs communication, control, and measurement of the connector 100, and a microprocessor unit 350 that detects the connector 100 and the controller 200 And a control unit 380 for controlling the sensor unit 370 and the connector 100.

The monitor unit 310 is configured to allow the administrator to control and manage the controller 200 and includes a user interface 311, a power management unit 313 for managing the power supply unit 330, a power source An error alarm unit 317 for detecting an error occurring in the controller 200 and informing the user of the error and a parameter setting unit 319 for setting an element of the monitor unit 310 by an administrator.

The user interface 311 is configured such that an administrator can manage and control the controller 200 and is configured such that an administrator can operate the controller 200. [

Here, the controller 200 controls and manages the connector 100 by connecting the plurality of connectors 100, and distributes the power to the electronic device through the connector 100, .

The power management unit 313 and the power control unit 315 are configured to manage and control the power unit 330. Specifically, when the administrator inputs corresponding power through the user interface 311, the power management unit 313 And a power control unit 315. The power supply unit 330 may be configured to generate corresponding power.

The error alarm unit 317 is configured to detect an error that occurs when the administrator operates the controller 200 or when the controller 200 operates and informs the manager of the detected error. Or transmit related data to the user interface 311. However, the present invention is not limited thereto and can be selectively configured.

The parameter setting unit 319 is configured to allow each component of the monitor unit 310 to be set by an administrator and includes a user interface 311, a power management unit 313, a power control unit 315, an error alarm unit 317, And the data can be individually set.

The power supply unit 330 is configured to supply, control, and manage power to the connector 100 and the controller 200 and includes a power input unit 331 for generating power and supplying power to the connector 100 and the controller 200, A DC rectification section 333 for deriving a voltage from the power input section 331 and an overvoltage prevention section 335 for preventing the voltage induced in the DC rectification section 333 from being overpressed.

The power supply input unit 331 generates power for supplying power to the connector 100 and the controller 200 so that the corresponding power is generated by the power management unit 313 and the power control unit 315, .

The DC rectification unit 333 is configured to guide the power generated by the power input unit 331 to a voltage. The DC rectification unit 333 is configured to induce a voltage by constituting a plurality of inductors. In the present invention, The number of the DC rectifying units 333 may be different.

The overvoltage prevention unit 335 senses that a voltage higher than necessary is supplied when the power supply unit 330 supplies the voltage to the connector 100 and the controller 200, (100) and the controller (200).

The microprocessor unit 350 is configured to perform communication, control, and measurement of the connector 100 and includes a communication input / output unit 351 that performs transmission and reception of the connector 100, And a memory unit 355 for converting the arrangement of the pins determined by the calculation unit 353 into signals and transmitting them to the connector 100. [

The communication input / output unit 351 transmits a signal generated by the microprocessor unit 350 to the connector 100 and the controller 200 or receives a control signal generated from the connector 100 and the controller 200 And is configured to transmit the pin control signal generated in the operation unit 353 and the memory unit 355 to the connector 100 and the controller 200. [

When an administrator receives an additional current through the user interface 311, the arithmetic unit 353 performs measurement so that the arrangement of the pins of the connector 100 corresponding to the input current can be rearranged. Accordingly, the number and position of the input pin and the output pin can be rearranged.

Here, the operation unit 353 can be configured such that the administrator can receive the currents of 5A, 15A, and 30A through the user interface 311 and configure the pins of the connector 100 to be rearranged differently according to the magnitude of the current. do.

The memory unit 355 is configured to convert the arrangement of the pins determined by the operation unit 353 into signals and transmit them to the connector 100. Specifically, the operation unit 353 changes the function of the pins of the connector 100 to signals And then transmitted to the connector 100. [

That is, after the microprocessor unit 350 measures the arrangement of the pins of the connector 100 according to the size of the current in the calculation unit 353, Data is converted into a signal and the data can be transmitted to the connector 100 and the controller 200 through the communication input / output unit 351. [

The sensor unit 370 performs a function of detecting over-current and overheating of the current used in the connector 100 and the controller 200, and transmits a signal sensed by each sensor to the controller 200 A power measuring unit 373 for measuring the power used in the connector 100 and the controller 200, a power sensing unit 375 for sensing the current supplied from the power supply unit 330, 100 and an overheat sensing unit 377 for sensing thermal energy generated in the controller 200.

The sensor input unit 371 is configured to transmit information sensed by the power measuring unit 373, the power sensing unit 375 and the overheat sensing unit 377 to the monitor unit 310, To the base station (310).

The power measuring unit 373 is configured to measure the power used in the connector 100 and the controller 200 and can measure the power used in the connector 100 and the controller 200 at all times And is configured to notify the monitor unit 310 of a corresponding power abnormality when an abnormality occurs in the power.

The power sensing unit 375 senses a current supplied from the power supply unit 330 and performs a function of closing the circuit and protecting the device from the device when more than necessary current is sensed. (Not shown), or a separate circuit for returning to the power supply unit 330 may be configured.

The overheat sensing unit 377 senses the thermal energy generated in the connector 100 and the controller 200. When the sensed temperature is higher than the proper temperature, As shown in FIG.

The control unit 380 includes an output unit 381 configured in the connector 100 and controlling all the components of the connector 100 as a whole and outputting current from the pins of the connector 100 to the electronic apparatus, And an overcurrent prevention unit 383 configured to prevent the current from flowing into the electronic device.

The output unit 381 outputs power to a plurality of electronic apparatuses in the controller 200. The overcurrent preventing unit 383 may be configured such that a current more than necessary is not supplied to power a plurality of electronic apparatuses , But is not limited thereto.

The input / output connector unit 385 is configured to allow the power generated by the power supply unit 330 to be input to the connector 100 or the power supplied to the connector 100 to be output to the electronic device.

The connector connection portion 387 is formed inside the controller 200 so that the connector 100 is inserted into the controller 200 and the connector 100 is smoothly operated inside the controller 200 .

The connector 100 is a connection mechanism for connecting an electric device and a cord, a cord and a cord to each other to form an electric circuit. The connector 100 is connected to the inside of the controller 200 to supply a predetermined electric power to a plurality of electric devices , The arrangement of the pins is rearranged according to the setting value of the manager so that it can be optimized according to the current size.

Specifically, the connector 100 includes a first pin 101, a second pin 102, And the 19th pin 119. The pin arrangement of the connector 100 is changed according to the magnitude of the current supplied from the power supply unit 310, that is, the current of 5A15A30A, Even if the size is changed organically, the connector 100 can be continuously used without replacement.

In addition, the connector 100 is rearranged to six input pins and twelve output pins when the current is 5A. When the current is 15A and 30A, the connector 100 rearranges to eight input pins and eight output pins. As shown in FIG.

Specifically, when the magnitude of the current is 5 A, the first pin 101 and the second pin 102 are supplied with power through the first output portion 391, The seventh pin 107 and the eighth pin 108 are connected to the power supply through the third output unit 393 and the seventh pin 107 and the eighth power supply through the third output unit 393, .

The ninth and tenth pins 109 and 110 are powered through the fourth output section 394 and the fourteenth and fifteenth pins 115 and 115 are connected to the fifth output section 395 And the 16th pin 116 and the 117th pin 117 are configured to output power through the sixth output unit 196. [

The fifth pin 105 and the nineteenth pin 119 are configured to receive power through the first inductor 333a and the sixth pin 106 and the eleventh pin 111 are configured to receive power through the second inductor 333b The twelfth pin 112 and the eighteenth pin 118 are configured to be supplied with power through the third inductor 333c and the thirteenth pin 113 is not used or It is configured to be used as ground (GND).

That is, when the magnitude of the current is set to 5 A, the first pin 101, the second pin 102, the third pin 103, the fourth pin 104, the seventh pin 107, The ninth pin 109, the tenth pin 110, the fourteenth pin 114, the fifteenth pin 115, the sixteenth pin 116 and the seventeenth pin 117, (391) to the sixth output unit (396).

When the magnitude of the current is set to 5 A, the fifth pin 105, the sixth pin 106, the eleventh pin 111, the twelfth pin 112, the eighteenth pin 118, 119 are configured to be supplied with the transformed power from the first inductor 333a to the third inductor 333c and the thirteenth pin 113 is not used or can be used as a ground GND.

4, the second pin 102 and the third pin 103 are supplied with power through the first output portion 391, and the seventh pin 107 and the third pin 103 are connected to each other, The eighth pin 108 is connected to the second output unit 392 and the twelfth pin 112 and the 113th pin 113 are connected to the third output unit 393, The seventeenth pin 117 and the eighteenth pin 118 are configured such that power is output through the fourth output portion 394. [

The first pin 101 and the sixth pin 106 are configured to be supplied with power through the first inductor 333a and the fourth pin 104 and the ninth pin 109 are configured to receive power through the second inductor 333b The eleventh pin 111 and the sixteenth pin 116 are configured to be supplied with power through the third inductor 333c and the fourteenth pin 114 and the nineteenth pin 119 are configured to receive power from the fourth inductor 333d.

Further, when the magnitude of the current is 15 A, the fifth pin 105, the tenth pin 110, the fifteenth pin 115 are not used or configured to be used as a ground (GND).

6, the third pin 103, the fourth pin 104, the fifth pin 105, and the sixth pin 106 are connected to the first output portion 391 And the seventeenth pin 114, the fifteenth pin 115, the sixteenth pin 116 and the seventeenth pin 117 are connected to the power output through the second output portion 392 do.

The first pin 101, the second pin 102, the seventh pin 107, the eighth pin 108, the twelfth pin 112, the thirteenth pin 113, the eighteenth pin 118, And the nineteenth pin 119 is configured to receive power through the first inductor 333a.

The ninth pin 109, the tenth pin 110, and the eleventh pin 111 are configured not to be used or to be used as a ground (GND) when the magnitude of the current is 30A .

That is, when the current is 5A, it is composed of 3 inductors and 6 outputs to supply power of 5A from six electronic devices. When the current is 15A, it consists of 4 inductors and 4 outputs And is configured to supply power of 15A from four electronic apparatuses. When the current is 30A, it consists of one inductor and two outputs to supply power of 30A from two electronic apparatuses.

The connector 100 includes a plurality of loads 150 and a TC sensor 170 for measuring the internal temperature of the connector 100. In the present invention, the TC sensor 170 is connected to the RTD sensor Resistor Tempereture Detector).

As shown in FIG. 6, a method of changing the arrangement of the pins according to the magnitude of the current is as follows: inputting a power supply value necessary for the electronic equipment (S410); arranging pins of the connector 100 according to the size of the power supply (S430), and supplying power to the electronic device through the output unit 381 (S450).

The step of inputting the current value (S410) is a step in which the manager inputs the current value corresponding to the electronic device through the controller 200. The administrator can selectively set the current size through the power management unit 313, 5A, 15A, and 30A.

The step S430 of rearranging the pins of the connector 100 according to the size of the power supply is a step in which the pins of the connector 100 are rearranged according to the size of the power set in step S410. In operation S431, six input pins and 12 output pins are arranged to supply power to six electronic devices (S432).

If the administrator inputs 15A in step S410 (S433), it is configured to be able to supply power to the four electronic apparatuses by rearranging them into eight input pins and eight output pins (S434). In step S410, When inputting 30A (S435), eight input pins and eight output pins are arranged to supply power to two electronic devices (S436).

In steps S444 and S446, the eight input pins and the eight output pins may be rearranged differently so that the power supply to the 15A or 30A may be smoothly performed.

After steps S432, S434, and S436 are performed, power is supplied to the electronic device and the number of rearranged output pins (step S450)

Although the present invention has been described in connection with the preferred embodiments thereof with reference to the accompanying drawings, it is to be understood that the present invention is not limited thereto, It is to be understood that various modifications and changes may be made without departing from the scope of the appended claims.

100: connector 200: controller
310: Monitor section 311: User interface
313: power management unit 315: power control unit
317: error alarm unit 319: parameter setting unit
330: power source unit 331: power source input unit
333: DC rectification part 335: Overvoltage prevention part
350: Microprocessor unit 351: Communication input / output unit
353: Operation unit 355:
370: sensor unit 371: sensor input unit
373: Power measuring unit 375: Power sensing unit
377: an overheat detecting unit 380:
381: Output section 383: Overcurrent prevention section
385: input / output connector part 387: connector connection part

Claims (8)

A connector for electrically connecting between the electric parts;
A controller for managing and controlling the connector;
A controller configured to smoothly manage and control the connector and the controller, the controller comprising: a user interface for allowing the manager to operate and control the controller; a power management unit for managing the power source; a power source control unit for controlling the power source; An error alarm unit for detecting and detecting an error occurring in the monitor unit;
A power supply unit configured to generate and supply power to the connector and the controller, and a power input unit to receive a corresponding power from the user interface;
A communication input / output unit for performing communication, control, and measurement of the connector and transmitting / receiving a signal generated by the connector; and an arithmetic unit for measuring and calculating the arrangement of pins of the connector corresponding to the current input to the connector, A microprocessor unit for converting the arrangement of the pins determined by the operation unit into a signal and transmitting the signal to the connector;
A sensor unit for preventing a power source used in the connector and the controller from over-pressure and overheating of the device; And
An output unit for controlling the connector and outputting the power supplied to the connector to each of the electronic apparatuses and an overcurrent preventing unit for preventing the current flowing into the connector from flowing more than necessary;
Lt; / RTI >
Wherein the connector comprises:
Wherein the pin arrangement is changed according to the magnitude of the current, characterized in that the pins of the connector are rearranged in accordance with the sizes of the power sources 5A, 15A and 30A.
The method according to claim 1,
The power supply unit,
A DC rectification part for guiding the power generated by the power input part to a voltage; And
An overvoltage preventing unit for preventing a voltage generated in the DC rectifying unit from being induced to a voltage equal to or higher than a predetermined voltage;
Wherein the pin arrangement is changed according to the magnitude of the current.
The method according to claim 1,
The sensor unit includes:
A sensor input unit for transmitting information sensed by the sensor unit to the monitor unit;
An electric power meter for measuring electric power used in the connector and the controller;
A power sensing unit which closes the circuit when a surplus current is sensed in the connector and the controller; And
An overheat sensing unit for sensing thermal energy generated in the connector and the controller;
Wherein the pin arrangement is changed according to the magnitude of the current.
delete The method according to claim 1,
Wherein the connector comprises:
Wherein the pin arrangement is rearranged so that power is supplied to the six electronic devices when the size of the power source is 5A. The connector system is changed.
The method according to claim 1,
Wherein the connector comprises:
Wherein the pin arrangement is rearranged so that power is supplied to the four electronic devices when the size of the power source is 15A. The connector system is changed.
The method according to claim 1,
Wherein the connector comprises:
Wherein the power supply is composed of 8 input pins and 8 output pins when the size of the power supply is 30A and the arrangement of the pins is rearranged so as to supply power to the two electronic devices. The connector system is changed.
The method according to claim 1,
Wherein the connector comprises:
A TC sensor for measuring a temperature inside the connector;
Wherein the pin arrangement is changed according to the magnitude of the current.

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