KR20110138841A - Battery sensor of vehicle - Google Patents

Abstract

PURPOSE: A battery sensor for a vehicle is provided to improve the durability of a battery terminal by improving the coherence of a wiring terminal and a shunt resistor. CONSTITUTION: A sensor unit(140) measures the value of a current which generates in the both ends of a shunt resistor(130). A first insulator(150) insulates a space between the upper side of a base unit(110) and the lower part of the step of the shunt resistor. A second insulator(151) insulates the bottom surface of the base unit. A spacer(160) protects the second insulator. A wiring terminal(170) closely adheres to the upper side of the shunt resistor.

Description

Automotive Battery Sensors {BATTERY SENSOR OF VEHICLE}

The present invention relates to a vehicle battery sensor, and more particularly, to a vehicle battery sensor that improves the assembly and durability by improving the coupling structure of the shunt resistor and the wiring terminal.

In general, a vehicle includes an ignition device for starting an engine, as well as a variety of electrical devices required for its operation, most of which are powered by electricity.

Accordingly, the vehicle is provided with a charging device for supplying power to the necessary elements by generating electricity by using the power of the engine, and separately provided with a battery for supplying power to the ignition device and the start motor at the initial start of the engine do.

The vehicle battery is discharged by supplying power to electric devices used in a vehicle, and when discharged in a predetermined amount or more is charged through the generation of a generator.

That is, the vehicle battery supplies power so that each electric device can be operated as needed even when the engine is stopped, and is electrically connected to the ignition device and the start motor, and is generated from the generator during operation of the engine. It is recharged using electricity.

The generator is driven by a belt driven by a crank pulley connected to the crankshaft of the engine. The generator not only charges a vehicle battery but also supplies electric devices used in a vehicle while driving.

On the other hand, such a vehicle battery should be monitored at all times in order to recognize a failure due to energy supply and to prepare a countermeasure when using safety-related electric devices.

Therefore, a sensor is attached to the battery to measure the voltage and current to monitor the current battery condition and to adjust the charge and discharge amount.

The battery sensor is configured to operate the generator when the internal power of the vehicle battery is insufficient to perform a charging operation, and to prevent overcharging by stopping the operation of the generator when a certain amount of power is charged by the vehicle battery.

1 is a view showing a battery sensor for a vehicle according to the prior art.

As shown in FIG. 1, the vehicle battery sensor according to the related art has a base part 10 having a battery connection port 11 installed at one side thereof, and a step formed at one side thereof, and the other side being fused with the base part 10. A shunt resistor 30, a sensor unit 40 for measuring a current value generated at both ends of the shunt resistor 30 and outputting it as a voltage, and an upper surface of the base unit 10 and a stage of the shunt resistor 30. And an insulator 50 that insulates between the lower portion of the vehicle surface, and a wiring terminal 70 fused by spot welding to one end of the shunt resistor 30.

In addition, the battery connection port 11 is coupled to the through-hole 12 of the battery connection port 11 by tightening the bolt 20 and the nut 21 to be fixed to the battery terminal (not shown), An insulator 51 that insulates the base part 10 is installed under the base part 10, and the spacers 60 are installed under the base part 10 to protect the insulator 51.

Meanwhile, in the battery sensor according to the related art, as shown in FIG. 2, the wiring terminal 70 is fused by spot welding to one end of the shunt resistor 30.

This is to minimize the contact area between the shunt resistor 30 and the wiring terminal 70 so that the change in the resistance value of the shunt resistor 30 is minimized, but in practice, the shunt resistor 30 and the wiring terminal 70 Even if the contact area increases, the resistance value change of the shunt resistor is very small.

In addition, in the battery sensor according to the related art, the tip of the shunt resistor 30 and the tip of the wiring terminal 70 are welded in a small area through spot welding, thereby coupling the coupling force between the shunt resistor 30 and the wiring terminal 70. There is a problem of not being firmly maintained.

In addition, the weakening of the coupling force has a problem that reduces the durability of the battery sensor.

In order to solve this problem, an object of the present invention is to provide a vehicle battery sensor that improves the assembly and durability of the battery sensor by improving the coupling structure of the shunt resistor and the wiring terminal.

In order to achieve the above object, the present invention provides a base unit having a battery connection port at one side, and a step formed at one side thereof, and a bottom surface of the step shunted at one end of the base unit, and at both ends of the shunt resistor. A sensor unit for measuring a current value generated and outputting it as a voltage, a first insulator for insulating between an upper surface of the base portion and a lower stepped surface of the shunt resistor, a second insulator for insulating the bottom surface of the base portion, and A vehicle battery sensor comprising a spacer protecting a second insulator and a wiring terminal in close contact with an upper surface of the shunt resistor.

A through hole penetrating the base portion, the shunt resistor, the first insulator, the second insulator, and the wiring terminal; And one side is in close contact with the upper surface of the wiring terminal through the through hole, and the other side is in close contact with the bottom surface of the spacer, and the base part, the shunt resistor, the first insulator, the second insulator, the spacer, and the wiring terminal are crimped. Coupled to be fixed; characterized in that it comprises a.

In addition, the present invention is characterized in that the wiring terminal in close contact with the upper surface of the shunt resistor, and the coupling portion in close contact with the wiring terminal and the spacer is welded fusion.

In addition, the present invention is a base portion provided with a battery connection port on one side, a step is formed on one side and the bottom surface of the step is a shunt resistor fused to one end of the base portion, and the current value generated at both ends of the shunt resistance A sensor unit for measuring and outputting a voltage, a first insulator insulated between an upper surface of the base portion and a lower stepped surface of the shunt resistor, a second insulator for insulating the bottom surface of the base portion, and a lower surface of the second insulator A battery sensor for a vehicle including a wiring terminal in close contact with the

A through hole penetrating the base portion, the shunt resistor, the first insulator, the second insulator, and the wiring terminal; And an upper surface of the shunt resistor and a bottom surface of the wiring terminal portion electrically connected to each other through the through hole, and the base portion, the shunt resistor, the first insulator, the second insulator, and the wiring terminal are pressed and fixed. It characterized in that it comprises a.

In addition, the present invention is characterized in that the bonding portion in close contact with the upper surface of the shunt resistor and in close contact with the bottom surface of the wiring terminal is fused by welding.

In addition, the present invention is a base portion provided with a battery connection port on one side, a step is formed on one side and the bottom surface of the step is a shunt resistor fused to one end of the base portion, and the current value generated at both ends of the shunt resistance A sensor unit for measuring and outputting a voltage, a first insulator insulating between the upper surface of the base portion and a lower stepped surface of the shunt resistor, a second insulator for insulating the bottom surface of the base portion, and protecting the second insulator An on-vehicle battery sensor comprising a spacer and a wiring terminal inserted into and closely inserted between the shunt resistor and the first insulator,

A through hole penetrating the base portion, the shunt resistor, the first insulator, the second insulator, the spacer, and the wiring terminal; And one side is in close contact with the upper surface of the shunt resistor and the other side is in close contact with the bottom surface of the spacer, and the base part, the shunt resistor, the first insulator, the second insulator, the spacer, and the wiring terminal are crimped and fixed through the through hole. It characterized in that it comprises a; coupling portion to be.

In addition, the present invention is characterized in that the bonding portion in close contact with the upper surface of the shunt resistor and the bottom of the spacer is welded fusion.

In addition, the coupling portion according to the invention is characterized in that any one of a bolt or rivet and a pair of bolts and nuts fastened to the through hole of the shunt resistor and the wiring terminal.

In addition, the wiring terminal according to the present invention is characterized in that the anti-rotation jaw formed on one surface to prevent the wiring terminal from flowing after the fastening operation or assembly.

In addition, the present invention is characterized in that it further comprises an insulation tube to insulate between the inner circumference of the through hole and the outer circumference of the coupling portion.

The present invention has the advantage that the coupling of the shunt resistor and the wiring terminal can be easily improved the assembly process effectively.

In addition, the present invention has an advantage that the durability of the battery terminal can be significantly improved by improving the coupling force between the shunt resistor and the wiring terminal.

1 is a perspective view showing a vehicle battery sensor according to the prior art.
Figure 2 is a partially exploded perspective view showing a coupling structure of the copper plate and the wiring terminal of the vehicle battery sensor according to the prior art.
3 is a perspective view showing a first embodiment of a vehicle battery sensor according to the present invention;
4 is a perspective view showing a second embodiment of a vehicle battery sensor according to the present invention;
5 is a perspective view showing a third embodiment of a vehicle battery sensor according to the present invention;

Hereinafter, exemplary embodiments of a vehicle battery sensor according to the present invention will be described in detail with reference to the accompanying drawings.

(First embodiment)

3 is a perspective view showing a first embodiment of a vehicle battery sensor according to the present invention.

As shown in FIG. 3, the battery sensor 100 according to the first exemplary embodiment of the present invention is a rectangular plate member, which includes a base 110 having a battery connection port 111 provided on one side thereof, and a rectangular plate member. A step is formed at one side and a bottom surface of the step is shunt resistor 130 fused to one end of the base portion 110, and is provided at a center portion of the shunt resistor 130 to be generated at both ends of the shunt resistor 130. A first insulator 150 that insulates the sensor unit 140 measuring a current value to be output as a voltage, an upper surface of the base unit 110, and a bottom surface of the shunt resistor 130 in which the step is formed; A second insulator 151 for insulating the bottom surface of the base part 110, a spacer 160 protecting the second insulator 151, and a wiring terminal in close contact with an upper surface of the shunt resistor 130. 170, the base 110, the shunt resistor 130, the first insulator 150, and the first 2 a through hole penetrating through the insulator 151, the spacer 160, and the wiring terminal 170, and the base part 110, the shunt resistor 130, the first insulator 150, and penetrate the through hole. The coupling part 180 for crimping and fixing the second insulator 151, the spacer 160, and the wiring terminal 170, and the insulating tube 190 to insulate the inner circumference of the through hole.

The battery connection port 111 formed at one side of the base unit 110 is fastened to a battery terminal (not shown), and the battery is connected to the battery port through hole 112 by a bolt 120 and a nut 121. It is fixed to the terminal.

In addition, the base part 110 is formed with a through hole (not shown) through which the coupling part 180 and the insulating tube 190 pass.

The shunt resistor 130 is a plate member of a copper material having a predetermined thickness, and a through hole (not shown) through which the coupling part 180 and the insulating tube 190 penetrate is formed at one side.

In addition, the bottom of the step formed by bending at one side of the shunt resistor 130 is fused with the base portion 110 by spot welding or brazing.

The sensor unit 140 detects a current generated at both ends of the shunt resistor 130 and outputs the voltage.

The first insulator 150 insulates portions other than the step fusion portions between the base portion 110 and the shunt resistor 130 to maintain current flow from the base portion 110 to the shunt resistor 130. To help.

The wiring terminal 170 is in close contact with the upper surface of the shunt resistor 130 in a sufficient area, and the through hole 171 formed in the wiring terminal 170 is the base portion 110 and the shunt resistor 130. And a through hole (not shown) formed in each of the first insulators 150 and concentric shafts.

In addition, a screw groove 172 is formed at the inner circumference of the through hole 171 of the wiring terminal 170 to be coupled to the coupling part 180.

In addition, the wiring terminal 170 forms a rotation preventing jaw 173 so that the part in which the part interviewed with the shunt resistor 130 is engaged with the coupling part 180 or after the center of the through hole 171. To prevent it from rotating.

In addition, the wiring terminal 170 has a circumference in close contact with the shunt resistor 130 and a screw groove portion 172 fastened with the coupling part 180 to increase the firmness with the shunt resistor 130. Is welded by spot welding or brazing.

Meanwhile, a second insulator 151 is installed on the bottom of the base part 110, and a spacer 160 is installed on the bottom of the second insulator 151 to provide the base part 110 and the shunt resistor 130. In this case, the crimping fixing of the first insulator 150 and the wiring terminal 170 may be further improved.

In addition, the second insulator 151 and the spacer 160 have a through hole (not shown) through which the coupling part 180 passes.

The coupling part 180 is a screw groove part 172 formed in the through holes formed in the base part 110, the shunt resistor 130, and the first insulator 150 and the through hole 171 of the wiring terminal. The base unit 110, the shunt resistor 130, the first insulator 150, the second insulator 151, the spacer 160, and the wiring terminal 170 are fixed to each other.

The coupling part 180 is preferably a bolt, and may use a rivet.

Meanwhile, when only the through hole 171 is formed in the wiring terminal 170 without the screw groove 172 in the wiring terminal 170, the coupling part 180 is fastened with the nut 181 on the upper surface of the wiring terminal 170 to the base. The unit 110, the shunt resistor 130, the first insulator 150, the second insulator 151, the spacer 160, and the wiring terminal 170 may be fixed.

In addition, the nut 181 in close contact with the wiring terminal 170 and the coupling part 180 in close contact with the spacer 160 may be welded by spot welding or brazing so as to increase the tightness of the coupling.

The insulator tube 190 penetrates the base part 110, the shunt resistor 130, the first insulator 150, the second insulator 151, the spacer 160, and the wiring terminal 170. Is inserted into the to maintain the insulation between the base portion 110 and the shunt resistor 130 to maintain the current flow from the base portion 110 to the shunt resistor 130.

Accordingly, the shunt resistor 130 and the wiring terminal 170 may be fastened through the coupling part 180 and fused through welding to be more firmly coupled.

In addition, the wiring prevention terminal 173 formed in the wiring terminal 170 can prevent the wiring terminal 170 from moving, so that the coupling can be more firmly maintained.

(Second embodiment)

4 is a perspective view showing a second embodiment of a vehicle battery sensor according to the present invention.

Repeated descriptions of the same elements as in the first embodiment are omitted.

As shown in FIG. 4, the battery sensor 100a according to the second exemplary embodiment of the present invention is a rectangular plate member, which includes a base 110 having a battery connection port 111 provided on one side thereof, and a rectangular plate member. A step is formed at one side and a bottom surface of the step is shunt resistor 130 fused to one end of the base portion 110, and is provided at a center portion of the shunt resistor 130 to be generated at both ends of the shunt resistor 130. A first insulator 150 that insulates the sensor unit 140 measuring a current value to be output as a voltage, an upper surface of the base unit 110, and a bottom surface of the shunt resistor 130 in which the step is formed; The second insulator 151 to insulate the bottom surface of the base unit 110, the wiring terminal 170 in close contact with the bottom surface of the second insulator 151, the base unit 110, and the shunt resistor ( 130, penetrating the first insulator 150, the second insulator 152, and the wiring terminal 170, respectively. And a coupling part through which the base part 110, the shunt resistor 130, the first insulator 150, the second insulator 151, and the wiring terminal 170 are crimped and fixed through the through hole. 180 and an insulating tube 190 to insulate the inner circumference of the through hole.

The second embodiment is different from the first embodiment as a coupling position of the wiring terminal 170, and the upper surface of the shunt resistor 130 and the bottom surface of the wiring terminal 170 are coupled to the coupling unit 180. It is possible to exclude the configuration of the spacer 160 to be electrically connected through).

In addition, a screw groove 132 is formed at an inner circumference of the through hole 131 formed in the shunt resistor 130, so that the screw groove 132 may be directly coupled to the coupling part 180, so that the shunt resistor 130 and the wiring terminal ( 170 may be electrically shorted through the coupling unit 180.

In addition, although not shown, when the coupling part 180 is inserted into the shunt resistor 130, a screw groove part 172 formed in the inner circumference of the through hole 171 of the wiring terminal 170 is illustrated. The shunt resistor 130 and the wiring terminal 170 may be electrically shorted through the coupling unit 180.

In addition, when the shunt resistor 130 is in close contact with the coupling unit 180 through the nut 181, the wiring terminal 170 and the coupling unit 180 may be in close contact and electrically shorted. .

In addition, the through hole 131 of the shunt resistor is fused with the coupling part 180, and the nut 181 and the coupling part 180 are the shunt resistor 130 and the wiring terminal 170, respectively. It can be welded by spot welding or brazing to bond more firmly.

Therefore, the shunt resistor 130 and the wiring terminal 170 may be fastened through the coupling part 1801 and may be fused through welding to be more firmly coupled.

In addition, the wiring prevention terminal 173 formed in the wiring terminal 170 can prevent the wiring terminal 170 from moving, so that the coupling can be more firmly maintained.

(Third embodiment)

5 is a perspective view showing a third embodiment of a vehicle battery sensor according to the present invention.

Repeated descriptions of the same elements as in the first embodiment are omitted.

As shown in Fig. 4, the battery sensor 100b according to the third embodiment of the present invention is a rectangular plate member, which has a base portion 110 having a battery connection port 111 provided on one side thereof, and a rectangular plate member. A step is formed at one side and a bottom surface of the step is shunt resistor 130 fused to one end of the base portion 110, and is provided at a center portion of the shunt resistor 130 to be generated at both ends of the shunt resistor 130. A first insulator 150 that insulates the sensor unit 140 measuring a current value to be output as a voltage, an upper surface of the base unit 110, and a bottom surface of the shunt resistor 130 in which the step is formed; A second insulator 151 to insulate the bottom of the base unit 110, a spacer 160 to protect the second insulator 151, the shunt resistor 130 and the first insulator 150. Wiring terminal 170 and the base portion which is inserted between the insert is in close contact with A through hole penetrating through the 110, a shunt resistor 130, a first insulator 150, a second insulator 151, a spacer 160, and a wiring terminal 170, and the base penetrating the through hole. Coupling unit 180 for crimping and fixing the unit 110, the shunt resistor 130, the first insulator 150, the second insulator 151, the spacer 160, and the wiring terminal 170, and through Insulation tube 190 to allow the inner circumference of the ball is insulated.

The third embodiment differs from the first embodiment in that the wiring terminal 170 is inserted between the shunt resistor 130 and the first insulator 150, and the bottom surface of the shunt resistor 130 is inserted into the wiring terminal 170. And the nut 181 of the coupling part are welded to the shunt resistor 130 by spot welding or brazing while the upper surface of the wiring terminal 170 is in close contact with each other.

At this time, the base 110 and the wiring terminal 170 are electrically insulated by the first insulator 150 to maintain current flow from the base 110 to the shunt resistor 130. Be sure to

In addition, by installing the second insulator 151 and the spacer 160 in the lower portion of the base portion 110 to weld the coupling portion 180 and the spacer 160 by spot welding or brazing to more firmly coupled. It may be.

Accordingly, the shunt resistor 130 and the wiring terminal 170 may be fastened through the coupling part 180 and fused through welding to be more firmly coupled.

In addition, the anti-rotation jaw formed on the wiring terminal 170 may prevent the wiring terminal 170 from moving after the assembly process and the fastening by inserting the insert, thereby maintaining the connection more firmly.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it will be understood by those of ordinary skill in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined by the appended claims. It can be understood that

100, 100a, 100b: battery sensor 110: base portion
111: battery port 112: battery port through hole
120, 180: bolt 121, 181: nut
130: shunt resistance 131: through hole
132: screw groove 140: sensor
150: first insulator 151: second insulator
160: spacer 170: wiring terminal
171: through hole 172: screw groove
173: anti-rotation jaw 190: insulated pipe

Claims (9)

A base portion having a battery connection port at one side, a stepped portion formed at one side thereof, and a bottom surface of the stepped shunt resistor welded to one end of the base portion, and a current value generated at both ends of the shunt resistor measured and outputted as a voltage A first insulator that insulates the sensor portion from the upper surface of the base portion and a lower portion of the stepped surface of the shunt resistor, a second insulator for insulating the bottom surface of the base portion, a spacer protecting the second insulator, and A vehicle battery sensor comprising a wiring terminal in close contact with an upper surface of a shunt resistor,
A through hole penetrating the base portion, the shunt resistor, the first insulator, the second insulator, and the wiring terminal; And
One side is in close contact with the upper surface of the wiring terminal through the through hole and the other side is in close contact with the bottom surface of the spacer, and the base part, the shunt resistor, the first insulator, the second insulator, the spacer and the wiring terminal are crimped and fixed. Vehicle battery sensor comprising a coupling to be. The method of claim 1,
The wiring terminal in close contact with the upper surface of the shunt resistor, and the coupling portion in close contact with the wiring terminal and the spacer, the vehicle battery sensor, characterized in that fusion welded. A base portion having a battery connection port installed at one side, a stepped portion formed at one side thereof, and a bottom surface of the stepped shunt resistor fused to one end of the base portion, and a current value generated at both ends of the shunt resistor measured and outputted as a voltage A first insulator that insulates between the sensor unit, an upper surface of the base portion, and a lower portion of the stepped surface of the shunt resistor, a second insulator which insulates the bottom surface of the base portion, and a wiring in close contact with the bottom surface of the second insulator. A vehicle battery sensor comprising a terminal,
A through hole penetrating the base portion, the shunt resistor, the first insulator, the second insulator, and the wiring terminal; And
A coupling part which penetrates the through hole to electrically connect the upper surface of the shunt resistor and the bottom surface of the wiring terminal part, and allows the base part, the shunt resistor, the first insulator, the second insulator, and the wiring terminal to be crimped and fixed. Vehicle battery sensor comprising a. The method of claim 3, wherein
The coupling part in close contact with the upper surface of the shunt resistor and in close contact with the bottom surface of the wiring terminal is welded fusion welding sensor. A base portion having a battery connection port at one side, a stepped portion formed at one side thereof, and a bottom surface of the stepped shunt resistor welded to one end of the base portion, and a current value generated at both ends of the shunt resistor measured and outputted as a voltage A first insulator that insulates the sensor portion from the upper surface of the base portion and a lower portion of the stepped surface of the shunt resistor, a second insulator for insulating the bottom surface of the base portion, a spacer protecting the second insulator, and A battery sensor for a vehicle including a wiring terminal inserted into and closely inserted between a shunt resistor and the first insulator,
A through hole penetrating the base portion, the shunt resistor, the first insulator, the second insulator, the spacer, and the wiring terminal; And
One side is in close contact with the upper surface of the shunt resistor through the through hole and the other side is in close contact with the bottom surface of the spacer, and the base part, the shunt resistor, the first insulator, the second insulator, the spacer, and the wiring terminal are pressed and fixed. Vehicle battery sensor comprising a coupling unit. The method of claim 5, wherein
The coupling part in close contact with the upper surface of the shunt resistor and the bottom surface of the spacer is welded fusion welding sensor. The method according to any one of claims 1 to 6,
The coupling part is a vehicle battery sensor, characterized in that any one of a bolt or rivet coupled to the through hole of the shunt resistor and the wiring terminal, a pair of bolts and nuts. The method according to any one of claims 1 to 6,
The wiring terminal has a rotation prevention jaw formed on one surface to prevent the wiring terminal from flowing after the fastening operation or assembly. The method according to any one of claims 1 to 6,
Vehicle battery sensor further comprises an insulating tube to insulate between the inner circumference of the through hole and the outer circumference of the coupling portion.

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