KR100190657B1 - Battery testing system - Google Patents

Abstract

The present invention relates to a battery inspection system for detecting productivity of a gasket insertion failure and inspecting whether a battery is insulated between a cathode and a can, and only a battery of good products is applied to a post process so as to improve productivity and work efficiency. An index table for forming a plurality of battery mounting grooves and rotating at a constant angular velocity to move the batteries to the respective inspection apparatuses; A gasket inspecting unit for inspecting whether or not a gasket is present in the battery moved by rotation of the index table; and a gasket inspecting unit for inspecting the battery, A first poor discharge portion for discharging the gas An insulation resistance measuring unit for measuring an insulation resistance between the cathode terminal of the battery and the can which is transferred by the rotation of the index table after it is judged by the inspection unit that the measured value is good, A second defective discharge unit for discharging the discharged product to the outside, and a good discharge unit which is determined by the insulation resistance measuring unit as being good and supplies the battery transferred by the rotation of the index table to a subsequent process.

Description

Battery Inspection System

More particularly, the present invention relates to a battery inspecting method, and more particularly, to a battery inspecting method for inspecting a battery having a poor gasket insertion state and measuring an insulation resistance between a battery terminal portion and an outer can to detect an insulated state, To a post-process.

Generally, inspecting insufficiency of inserting gasket of a battery is to inspect gasket inserting part by inspecting whether or not a gasket is inserted into a battery by using a photosensor, and inspecting insufficient insulation between battery terminal part and outer can Cathode) and the outer can (can), respectively, and the measurement values appearing on the measurement unit 3 are checked to check the battery insulation failure. That is, it is checked whether or not the value displayed on the meter is equal to or greater than a reference value (i.e., DC 250V, 4000 M?), And if it is not less than the reference value,

However, the conventional battery inspection apparatus is required to inspect only one of the gasket inspection and the insulation resistance measurement.

Conventionally, there has been a problem that the time required for the inspection is increased by checking the measurement value displayed on the meter after the operator touches the probe to all the batteries one by one in measuring the insulation resistance. In addition, The worker's fatigue is increased and the efficiency is lowered. In addition, there is a problem that perfect inspection is not performed.

In addition, there is a problem in that a large number of workers are required by performing the insulation resistance inspection by hand or separately inspecting the gasket and the insulation resistance, thereby increasing the production cost of the battery.

SUMMARY OF THE INVENTION The present invention has been made in order to solve the conventional problems as described above, and it is an object of the present invention to provide a method of detecting a battery having a poor gasket insertion state and measuring insulation resistance between a battery terminal portion and an outer can, The present invention is also directed to a battery inspection system having an effect of improving workability and productivity.

1 is a plan view showing an external configuration of a battery inspection system according to the present invention.

2 is a block diagram showing an internal configuration of a battery inspection system according to the present invention.

3 is a flow chart showing a battery testing method according to the present invention.

FIG. 4 is a side view of a battery inspecting apparatus according to the present invention.

Description of the Related Art [0002]

1 to 8: Battery mounting groove 11: Battery supply part

12: gasket inspection part 13: first bad discharge part

14: insulation resistance measuring section 15: second defective discharge section

16: Good product discharge part 17: Index table

As a technical means for accomplishing the above object, the present invention provides a battery inspection system provided between a gasket inserting process and an electrolyte injection process,

A battery supply portion for inserting the battery discharged from the gasket inserting process into the battery mounting groove of the index table and a battery accommodating portion for accommodating the battery moved by rotation of the index table; A gasket inspecting unit for inspecting the presence or absence of a gasket, a first failure discharge unit for discharging the battery determined to be defective by the gasket inspecting unit to the outside, An insulation resistance measuring unit for measuring an insulation resistance between the cathode terminal of the battery and the can, and a second defective discharge unit for discharging the battery whose measured value measured by the insulation resistance measuring unit is equal to or less than a reference value, It is determined that the insulation state is good by the insulation resistance measuring unit, It depends as having a non-defective discharge unit for supplying the process after the battery feed by the rotation of the table.

FIG. 1 is a plan view showing an external configuration of a battery inspection system according to the present invention. FIG. 1 is a plan view showing a battery supply unit 11 (see FIG. 1) for inserting a tested battery discharged from a gasket inserting process And a photosensor 12a installed to sense the gasket of the battery at the inspection position 2 above the index table 17 to inspect the presence or absence of the gasket of the battery transferred to the inspection position, A first defective discharge portion 13 for opening and closing a shutter provided under the battery mounting groove formed in the index table 17 to discharge the battery determined to be defective by the gasket inspection portion 12 to the outside, An insulation resistance measuring unit 14 for measuring the insulation resistance by bringing the probe into contact with the terminals of the battery and the can when the battery is delivered to the inspection position 6; A second defective discharge portion 15 for opening and closing the shutter to discharge the battery determined to be defective by the insulation resistance measuring portion 14 and a second defective discharge portion 15 for judging that the gasket inspecting portion 12 and the insulation resistance measuring portion 14 are good A good article discharging portion 16 for transferring the transferred battery to an electrolyte injection process (not shown) as a post-process, and a circular index table 17 (see FIG. 1) formed with a plurality of battery mounting grooves 1 to 8, A gasket inspecting unit 12, a first faulty discharging unit 13, an insulation resistance measuring unit 14, a second faulty discharging unit 15 and a good discharging unit 16, The gasket inspecting section 12, the gasket inspecting section 12, the gasket inspecting section 12, the gasket inspecting section 12, the gasket inspecting section 12, The first defective discharge portion 13, the insulation resistance measurement portion 14, the second defective discharge portion 15, and the good discharge portion 16 are arranged in this order.

FIG. 2 is a schematic diagram showing an internal configuration of a battery inspection system according to the present invention. The operation panel unit 21 is operated by an operator to output a command signal for an inspection operation. A programmable logic controller unit (hereinafter, referred to as a PLC unit) 22 that is programmed to detect a sensing signal input from the sensing unit 24 according to an applied command signal and output an operation control signal of each device, A link module 23 for connecting the measuring unit 26 and the measuring unit 26 so as to exchange signals with each other, and a sensor for detecting the position of the battery cathode, And a cylinder which is operated under the control of the PLC (22) to bring the anode and the cathode probes into contact with the cathode of the battery and the can. In order to inspect the defective gasket and insulated state, A measuring unit 26 for measuring the insulation resistance between the probe connected to the inspected battery under the control of the PLC 22 and an actuator unit 25 composed of a plurality of cylinders for controlling the PLC 22, And an index table 28 which is rotated by the driving of the motor unit 27 and has a plurality of battery mounting grooves on the periphery thereof.

FIG. 3 is a flow chart showing a battery inspection method by the battery inspection system shown in FIG. 1 and FIG. 2;

4 is a side view showing in detail the insulation resistance measuring unit 14 shown in FIG. 1, and is a sectional view of the cathode transferred to the position (5) in which the insulation resistance measuring apparatus 14 shown in FIG. And a finger cylinder 41 which is operated by a control signal from an external controller (PLC section 22 in FIG. 2), which is composed of a terminal 42 and a can 42 surrounding the terminal 44 and a gasket 43, A finger 46 connected to the measuring unit 26 through a lead wire 53 and connected to the cathode terminal 44 by the finger cylinder 45 in the left and right direction, A negative electrode probe 47 connected to the measuring unit 26 through the lead wire 54 and a cylinder 48 for moving the negative electrode probe 47 to contact the can 42 of the battery 41, A magnet 49 for contacting the battery 41 at the lower portion of the test battery 41 to fix the battery 41 and an external controller A motor 50 which is driven by the control of the motor 46 to rotate the magnet 49 at a predetermined angle and a cathode terminal 44 which is parallel to the finger 46 and installed at the height of the cathode 44 of the battery, And a sensor 51 for detecting whether the finger 46 and the finger 46 are arranged in parallel.

Next, the operation according to the present invention will be described.

The battery inspection operation according to the present invention will be described with reference to FIGS. 1 and 3. The battery is fed to the index table 17 by the battery supply unit 11. [ Here, the battery supply unit 11 senses the presence or absence of the battery supplied by the conveyor (not shown) and the state inserted into the index table 17 by a sensor installed at an appropriate position, . That is, when the empty battery mounting groove 1 is moved to the battery supply part 11 by the rotation of the index table 17, the battery transferred from the previous process by the transfer conveyor is inserted into the battery mounting groove 1 (301) .

When the battery is inserted into the mounting groove at the position (1) as in the step 301, the battery is moved to the position (2) where the gasket inspection part 12 is provided by the rotation of the index table 17. Here, the gasket inspecting unit 12 checks whether the gasket is inserted (302), as follows.

The battery moved to the position (2) is adjusted to the correct position by the gasket inspecting unit 12. Since the photosensor 12a provided in the gasket inspecting unit 12 is installed to sense the gasket inserting part, The output value of the photosensor 12a in the case of being inserted and the case of not being inserted are different. Therefore, when the output signal of the photosensor 12a is checked, the case where the gasket is inserted is judged as bad when the gasket is not inserted into the good product, and the inspection result is outputted.

Thus, the battery whose gasket has been inspected at the position (2) is moved to the position (3) where the first defective discharge portion 13 is provided by the rotation of the index table 17 again. If the battery is determined to be defective by the gasket inspection unit 12, the first defective discharge unit 13 operates the cylinder connected to the shutter (not shown) formed at the lower portion of the position (3) And the battery transferred to the position (3) is dropped to a loading box (not shown) provided below through an open shutter. However, when the battery is determined to be good, the first defective discharge section 13 operates to close the shutter, and the battery transferred to the position (3) is again subjected to insulation resistance measurement And moved to the position (5) where the unit 14 is addressed (303).

The battery which has been moved to the position (5) is subjected to the insulation state inspection by the insulation resistance measurement unit 14. First, the insulation resistance measurement unit 14 confirms whether there is a battery at the position (5) . This is to confirm the presence of the battery because there is a case where the battery is discharged by the first failure discharge part 13 and the battery is not transferred to the (5) position.

Then, when there is a transferred battery, the insulation resistance measuring unit 14 applies a probe (not shown) to the terminal (i.e., the cathode terminal) of the battery and the can ) To check whether the terminal and the can are in an insulated state. That is, the measured value through the probe contacted to the battery is compared with the set reference value to determine whether it is defective (305).

The inspection result of the insulation resistance measuring unit 14 is transmitted to the second defective discharge unit 15 and the position of the second defective discharge unit 15 at the position (6) where the second defective discharge unit 15 is addressed by the rotation of the index table 17 .

Similarly to the first defective discharge unit 13, the second defective discharge unit 15 operates in accordance with the result of inspection of the battery by the insulation resistance measurement unit 14, that is, The first defective discharge unit 13 opens the shutter formed at the lower end of the position (6) to discharge the battery transferred to the position (6) to the external loading box, If it is determined that the insulated state is good, the first defective discharge unit 13 closes the shutter and passes the battery transferred to the sixth position (step 306).

The battery which has been judged to be good and has been transferred to the position 6 is again moved to the position 7 where the good product discharge portion 16 is provided by the rotation of the index table 7, (307) according to the guide provided so as to discharge the battery of the good product of the good product discharge portion 16 to the post-process.

Referring to FIG. 2, the battery inspection operation will be described with reference to the internal configuration of the battery inspection system.

The operation panel unit 21 includes a plurality of buttons or switches, each of which is operated by a worker, so that the operator can control the battery inspection operation.

For example, the operation panel unit 21 is provided with a power switch for supplying power to the battery inspecting system, and the battery inspecting system performs a series of inspections from the gasket inspections to the insulation resistance inspections A manual mode switch for allowing the operator to manually inspect the gasket inspection, the insulation resistance inspection, the defective discharge, etc. of the battery inspection system can be provided.

An emergency stop button may also be provided to stop the running battery inspection system when a sudden emergency condition occurs or when the operation of the battery inspection system is abnormal.

The gasket inspecting unit 12, the first and second defective discharging units 13 and 15, and the insulation resistance measuring unit 14 may be provided with control buttons for controlling the operation of the inspecting unit.

When a plurality of operation buttons or switches as described above are operated by the operator, the signals of the switches or buttons are inputted to the PLC 22.

The PLC 22 is programmed to control the operation of each mechanism in accordance with input signals from the operation panel 21, the sensing unit 24, and the measurement unit 26. [

The sensing unit 24 is provided with a plurality of sensors for detecting the supply and discharge of the battery and the transfer of the battery. For example, the sensor 24 is provided in the battery supply unit 11 and detects whether or not the battery is supplied. A sensor provided in the insulation resistance measuring unit 14 for detecting whether the cathode terminal of the battery is aligned in parallel with the probe and a sensor for detecting whether or not the battery is transferred to the inspection position of the insulation resistance measuring unit 14 There may be a sensor.

The actuator unit 25 includes a plurality of cylinders operated under the control of the PLC 25. The actuator unit 25 includes a cylinder for moving up and down a stopper for fixing a battery included in the gasket inspecting unit 12, And cylinders for opening and closing the shutters provided in the first and second defective discharge units 13 and 15, respectively.

The motor section 27 rotates the index table 28 and the index table 28 is rotated by driving the motor provided in the motor section 27. That is, the rotation speed of the index table 28 can be adjusted by controlling the drive of the motor unit 27. [

The link module 23 enables exchange of measured values between the measuring section 26 and the PLC section 22 so that the measuring section 26 can measure the insulation resistance between the terminals of the battery and the can And a measuring module for measuring the insulation resistance and exchanges measured values and control signals with the PLC 22 via the link module 23. [

The operation of the insulation resistance measuring unit 14 will now be described in more detail with reference to FIG.

When the battery 41 is transferred to the position (5) in FIG. 1, first, the magnet 49 is brought into contact with the bottom of the battery 41. The motor 50 connected to the magnet 40 is driven according to an output signal of the sensor 51. The sensor 51 detects whether the cathode terminal 44 of the battery is positioned horizontally with the finger 46 Which is parallel to the fingers 46 and is disposed at an arbitrary position at the same height as the cathode terminal 44. Therefore, when the cathode terminal 44 is placed at a position in parallel with the finger 46, the light incident on the light receiving element of the sensor 51 is blocked, whereby a detection signal (e.g., a low level signal) And the sensor 51 outputs a normal signal (for example, a high level signal) when the cathode terminal 44 is placed at a different position not parallel to the finger 46.

The motor 50 is driven until the detection signal (that is, a low level signal) is output from the sensor 51 to rotate the magnet 49 at a constant speed, The battery 41 rotates together and the cathode terminal 44 is moved.

The output signal of the sensor 51 is checked and the driving control of the motor 50 is performed by the PLC 22 shown in FIG. That is, the PLC unit 22 checks the signal of the sensor 51 while controlling the motor 50 to rotate at a certain angle, and outputs a detection signal (for example, a low level signal) from the sensor 51 The motor 50 is stopped.

When the cathode terminal 44 of the battery is raised to the normal position as described above, the PLC 22 causes the cylinder 45 to move the fingers 46 to contract in the center direction, and the cylinder 48 moves the cathode 46 ) To the battery 44 side so as to be in contact with the can 42 of the battery. The portion of the finger 46 that contacts the cathode 44 is a straight line, which is intended to prevent the cathode terminal 44 from being stuck in contact with the finger 46.

Thus, as the fingers 46 are gathered in the center direction, the anode probes of the fingers 46 are brought into contact with the cathode terminals 44, and the cathode probes 47 are brought into contact with the cans. Thus, the lead wires 53 and 54 are connected to the measuring section 26 while the anode and the cathode probes 46 and 47 are contacted to the cathode terminal 44 and the can 42, and the insulation resistance between the cathode and the can is measured.

Thus, the battery inspection system according to the present invention has an effect of detecting defective gasket insertion and defective insulation and discharging a defective battery, so that only a good battery can be applied to a post-process. Further, It is possible to efficiently manage the production by discharging the defective battery separately. In addition, it is possible to detect an accurate insulation resistance by adjusting the cathode of the battery and the fingers of the anode probe to be parallel to each other during inspecting the insulated state, and since the contact portion of the finger is formed as a straight line instead of a curved line, There is an effect.

Claims (3)

A battery inspection system provided between a gasket inserting process and an electrolyte injection process, An index table formed with a plurality of battery mounting grooves and rotated at a constant angular velocity, A battery supply portion for inserting the battery discharged from the gasket inserting process into the battery mounting groove of the index table, A gasket inspection unit for inspecting whether or not a gasket is present in the battery moved by the rotation of the index table; A first defective discharge unit for discharging the battery determined to be defective by the gasket inspecting unit to the outside, An insulation resistance measuring unit for measuring an insulation resistance between the cathode terminal of the battery and the can carried by the rotation of the index table after the gasket check unit is judged to be good, A second defective discharge unit for discharging a battery whose measured value is equal to or lower than a reference value by the insulation resistance measuring unit to the outside, And a good product discharging unit which is determined by the insulation resistance measuring unit as being good and supplies the battery transferred by the rotation of the index table to a post-process. The method according to claim 1, The battery inspection system A control panel unit having a plurality of function keys for controlling operations of the battery inspection system; A control unit for controlling the operation of each cylinder provided in the actuator unit in accordance with a signal from the sensing unit, A programmable logic controller (PLC) unit for controlling the driving of the sub- A link module for transferring signals between the programmable logic controller and the measurement unit, A measuring unit for measuring an insulation state between the cathode terminal of the battery and the can, which is in contact with the positive electrode probe of the insulation resistance measuring unit under the control of the programmable logic controller through the link module, A motor unit driven by the programmable logic controller to rotate the index table at a constant speed, A cylinder for driving a stopper for fixing the battery in the gasket inspecting unit, and a cylinder for driving a finger serving as a positive electrode probe of the insulation resistance measuring unit, wherein the programmable logic An actuator unit including a plurality of cylinders operated by a control signal of the controller, And a sensor unit having a plurality of sensors including a sensor for detecting whether a battery is supplied, a sensor for detecting whether a gasket is inserted, and a sensor for detecting a position of a cathode, and outputting a sensing signal to the programmable logic controller Battery inspection system. 3. The method according to claim 1 or 2, The insulation resistance measuring unit A finger cylinder for driving the finger by a control signal of the PLC unit, A finger which is driven by the finger cylinder and is brought into contact with the cathode of the battery as a bipolar probe connected to an input terminal through a lead wire, A negative electrode probe connected to an input terminal of the measuring unit via a lead wire, A cylinder for driving the negative electrode probe to contact the can of the battery under the control of the PLC unit, A magnet attached to a lower portion of the tested battery to fix the battery, A motor which is connected to the magnet and driven by control of the PLC to rotate the magnet by a predetermined angle; And a sensor for detecting whether or not the cathode and the finger of the battery are arranged in parallel and outputting a detection signal to the PLC, The PLC unit Wherein the controller is operated to drive the motor until a sensing signal is input from the sensor.