KR102684513B1 - Socket and plug type electrical wiring connector, and battery charging system using the same - Google Patents

Abstract

The present invention relates to a socket and plug type electrical wiring connector and a battery charging and discharging system using the same. The socket and plug type electrical wiring connector according to the present invention includes a socket housing (111) including a plug receiving hole 111 of a certain depth on one side. 110), a positive socket terminal 121 and a negative socket terminal, a portion of which is accommodated in the plug receiving hole 111 and the other portion connected to the printed circuit board 10, arranged adjacent to each other within the socket housing 110. (122), and a positive voltage sensing pin 131, a negative voltage sensing pin 132, and a pair of positive voltage miswiring detection pins exposed on the other side of the socket housing 110 and connected to the printed circuit board 10, respectively. A socket connector 100 and a plug housing 210 including (141) and a pair of negative voltage miswiring detection pins 142, protruding from one surface of the plug housing 210 and within the plug receiving hole 111. The insert portion 220, which is inserted, is accommodated within the plug housing 210 and the insert portion 220, and a cable is pressed and fixed at the rear end, and are arranged adjacent to each other within the plug housing 210 and the insert portion 220. a positive plug terminal 231 and a negative plug terminal 232, and a positive miswiring detection resistor 251 and a negative plug terminal 232 disposed adjacent to the positive plug terminal 231 and having a unique first resistance value. It includes a plug connector 200 that is disposed adjacent to and includes a negative miswiring detection resistor 252 having a unique second resistance value.

Description

Socket and plug type electrical wiring connector and battery charging and discharging system using the same {SOCKET AND PLUG TYPE ELECTRICAL WIRING CONNECTOR, AND BATTERY CHARGING SYSTEM USING THE SAME}

The present invention relates to an electrical wiring connector and a battery charging and discharging system using the same. More specifically, a socket and plug type electrical wiring connector that not only simplifies electrical wiring but also detects miswiring of the electrical wiring, and a battery using the same. It is about the charging and discharging system.

Most electronic devices have components connected through very diverse and complex electrical wiring.

1 is a diagram showing a conventional electrical wiring structure.

Referring to Figure 1, conventionally, the bolt fastening method was mostly used for electrical wiring. That is, the BR terminal 21, which is soldered to the printed circuit board 10 and has a screw hole, is fixed to the printed circuit board 10, and the wiring crimp terminal 22 is connected to the cables (electrical lines) 31 and 32. The electrical wiring was made by fixing ) to the BR terminal (21) using a bolt (40). In this conventional electrical wiring structure, wiring is performed by fastening bolts to each cable, making the electrical wiring process inconvenient and cumbersome, and furthermore, the efficiency of the electrical wiring work is low and it takes a lot of time.

Additionally, there is a problem in that it cannot be confirmed whether electrical wiring is miswired until the electronic device does not operate normally or a malfunction occurs. For example, if the electrical wiring in the battery charger/discharger is incorrectly wired, the user cannot confirm whether the wiring was incorrect until the battery is overcharged or a fire occurs.

Korean Patent Publication KR10-2018-0116031 (2018.10.24), pages 2 to 4

The present invention provides a socket and plug type electrical wiring connector that simplifies the wiring process of positive and negative cables and further improves the convenience of wiring work, and a battery charging and discharging system using the same.

The present invention provides a socket and plug type electrical wiring connector that can prevent device failure (e.g., overcharging, fire, etc. in the case of batteries) due to physical miswiring, and a battery charging and discharging system using the same.

The present invention provides a socket and plug type electrical wiring connector capable of controlling charge/discharge current by sensing battery voltage, and a battery charge/discharge system using the same.

The socket and plug type electrical wiring connector according to the present invention includes a socket housing 110 including a plug receiving hole 111 of a certain depth on one side, a portion of which is accommodated in the plug receiving hole 111, and the other portion is a printed circuit board. The positive socket terminal 121 and the negative socket terminal 122 are connected to (10) and disposed adjacent to each other within the socket housing 110, and are exposed to the other side of the socket housing 110, respectively, to form a printed circuit board 10. ) A socket connector including a positive voltage sensing pin 131, a negative voltage sensing pin 132, a pair of positive voltage miswiring detection pins 141, and a pair of negative voltage miswiring detection pins 142 connected to ). (100) and the plug housing 210, the insert portion 220 protruding from one surface of the plug housing 210 and inserted into the plug receiving hole 111, the plug housing 210 and the insert portion 220 A positive plug terminal 231, a negative plug terminal 232, and a positive plug terminal 231 are accommodated within, the cable is pressed and fixed at the rear end, and are disposed adjacent to each other within the plug housing 210 and the insert portion 220. ) and a positive miswiring detection resistor 251 disposed adjacent to and having a unique first resistance value, and a negative miswiring detection resistor 252 disposed adjacent to the negative plug terminal 232 and having a unique second resistance value. It includes a plug connector 200 including.

In one embodiment, the positive socket terminal 121 and the negative socket terminal 122 each have first terminal connection areas 1211 and 1221 that are inserted into and received in the plug receiving hole 111 and the first terminal connection. It includes first substrate connection areas 1212 and 1222 that are bent in a direction perpendicular to the areas 1211 and 1221 and exposed to the outside of the socket housing 110, and the first terminal connection areas 1211 and 1221 are It is connected to the plug terminals 231 and 232, and the first board connection areas 1212 and 1222 can be connected to the printed circuit board 10.

In one embodiment, a guide protrusion 111c is provided on one side of the plug receiving hole 111 and extends in the depth direction of the plug receiving hole 111 to guide the insertion of the insert portion 220, and the insert The part 220 may be provided with a guide groove 221 into which the guide protrusion 111c is inserted.

In one embodiment, the anode voltage sensing pin 131 and the cathode voltage sensing pin 132 each have a second substrate connection area 1311 and 1321 exposed to the outside of one surface of the socket housing 110 and the second It includes second connection areas (1312, 1322) extending from the board connection areas (1311, 1321) and exposed to the outside of the other side of the socket housing (110), and the second connection areas (1312, 1322) are connected to the plug connector. They are connected to the anode and cathode of the battery, respectively, through the first plug connection pins 261 and 262 of 200, and the second board connection areas 1311 and 1321 can be connected to the printed circuit board 10. .

In one embodiment, the pair of anode voltage miswiring detection pins 141 are connected to third board connection areas 1411a and 1411b exposed to the outside of one surface of the socket housing 110 and the third board connection area 1411a. , 1411b) and includes third connection areas 1412a and 1412b exposed to the outside of the other surface of the socket housing 110, and the third connection areas 1412a and 1412b are 1 of the plug connector 200. It is connected to the anode miswiring detection resistor 251 through a pair of second plug connection pins 241, and the third board connection areas 1411a and 1411b are connected to the printed circuit board 10, and the pair of The negative voltage miswiring detection pin 142 extends from the fourth board connection area (1421a, 1421b) and the fourth board connection area (1421a, 1421b) exposed to the outside of one side of the socket housing 110 to connect the socket to the socket. It includes a fourth connection area (1422a, 1422b) exposed to the outside of the other surface of the housing 110, and the fourth connection area (1422a, 1422b) is a pair of third plug connection pins of the plug connector 200 ( It is connected to the cathode miswiring detection resistor 252 through 242), and the fourth board connection area (1421a, 1421b) can be connected to the printed circuit board (10).

In one embodiment, the positive voltage sensing pin 131 and the pair of positive voltage miswiring detection pins 141 are disposed adjacent to the positive socket terminal 121, and the negative voltage sensing pin 132 and The pair of negative voltage miswiring detection pins 142 may be disposed adjacent to the negative socket terminal 122.

The battery charging and discharging system according to the present invention includes a power source that supplies charging current through electrical wiring, a socket and plug-type electrical wiring connector consisting of a socket connector connected to the electrical wiring and a plug connector connected to the battery, and charging and discharging of the battery. A control unit that controls, wherein the socket connector of the socket and plug type electrical wiring connector includes a miswiring detection pin, and the plug connector of the socket and plug type electrical wiring connector includes a miswiring detection resistor having a unique resistance value. Including, when the socket connector and the plug connector are electrically connected, the miswiring detection pin and the miswiring detection resistor are electrically connected, and when a preset voltage is applied to the miswiring detection pin of the socket connector, the miswiring detection pin and the miswiring detection resistor are electrically connected. The control unit determines whether the socket connector and the plug connector are miswired based on the voltage output through the miswiring detection resistor.

In one embodiment, the socket connector may include a pair of positive voltage miswiring detection pins and a pair of negative voltage miswiring detection pins.

In one embodiment, the plug connector may include a positive voltage line miswiring detection resistor having a first specific resistance value and a negative voltage line miswiring detection resistor having a second specific resistance value.

In one embodiment, when the socket connector and the plug connector are electrically connected, the pair of positive voltage miswiring detection pins are electrically connected to the positive voltage line miswiring detection resistor, and the pair of negative voltage line miswiring detection pins are electrically connected to the positive voltage line miswiring detection resistor. The detection pin may be electrically connected to the negative voltage line miswiring detection resistor.

In one embodiment, the socket connector includes a positive voltage sensing pin and a negative voltage sensing pin, and when the socket connector and the plug connector are electrically connected, the positive voltage sensing pin and the negative voltage sensing pin connect the plug connector. They can be electrically connected to the positive and negative electrodes of the battery, respectively.

In one embodiment, when the socket connector and the plug connector are electrically connected, the control unit charges the battery based on the positive and negative voltages of the battery detected through the positive and negative voltage sensing pins. Discharge can be controlled.

In one embodiment, when the voltage output through the miswiring detection resistor is outside the voltage value range corresponding to the miswiring detection resistance of the plug connector, the control unit determines that the socket connector and the plug connector are miswired. You can.

As described above, the socket and plug type electrical wiring connector according to the present invention and the battery charging and discharging system using the same can simplify the wiring process of the positive and negative cables and further improve the convenience of wiring work.

The socket and plug type electrical wiring connector and the battery charging and discharging system using the same according to the present invention can prevent device failure (for example, overcharging of batteries, fire, etc.) due to physical miswiring.

The socket and plug type electrical wiring connector according to the present invention and the battery charging and discharging system using the same can control charging and discharging current by sensing the battery voltage.

1 is a diagram showing a conventional electrical wiring structure.
Figure 2 is a perspective view showing the configuration of a socket and plug-type electrical wiring connector according to an embodiment of the present invention.
Figure 3 is an exploded perspective view showing the configuration of the socket connector shown in Figure 2
Figure 4 is a diagram showing a front view of the socket connector shown in Figure 2
Figure 5 is a view showing the rear view of the socket connector shown in Figure 2
Figure 6 is an exploded perspective view showing the configuration of the plug connector shown in Figure 2
Figure 7 is a view showing the rear view of the plug connector shown in Figure 2
Figure 8 is a perspective view showing the socket connector and plug connector shown in Figure 2 fastened.
Figure 9 is a perspective view showing a state in which positive and negative cables are wired using a socket and plug-type electrical wiring connector according to an embodiment of the present invention.
Figure 10 is a diagram schematically showing the circuit connection of a battery charging and discharging system using a socket and plug-type electrical wiring connector according to an embodiment of the present invention.

Hereinafter, specific details for implementing the socket and plug type electrical wiring connector and the battery charging and discharging system using the same according to the present invention will be described as follows.

FIG. 2 is a perspective view showing the configuration of a socket and plug-type electrical wiring connector according to an embodiment of the present invention, FIG. 3 is an exploded perspective view showing the configuration of the socket connector shown in FIG. 2, and FIG. 4 is shown in FIG. 2. FIG. 5 is a view showing the rear view of the socket connector shown in FIG. 2, FIG. 6 is an exploded perspective view showing the configuration of the plug connector shown in FIG. 2, and FIG. 7 is a view showing the front view of the socket connector shown in FIG. It is a view showing the back of the plug connector shown in FIG. 2, FIG. 8 is a perspective view showing the socket connector and plug connector shown in FIG. 2 fastened, and FIG. 9 is a socket and a plug connector according to an embodiment of the present invention. This is a perspective view showing the positive and negative cables being wired using a plug-type electrical wiring connector.

2 to 9, a socket and plug type electrical wiring connector according to an embodiment of the present invention includes a socket connector 100 and a plug connector 200.

The socket connector 100 may include a socket housing 110, a positive socket terminal 121, and a negative socket terminal 122.

The socket housing 110 may have an overall shape of a rectangular parallelepiped and may include a plug receiving hole 111.

The plug receiving hole 111 has a certain depth from the front to the back of the rectangular parallelepiped shape of the socket housing 110. The inlet 111a of the plug receiving hole 111 is open, and a positive socket terminal 121 and a negative socket terminal 122 are provided on the bottom surface 111b of the plug receiving hole 111 opposite the inlet 111a. A pair of terminal insertion holes 112 for insertion may be formed.

The positive socket terminal 121 and the negative socket terminal 122 may be cylindrical, and a portion of the cylinder is accommodated in the plug receiving hole 111 and disposed adjacent to each other within the plug receiving hole 111. Each of the positive socket terminal 121 and the negative socket terminal 122 may include terminal connection areas 1211 and 1221 and first substrate connection areas 1212 and 1222. The terminal connection areas (1211, 1221) are inserted into and accommodated in the plug receiving hole (111), and the first board connection areas (1212, 1222) are bent in a direction perpendicular to the terminal connection areas (1211, 1221) to form a socket housing. It may be exposed to the outside of (110).

The positive voltage sensing pin 131 is placed adjacent to the positive socket terminal 121, and the negative voltage sensing pin 132 is placed adjacent to the negative socket terminal 122. Each of the positive voltage sensing pin 131 and the negative voltage sensing pin 132 may be exposed toward the rear side of the rectangular parallelepiped shape of the socket housing 110.

Each of the anode voltage sensing pin 131 and the cathode voltage sensing pin 132 may include second substrate connection areas 1311 and 1321 and second connection areas 1312 and 1322. The second substrate connection areas 1311 and 1321 may be bent in a direction perpendicular to the second connection areas 1312 and 1322 and exposed to the outside of the rear surface of the socket housing 110. The second connection areas 1312 and 1322 may extend from the second board connection areas 1311 and 1321 in the front direction and be exposed to the outside of the front of the socket housing 110 .

A pair of positive voltage miswiring detection pins 141 and a pair of negative voltage miswiring detection pins 142 are arranged between the positive socket terminal 121 and the negative socket terminal 122, and a pair of positive voltage miswiring detection pins 142 are disposed between the positive socket terminal 121 and the negative socket terminal 122. The wiring detection pin 141 is placed adjacent to the positive socket terminal 121, and a pair of negative voltage miswiring detection pins 142 are placed adjacent to the negative socket terminal 122.

Each of the pair of positive voltage miswiring detection pins 141 and the pair of negative voltage miswiring detection pins 142 may be exposed toward the rear of the rectangular parallelepiped shape of the socket housing 110.

A pair of anode voltage miswiring detection pins 141 may include third substrate connection areas 1411a and 1411b and third connection areas 1412a and 1412b. The third substrate connection areas 1411a and 1411b may be bent in a direction perpendicular to the third connection areas 1412a and 1412b and exposed to the outside of the rear surface of the socket housing 110. The third connection areas 1412a and 1412b may extend from the third substrate connection areas 1411a and 1411b in the front direction and be exposed to the outside of the front of the socket housing 110.

A pair of negative voltage miswiring detection pins 142 may include fourth substrate connection areas 1421a and 1421b and fourth connection areas 1422a and 1422b. The fourth substrate connection areas 1421a and 1421b may be bent in a direction perpendicular to the fourth connection areas 1422a and 1422b and exposed to the outside of the rear surface of the socket housing 110. The fourth connection areas 1422a and 1422b may extend from the fourth substrate connection areas 1421a and 1421b in the front direction and be exposed to the outside of the front of the socket housing 110.

As an example in the drawing, the positions of the anode voltage sensing pin 131, the cathode voltage sensing pin 132, a pair of anode voltage miswiring detection pins 141, and a pair of cathode voltage miswiring detection pins 142 are one. This is an example, and the location may be implemented differently depending on the implementation example.

The plug connector 200 may be fastened to the socket housing 110 to be electrically connected. The plug connector 200 may include a plug housing 210, an insert portion 220, a positive plug terminal 231, and a negative plug terminal 232.

The plug housing 210 may have an overall shape of a rectangular parallelepiped, and its size may correspond to the rectangular shape of the socket housing 110.

The insert portion 220 may protrude from one side of the plug housing 210, for example, from the rectangular parallelepiped-shaped rear surface of the plug housing 210, and may have the shape and shape of the plug receiving hole 111 of the socket housing 110. It has a shape and size corresponding to the size and can be inserted into the plug receiving hole 111.

The positive plug terminal 231 and the negative plug terminal 232 may be accommodated within the plug housing 210 and the insert portion 220 and arranged adjacent to each other. At this time, the separation distance between the positive plug terminal 231 and the negative plug terminal 232 may be less than the distance between the positive socket terminal 121 and the negative socket terminal 122. The positive plug terminal 231 and the negative plug terminal 232 may have a hollow cylindrical shape, and the hollow has a diameter that can accommodate the positive socket terminal 121 and the negative socket terminal 122. The positive socket terminal 121 and the negative socket terminal 122 may be inserted into the positive plug terminal 231 and the negative plug terminal 232, respectively.

The positive plug terminal 231 and a portion of each of the positive plug terminals 231 may protrude to the opposite side of the protruding direction of the insert portion 220 and be exposed to the outside of the plug housing 210, and the exposed portion may be exposed to the outside of the plug housing 210. The anode cable 31 and the cathode cable 32 may be pressed and fixed to some lengths.

The plug connector 200 is disposed adjacent to the positive plug terminal 231 and has a unique first resistance value, and a positive miswiring detection resistor 251 is disposed adjacent to the negative plug terminal 232 and has a unique second resistance value. It includes a negative miswiring detection resistor 252 having a value. In one embodiment, the first resistance value and the second resistance value may be determined in advance by the manufacturer and may have different values.

The plug connector 200 includes first plug connection pins 261 and 262, a pair of second plug connection pins 241, and a pair of third plug connection pins 242. The first plug connection pins 261 and 262 may be located in the plug housing 210 corresponding to the positions of the positive voltage sensing pin 131 and the negative voltage sensing pin 132 of the socket housing 110.

A pair of second plug connection pins 241 and a pair of third plug connection pins 242 are respectively connected to a pair of positive voltage miswiring detection pins 141 and a pair of negative voltage error detection pins of the socket housing 110. It may be located in the plug housing 210 in correspondence with the position of the wiring detection pin 142. In another embodiment, a pair of second plug connection pins 241 and a pair of third plug connection pins 242 each correspond to a pair of positive voltage miswiring detection pins 141 and a pair of negative voltage miswiring detection pins 141. It may be located within the insert portion 220 corresponding to the position of the sensing pin 142. A pair of second plug connection pins 241 may be connected to the positive miswiring detection resistor 251, and a pair of negative voltage miswiring detection pins 142 may be connected to the negative miswiring detection resistor 252. You can.

Meanwhile, the plug receiving hole 111 may include a guide protrusion 111c, and the insert portion 220 may include a guide groove 221.

The guide protrusion 111c may be formed on one side of the plug receiving hole 111, for example, at the lower center of the plug receiving hole 111, extending in the depth direction of the plug receiving hole 111.

The guide groove 221 is formed on one side, for example, a lower surface of the insert portion 220, extending in the protruding direction of the insert portion 220, and the insert portion 220 is positioned in the plug receiving hole 111. ), the guide protrusion 111c may be inserted.

These guide protrusions 111c and guide grooves 221 guide the insertion of the insert portion 220 when the insert portion 220 is inserted into the plug receiving hole 111.

Meanwhile, the socket housing 110 may include a restraining hole 113, and the insert portion 220 may include a restraining protrusion 222.

The restraining hole 113 may be formed on one surface of the socket housing 110, for example, on the upper surface of the socket housing 110. There may be at least one restraining hole 113, for example, two.

The restraining protrusion 222 may be formed on one surface of the insert portion 220, for example, on the upper surface of the insert portion 220 in contact with the upper surface of the socket housing 110. The number of restraining protrusions 222 may be at least one, for example, two.

The restraining protrusion 222 is fastened to the restraining hole 113 when the insert portion 220 is inserted into the plug receiving hole 111, and is used for fastening of the restraining hole 113 and the restraining protrusion 222. As a result, the insertion state of the insert portion 220 may be restricted.

Meanwhile, the socket housing 110 may further include a protrusion receiving groove 114, and the plug housing 210 may further include a flow prevention protrusion 211.

The protrusion receiving groove 114 may be formed at the end of the inlet 111a of the plug receiving hole 111 of the socket housing 110.

The flow prevention protrusion 211 may protrude from a surface perpendicular to the upper surface of the insert portion 220, that is, a surface disposed at a right angle to the upper surface of the insert portion 220, and the insert portion 220 may be positioned at a right angle to the upper surface of the insert portion 220. When inserted into the plug receiving hole 111, it may be inserted into the protrusion receiving groove 114. These flow prevention protrusions 211 can prevent left and right movement when the plug housing 210 is coupled to the socket housing 110.

Meanwhile, the plug housing 210 may further include a grip protrusion 212 protruding from the upper surface of the plug housing 210. The grip protrusion 212 may be disposed behind the anti-flow protrusion 211 and can prevent the user's hand from slipping when connecting or disconnecting the plug connector 200 from the socket connector 100. .

Hereinafter, a description will be given of how the socket and plug type electrical wiring connector according to an embodiment of the present invention is fastened for connection and wiring of the positive cable 31 and the negative cable 32.

The socket connector 100 is fixed on the printed circuit board 10 by connecting a positive socket terminal 121 and a negative socket terminal 122 to the printed circuit board 10. At this time, the first board connection areas 1212 and 1222 exposed to the outside of the socket housing 110 of the positive socket terminal 121 and the negative socket terminal 122 are connected to the printed circuit board 10, and the positive voltage sensing pin The second board connection areas 1311 and 1321 exposed to the outside of the socket housing 110 of the cathode voltage sensing pin 131 and 132 are connected to the printed circuit board 10.

In addition, the third board connection area (1411a, 1411b) of the positive voltage miswiring detection pin 141 is exposed to the outside of the socket housing 110, and the negative voltage miswiring detection pin 142 is exposed to the outside of the socket housing 110. The fourth substrate connection areas 1421a and 1421b are connected to the printed circuit board 10.

The plug connector 200 is a socket fixed on the printed circuit board 10 with the positive cable 31 connected to the positive plug terminal 231 and the negative cable 32 connected to the negative plug terminal 232. It is fastened to the connector 100. In one embodiment, positive cable 31 may be connected to the positive pole of the battery and negative cable 32 may be connected to the negative pole of the battery. In another embodiment, the positive plug terminal 231 and the negative plug terminal 232 may be directly connected to the positive electrode and negative electrode of the battery, respectively, without connecting a cable. In this case, the positive plug terminal 231 and the negative plug terminal 232 may have terminal sizes and shapes corresponding to the positive and negative electrodes of the battery so that they can be directly connected to the positive and negative electrodes of the battery.

That is, the insert portion 220 of the plug connector 200 is inserted into the plug receiving hole 111 of the socket connector 100, and at this time, the positive socket terminal is inside the positive plug terminal 231 and the negative plug terminal 232. (121) and the negative socket terminal 122 are inserted to establish electrical connection between the plug connector 200 and the socket connector 100.

The second connection areas 1312 and 1322 of the positive voltage sensing pin 131 and the negative voltage sensing pin 132 are connected to the positive and negative poles of the battery, respectively, through the first plug connection pins 261 and 262 of the plug connector 200. It is connected to In one embodiment, the first plug connection pins 261 and 262 may be connected to the positive and negative poles of the battery, respectively, through separate connection lines. In another embodiment, the first plug connection pins 261 and 262 may be exposed to the outside of the plug housing 210 and directly connected to the positive and negative electrodes of the battery, respectively, through the exposed areas.

The third connection areas (1412a, 1412b) of the anode voltage miswiring detection pin 141 are connected to the anode miswiring detection resistor 251 through a pair of second plug connection pins 241 of the plug connector 200. , the fourth connection areas 1422a and 1422b of the negative voltage miswiring detection pin 142 are connected to the negative miswiring detection resistor 252 through a pair of third plug connection pins 242 of the plug connector 200. do.

Meanwhile, when the insert portion 220 of the plug connector 200 is inserted into the plug receiving hole 111 of the socket connector 100, the plug receiving hole 111 is inserted into the guide groove 221 of the insert portion 220. ) As the inner guide protrusion 111c is inserted, the insert portion 220 is inserted into the plug receiving hole 111, and the restraining protrusion 222 formed on the insert portion 220 is connected to the restraining hole formed on the socket housing 110 ( 113), so that the inserted state of the insert portion 220 is restricted.

In addition, the flow prevention protrusion 211 of the plug housing 210 is inserted into the protrusion receiving groove 114 of the socket housing 110 to prevent the plug housing 210 from moving left and right.

Figure 10 is a diagram schematically showing the circuit connection of a battery charging and discharging system using a socket and plug-type electrical wiring connector according to an embodiment of the present invention.

Referring to FIG. 10, FIG. 10 is a diagram showing the circuit connection of a two-channel battery charging and discharging system that can charge two batteries by connecting two sockets and plug-type electrical wiring connectors to one printed circuit board 10. am. In another embodiment, the battery charging and discharging system may consist of two or more multiple channels. Hereinafter, for convenience of explanation, a two-channel battery charging and discharging system will be used as an example.

The socket connectors 100a and 100b of the socket and plug type electrical wiring connectors are connected to the electrical wiring of the printed circuit board 10, and the plug connectors 200a and 200b are connected to the batteries 501 and 502.

The positive electrical wiring is electrically connected to the positive electrode of the battery 501 through the socket connector 100a and the plug connector 200a (50a), and the negative electrical wiring is electrically connected to the battery 501 through the socket connector 100a and the plug connector 200a. It is electrically connected to the cathode of (501) (51a). The cable is connected to a power source (not shown), and the power supply supplies a charging current of 100A to the battery 501 through the cable.

The positive voltage sensing pin 131 and the negative voltage sensing pin 132 are electrically connected to the control unit 701 of the printed circuit board 10 (52a, 53a). The control unit 701 controls charging and discharging of the battery 501 based on the positive and negative voltages of the battery 501 detected through the positive voltage sensing pin 131 and the negative voltage sensing pin 132. For example, the control unit 701 may maintain charging based on the positive and negative voltages of the battery 501, and when it exceeds a preset voltage level, it may short-circuit the power to stop charging the battery 501. . Alternatively, when an abnormal state occurs, such as when the anode voltage and cathode voltage of the battery 501 are unstable or when there is no change in the anode voltage and cathode voltage of the battery 501 for a certain period of time, the control unit 701 sends an abnormal state report. Create and record or create a notification. The abnormal state report may include the battery channel in which the abnormal state occurred, the occurrence time, and battery positive and negative voltage information.

A pair of anode voltage miswiring detection pins 141 are connected to the anode miswiring detection resistor 251a through the socket connector 100a and the plug connector 200a, and are connected to the first voltage detection element of the printed circuit board 10. It is electrically connected to (601a) to form a closed circuit (54a). In one embodiment, the first voltage sensing element 601a may correspond to a diode or switch having a preset unique operating voltage value. The first voltage sensing element 601a may be connected to the control unit 701.

When a closed circuit is formed (54a), power is applied to the circuit through the first power source 603a, and a voltage drop occurs at the anode miswiring detection resistor 251a. Since the first power source 603a has a preset voltage value and current value, and the anode miswiring detection resistor 251a has a first specific resistance value, the voltage drop in the anode miswiring detection resistor 251a is constant. It can have a value. The control unit 701 may determine whether there is a miswiring based on the voltage value output by the voltage drop at the anode miswiring detection resistor 251a.

When the voltage output through the anode miswiring detection resistor 251a is the same as the operating voltage of the first voltage sensing element 601a (or when the output voltage is within the operating voltage range of the first voltage sensing element 601a) ), the first voltage sensing element 601a may transmit an operation signal to the control unit 701. When an operation signal is received, the control unit 701 may determine that the correct cable is connected to the voltage wiring connected to the voltage sensing element through which the operation signal was received. For example, when an operation signal is received from the first voltage sensing element 601a, the control unit 701 connects the correct socket connector 100a to the plug connector 200a connected to the positive voltage of the first battery 501. It can be determined that the correct wiring (for example, wiring matching the specifications of the corresponding connector) is connected to the plug connector 200a connected to the positive voltage of the first battery 501. Accordingly, the control unit 701 may determine that the correct cable is connected to the positive voltage of the first battery 501.

When the voltage output through the anode miswiring detection resistor 251a is different from the operating voltage of the first voltage sensing element 601a (or when the output voltage is outside the operating voltage range of the first voltage sensing element 601a) ), the first voltage sensing element 601a does not operate, and the first voltage sensing element 601a does not transmit an operating signal to the control unit 701. When the operation signal is not received, the control unit 701 may determine that an incorrect cable is connected (miswired) to the plug connector connected to the voltage sensing element from which the operation signal is not received.

In one embodiment, when the positive and negative voltages of the battery are sensed through the positive and negative voltage sensing pins, the control unit 701 confirms that the cable is connected to the battery and determines whether or not there is miswiring. . For example, when the positive and negative voltages of the battery 501 are detected through the positive voltage sensing pin 131 and the negative voltage sensing pin 132, it is confirmed that the cable is connected to the battery 501, and the first voltage When an operation signal is not received from the sensing element 601a, the control unit 701 may determine that the anode voltage of the first battery 501 is miswired.

A pair of negative voltage miswiring detection pins 142 are connected to the negative miswiring detection resistor 252a through the socket connector 100a and the plug connector 200a, and the second voltage sensing element of the printed circuit board 10 It is electrically connected to (602a) to form a closed circuit (55a). In one embodiment, the second voltage sensing element 602a may correspond to a diode or switch having a preset unique operating voltage value. The second voltage sensing element 602a may be connected to the control unit 701.

When a closed circuit is formed (55a), power is applied to the circuit through the second power source 604a, and a voltage drop occurs at the negative miswiring detection resistor 252a. Since the second power source 604a has a preset voltage value and current value, and the negative miswiring detection resistor 252a has a second specific resistance value, the voltage drop at the negative miswiring detection resistor 252a is constant. It can have a value. The control unit 701 may determine whether there is a miswiring based on the voltage value output as a result of the voltage drop at the cathode miswiring detection resistor 252a. The process of determining whether there is a miswiring is the same as that described with respect to the anode voltage miswiring detection pin 141 and the first voltage sensing element 601a.

The circuits 54b and 55b of the second channel connected to the second battery 502 have the same operating method as the circuits 54a and 55b of the first channel. In one embodiment, each miswiring detection resistor 251a, 252a, 251b, and 252b may have a different specific resistance value. Each voltage sensing element (601a, 602a, 601b, 602b) has a different operating voltage, and may have an operating voltage corresponding to the miswiring detection resistor (601a, 602a, 601b, 602b) when the correct cable is connected. The manufacturer manufactures each plug connector 200 with miswiring detection resistors 251a, 252a, 251b, and 252b, each having a different specific resistance value, and the voltage detection elements 601a, 602a, 601b, and 602b are connected to the correct cable. When connected, it can be manufactured by setting the operating voltage corresponding to the miswiring detection resistors 601a, 602a, 601b, and 602b.

For example, the first power source 603a, the second power source 604a, the third power source 603b, and the fourth power source 604b supply currents of 5V and 100A to the circuit, respectively, and the first power supply of the first channel The anode miswiring detection resistor 251a has a resistance value of 0.02Ω, the first negative miswiring detection resistor 252a of the first channel has a resistance value of 0.025Ω, and the second anode miswiring detection resistor 251b of the second channel has a resistance value of 0.025Ω. It is assumed that is designed to have a resistance value of 0.03Ω, and the second cathode miswiring detection resistor 252b of the second channel is designed to have a resistance value of 0.045Ω.

In addition, the first voltage sensing element 601a associated with the positive voltage wiring of the first channel has an operating voltage of 3V, and the second voltage sensing element 602a associated with the negative voltage wiring of the first channel has an operating voltage of 2.5V. The third voltage sensing element 601b, which has an operating voltage and is connected to the positive voltage wiring of the second channel, has an operating voltage of 2V, and the fourth voltage sensing element 602b, connected to the negative voltage wiring of the second channel, is Assume that it is designed to have an operating voltage of 1.5V. The operating voltage value of each voltage sensing element 601a, 602a, 601b, and 602b may be set to an operating voltage range.

Assuming that the correct cable is connected, when the socket connector 100a connected to the positive voltage wiring of the first channel is connected to the plug connector 200a connected to the positive voltage of the first channel battery, the first power source 603a, 1 The voltage sensing element 601a and the first anode miswiring detection resistor 251a form a closed circuit. When a current of 100A flows through the first power source 603a, a voltage drop of 2V occurs in the first anode miswiring detection resistor 251a, and the voltage output through the first anode miswiring detection resistor 251a is 3V. A voltage of 3V is applied to the first voltage sensing element 601a, and since the first voltage sensing element 601a has an operating voltage of 3V, the first voltage sensing device 601a transmits an operating signal to the control unit 701. When an operation signal is received from the first voltage sensing element 601a, the control unit 701 may determine that the correct cable is connected to the line of the corresponding channel.

When the socket connector 100a connected to the negative voltage wiring of the first channel is connected to the plug connector 200a connected to the negative voltage of the first channel battery, when a current of 100A flows through the second power source 604a, the first negative voltage is A voltage drop of 2.5V occurs at the wiring detection resistor 252a, and the voltage output through the first cathode miswiring detection resistor 252a is 2.5V. A voltage of 2.5V is applied to the second voltage sensing element 602a, and since the second voltage sensing element 602a has an operating voltage of 2.5V, the second voltage sensing element 602a transmits an operating signal to the control unit 701. do.

Assuming a miswiring case, when the socket connector 100b connected to the positive voltage wiring of the second channel is connected to the plug connector 200a connected to the positive voltage of the first channel battery, the third power source 603b, the third power supply 603b The voltage sensing element 601b and the first anode miswiring detection resistor 251a form a closed circuit. When a current of 100A flows through the third power source 603b, a voltage drop of 2V occurs in the first voltage sensing element 601a, and the voltage output through the first voltage sensing element 601a is 3V. A voltage of 3V is applied to the third voltage sensing element 601b, and the third voltage sensing element 601b has an operating voltage of 2V, so the third voltage sensing element 601b does not transmit an operating signal to the control unit 701. . If an operation signal is not received from the third voltage sensing element 601b, the control unit 701 may determine that the line of the corresponding channel is miswired.

In one embodiment, the positive and negative voltages of the battery are detected through the positive voltage sensing pin and the negative voltage sensing pin to confirm that the cable is connected to the battery, and an operation signal is received from the third voltage sensing element 601b for a preset time. If is not received, the control unit 701 may determine that the line of the corresponding channel is miswired.

The control unit 701 can display on the screen whether each channel and each wire are miswired using an operation signal received from a voltage sensing element associated with each channel and each wire. Alternatively, the control unit 701 may generate a notification regarding the channel and wiring location where miswiring occurs and inform the user of the location of miswiring.

In one embodiment, if it is not confirmed that the correct cable is connected for a preset period of time after notification of the miswiring location, the control unit 701 may stop charging the battery corresponding to the miswiring location. In another embodiment, when it is determined that miswiring is connected, the control unit 701 may control charging of the battery by sensing the voltage of the battery corresponding to the location of miswiring through the positive voltage sensing pin and the negative voltage sensing pin. . For example, the control unit 701 senses the voltage of the battery corresponding to the location where the miswiring occurs through the positive voltage sensing pin and the negative voltage sensing pin, and detects when the voltage level of the battery exceeds the threshold. Only in this case can you stop charging the battery by short-circuiting the charging power source. The threshold value may be a preset value or a value that changes in proportion to the capacity of the battery to be charged.

By using the socket and plug type electrical wiring connector according to an embodiment of the present invention, the wiring process of the positive and negative cables is simpler than the conventional method of connecting terminals by bolting for wiring the positive and negative cables. There is an advantage that the convenience of wiring work can be improved. In addition, using the socket and plug-type electrical wiring connector according to an embodiment of the present invention has the advantage of preventing device failure (e.g., overcharging of batteries, fire, etc.) due to physical miswiring. There is.

Although the present invention has been described as an embodiment of the present invention, the technical idea of the present invention is not limited to the above embodiment, and various socket and plug-type electrical wiring connectors and battery charging and discharging systems using the same are provided without departing from the technical idea of the present invention. It can be implemented.

10: printed circuit board
31, 32: Cable (electrical cable)
100: socket connector
200: plug connector

Claims (13)

A socket housing 110 including a plug receiving hole 111 of a certain depth on one side, a portion of which is accommodated in the plug receiving hole 111 and another portion connected to a printed circuit board 10, and the socket housing 110 A positive socket terminal 121 and a negative socket terminal 122 disposed adjacent to each other within, and a positive voltage sensing pin 131 exposed to the other side of the socket housing 110 and connected to the printed circuit board 10, respectively, A socket connector 100 including a negative voltage sensing pin 132, a pair of positive voltage miswiring detection pins 141, and a pair of negative voltage miswiring detection pins 142; and
Plug housing 210, an insert portion 220 that protrudes from one side of the plug housing 210 and is inserted into the plug receiving hole 111, is accommodated in the plug housing 210 and the insert portion 220, and has a rear end The cable is pressed and fixed to the positive plug terminal 231 and the negative plug terminal 232, which are disposed adjacent to each other within the plug housing 210 and the insert portion 220, and adjacent to the positive plug terminal 231. A plug including a positive miswiring detection resistor 251 disposed and having a unique first resistance value and a negative miswiring sensing resistor 252 disposed adjacent to the negative plug terminal 232 and having a unique second resistance value. Including a connector 200,
Socket and plug type connectors for electrical wiring. According to paragraph 1,
Each of the positive socket terminal 121 and the negative socket terminal 122,
First terminal connection areas (1211, 1221) inserted into and received in the plug receiving hole (111); and
It includes first substrate connection areas (1212, 1222) bent in a direction perpendicular to the first terminal connection areas (1211, 1221) and exposed to the outside of the socket housing (110),
The first terminal connection areas (1211, 1221) are connected to the plug terminals (231, 232), and the first board connection areas (1212, 1222) are connected to the printed circuit board (10). ,
Socket and plug type connectors for electrical wiring. According to paragraph 1,
A guide protrusion 111c is provided on one side of the plug receiving hole 111 and extends in the depth direction of the plug receiving hole 111 to guide the insertion of the insert portion 220,
The insert portion 220 is characterized in that it is provided with a guide groove 221 into which the guide protrusion 111c is inserted.
Socket and plug type connectors for electrical wiring. According to paragraph 1,
Each of the positive voltage sensing pin 131 and the negative voltage sensing pin 132 is
A second board connection area (1311, 1321) exposed to the outside of one side of the socket housing 110, and a second board connection area (1311, 1321) extending from the second board connection area (1311, 1321) and exposed to the outside of the other side of the socket housing (110). 2 including connection areas (1312, 1322),
The second connection areas 1312 and 1322 are connected to the positive and negative electrodes of the battery, respectively, through the first plug connection pins 261 and 262 of the plug connector 200, and the second substrate connection areas 1311 and 1321 ) is characterized in that it is connected to the printed circuit board 10,
Socket and plug type connectors for electrical wiring. According to paragraph 1,
The pair of positive voltage miswiring detection pins 141 are
A third substrate connection area (1411a, 1411b) exposed to the outside of one side of the socket housing 110 and a third board connection area (1411a, 1411b) extending from the third substrate connection area (1411a, 1411b) and exposed to the outside of the other side of the socket housing 110. Includes 3 connection areas (1412a, 1412b),
The third connection areas 1412a and 1412b are connected to the anode miswiring detection resistor 251 through a pair of second plug connection pins 241 of the plug connector 200, and the third substrate connection area ( 1411a, 1411b) are connected to the printed circuit board 10,
The pair of negative voltage miswiring detection pins 142 are
A fourth substrate connection area (1421a, 1421b) exposed to the outside of one side of the socket housing 110 and a fourth board connection area (1421a, 1421b) extending from the fourth substrate connection area (1421a, 1421b) and exposed to the outside of the other side of the socket housing 110. Includes 4 connection areas (1422a, 1422b),
The fourth connection areas 1422a and 1422b are connected to the negative miswiring detection resistor 252 through a pair of third plug connection pins 242 of the plug connector 200, and the fourth substrate connection area ( 1421a, 1421b) are characterized in that they are connected to the printed circuit board 10,
Socket and plug type connectors for electrical wiring. According to clause 5,
The positive voltage sensing pin 131 and the pair of positive voltage miswiring detection pins 141 are disposed adjacent to the positive socket terminal 121.
The negative voltage sensing pin 132 and the pair of negative voltage miswiring detection pins 142 are disposed adjacent to the negative socket terminal 122.
Socket and plug type connectors for electrical wiring. A power source that supplies charging current through electrical wiring;
A socket and plug type electrical wiring connector consisting of a socket connector connected to the electrical wiring and a plug connector connected to a battery; and
It includes a control unit that controls charging and discharging of the battery,
The socket connector of the socket and plug type electrical wiring connector includes a miswiring detection pin,
The plug connector of the socket and plug type electrical wiring connector includes a miswiring detection resistor having a unique resistance value,
When the socket connector and the plug connector are electrically connected, the miswiring detection pin and the miswiring detection resistor are electrically connected, and when a preset voltage is applied to the miswiring detection pin of the socket connector, the control unit detects the error. A battery charging and discharging system that determines whether the socket connector and the plug connector are miswired based on the voltage output through a wiring detection resistor. In clause 7,
The socket connector is a battery charging and discharging system including a pair of positive voltage miswiring detection pins and a pair of negative voltage miswiring detection pins. According to clause 8,
The plug connector is a battery charging and discharging system including a positive voltage line miswiring detection resistor having a first specific resistance value and a negative voltage line miswiring detection resistor having a second specific resistance value. According to clause 9,
When the socket connector and the plug connector are electrically connected, the pair of positive voltage miswiring detection pins are electrically connected to the positive voltage line miswiring detection resistor, and the pair of negative voltage miswiring detection pins are electrically connected to the negative voltage line miswiring detection resistor. A battery charging and discharging system that is electrically connected to a voltage line miswiring detection resistor. In clause 7,
The socket connector includes a positive voltage sensing pin and a negative voltage sensing pin, and when the socket connector and the plug connector are electrically connected, the positive voltage sensing pin and the negative voltage sensing pin are each connected to the battery through the plug connector. A battery charging and discharging system that is electrically connected to the anode and cathode. According to clause 11,
When the socket connector and the plug connector are electrically connected, the control unit controls charging and discharging of the battery based on the positive and negative voltages of the battery detected through the positive and negative voltage sensing pins. Charging/discharging system. In clause 7,
The control unit determines that the socket connector and the plug connector are connected by miswiring when the voltage output through the miswiring detection resistor is outside the voltage value range corresponding to the miswiring detection resistance of the plug connector. .