JP3663251B2 - Capacitor leakage current measurement method - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a method for measuring a leakage current of a capacitor. More specifically, the present invention relates to a method for measuring a leakage current of a capacitor in which at least two kinds of voltages are applied and inspection is performed using currents after a certain period of time, thereby reducing a measurement error caused by a production line abnormality.
[0002]
[Prior art]
Conventionally, for example, a capacitor such as a tantalum capacitor has a current limiting resistor R connected in series, a constant voltage V is applied, and a current after a predetermined time is measured by an ammeter A as shown in FIG. As a result, the quality of the leakage current is inspected. In general, as shown in FIG. 3B, an equivalent circuit of a capacitor is connected in parallel with a resistor R _ISO that causes a leakage current and a resistor R ₀ and a capacitance C ₀ as a dielectric absorption current in parallel with the capacitance C of the capacitor. A series equivalent resistance ESR and an inductance L are connected in series to the above. The inspection standard for leakage current in the case of a tantalum capacitor is the current after a certain time when a voltage V ₁ lower than the rated voltage is applied and the time after a certain time when a voltage V ₂ that is about twice the rated voltage is applied. Is determined by whether or not both currents are within a certain value.
[0003]
As shown in the schematic diagram of FIG. 4, for example, such a leak current measuring method is carried in such a manner that a large number of capacitors 1 connected in parallel to a lead frame or the like are transported frame by frame and sent before each measuring instrument. Several capacitors 1 are measured, and the measured number is intermittently conveyed in the direction of arrow A.
[0004]
In FIG. 4, the first leak current measuring device 2 (LC1 measurement) connects the probe 21 to four capacitors 1 in the example shown in the figure, and applies a low voltage V ₁ to the four capacitors at a time. For example, it is allowed to stand for about 20 to 32 seconds, and then each current I ₁ is measured. In the meantime, the measurement by the first leak current measuring device 2 (LC1 measurement) is already finished, and the second leak current measuring device 3 is transferred to the capacitor 1 conveyed before the second leak current measuring device 3 (LC2 measurement). The probe 31 is connected. Then, a high voltage V ₂ is applied to the four capacitors 1 at a time, and left for, for example, about 20 to 32 seconds of the same time, and then the current I ₂ of each capacitor is measured. After both the measurements by the first and second leak current measuring devices 2 and 3 are completed, the connected capacitors 1 are conveyed by the measured number.
[0005]
FIG. 5A shows the relationship between the voltage applied by the first and second leakage current measurements and the current at that time. In FIG. 5A, the time t ₁ is the time measured by the first leak current measuring device 2, the voltage V ₁ is applied, and the charging current that has flowed first initially decreases exponentially. The current I ₁ at the elapse of t ₁ is measured as the first leakage current value. Time t ₀ is the time during the transportation from the end of the measurement by the first leak current measuring device 2 to the second leak current measuring device 3, during which the residual voltage of the _first leak current measuring voltage V ₁ is reached. V ₀ is applied to the capacitor. The next time t ₂ is a measurement time by the second leak current measuring device 3, and the voltage V ₂ is applied. Also at this time, a large amount of charging current flows at the beginning of voltage application and decreases exponentially, and the current value I ₂ at the elapse of time t ₂ is measured as the second leakage current value. When the elapsed after the voltage of the time t ₂ is 0, momentarily reverse current D flows.
[0006]
After the measurement of the second leakage current is completed, the capacitor 1 conveyed before the discharger 4 is discharged with a resistor connected between both electrodes of the capacitor 1. This series of operations is performed intermittently, for example, every four pieces. Further, the discharged capacitor 1 is further transported to the next process, and the defective product is cut and removed by the measurement result of the leakage current, and the non-defective product is sent to the next process as it is.
[0007]
[Problems to be solved by the invention]
In the method of measuring the leakage current at one of the stations while connecting the conventional capacitors and transporting each station in the capacitor manufacturing process, a manual stop or an abnormal alarm stop occurs at some point in the manufacturing line. There is a problem that the leakage current value becomes a small value at the time of abnormality in the measurement by the second leakage current measuring device 3 when the conveyance of the current is interrupted.
[0008]
The present inventor has intensively studied the cause of a decrease in the leakage current measured by the second leakage current measuring device when the frame transportation is interrupted, and found that the following causes are found. . That is, in the conventional leak current measurement, as described above, the first leak current measurement and the second leak current measurement are performed by different measuring devices and at different stations. Therefore, the capacitor 1 in the middle of conveyance exists between the first and second leak current measuring devices 2 and 3 and the residual voltage V ₀ is applied for the time t ₀ . If there is no trouble in the production line and it is always transported at a fixed number, the time between the first leak current measurement and the second leak current measurement is constant, and there is no problem if the measurement conditions are the same. When a failure such as a trouble of defective product occurs in the production line, the time t _f (see FIG. 5B) becomes abnormally long. When the time until the measurement of the second leakage current becomes longer, the dielectric absorption of the capacitor proceeds more due to the residual voltage V ₀ , and as shown in FIG. 5B, the measured value of the second leakage current becomes lower. (The current change when the broken line is normal). As a result, it has been found that the measured value is far from the measured value of the first leakage current, and the accuracy (reliability) of the measuring instrument is reduced.
[0009]
On the other hand, it may be possible to eliminate the residual voltage of the measurement voltage V ₁ by discharging after the measurement of the first leakage current, but it is impossible to completely discharge the discharge for several tens of seconds, and the voltage is applied once. Returning the capacitor to the state before voltage application requires a long discharge time and is not practical.
[0010]
The present invention has been made to solve such a problem, and even when the production line is stopped due to some abnormality, the method for measuring the leakage current of the capacitor with high reliability does not affect the measurement of the leakage current of the capacitor. The purpose is to provide.
[0011]
[Means for Solving the Problems]
The method for measuring the leakage current of a capacitor according to the present invention is a method for measuring the leakage current of a capacitor in which two kinds of voltages are applied to the capacitor and each current value after a predetermined time is inspected to be within a predetermined range. A plurality of capacitors are connected in parallel to a long frame, and the frame is transported so as to pass through each capacitor manufacturing process station. The first leakage current is measured by applying the first voltage, and then the second leakage current is measured by continuously applying the second voltage, and then the frame is moved, The residual voltage is discharged for some capacitors for which the leakage current has been measured at the second station, and the first and the other capacitors are discharged for the first and second capacitors. Continuously measuring the second leakage current is characterized in that performed by the first station.
[0012]
According to another aspect of the method for measuring a leakage current of a capacitor according to the present invention, two types of voltages are applied to the capacitor and each of the current values after a predetermined time is inspected to determine whether or not they are within a predetermined range. a measurement method, a plurality of capacitor coupled in parallel to the frame of a long, conveying the frame to pass through the stations of the manufacturing process of the capacitor, the plurality in the first station For a part of the capacitor, the first leakage current is measured by applying the first voltage, the second leakage current is continuously measured by applying the second voltage continuously, and the residual voltage continues. Discharge the voltage, then move the frame, and perform another process for some of the capacitors measured for the leakage current at the second station. For some of the capacitors are continuously measured and discharging operations of the first and second leakage current and performing at the first station.
[0013]
DETAILED DESCRIPTION OF THE INVENTION
Next, a method for measuring the leakage current of the capacitor of the present invention will be described with reference to the drawings.
[0014]
FIG. 1A is a schematic diagram for explaining a method for measuring a leakage current according to the present invention, and FIGS. 1B and 1C are flowcharts thereof. The capacitor 1 is connected in parallel to a long copper frame or the like as in the prior art, and the number of probe terminals of the leak current measuring device 5 while being sequentially conveyed (three in FIG. 1, different from FIG. 4, but limited to the number). The leakage current of that number of capacitors is measured at once. In the present invention, the leak current measuring device 5 is switched to two kinds of measurement voltages by the controller 6. First, one voltage, for example, a low voltage V ₁ is applied and a current after a predetermined time has elapsed. After measuring the value, the voltage of the leak current measuring device 5 is immediately switched by the controller 6 to the high voltage V ₂ , and the current value after the elapse of a predetermined time is measured.
[0015]
That is, according to the present invention, since the measurement of the two kinds of voltages is always performed continuously when the measurement of the leakage current is started, the first leakage current is measured and then left for a long time, and then the second leakage current is measured. This does not happen. If a failure that interrupts the line occurs somewhere in the production line, the measurement is performed until the measurement of the leakage current is completed, and then the interruption occurs. This is because the transport of the connected capacitors is originally stopped during the leakage current measurement time, and is intermittently transported every time work of each process such as measurement of the leakage current is completed.
[0016]
After the measurement of the two kinds of leakage currents is completed, the connected capacitors 1 are transported to the next process by the number of capacitors, and the capacitors 1 sent to the discharger 4 are connected to the discharger 4 and discharged. The Thereafter, the defective product is sent to the defective ejector 7 and only the defective product is cut off from the connected portion according to the instruction from the controller 6 based on the measurement result of the current measuring device 5 in the previous process (NG). While connected, it is further sent to the next process (GO). FIG. 1B is a flowchart showing this series of steps.
[0017]
In the above-described method, after measuring the leakage current, a series of capacitors are conveyed by the number of measurement, and discharged by the discharger 4 provided in a different station. By doing so, the measurement of the leakage current and the discharge can be performed in parallel at the same time, which is convenient for improving the rotation speed of the equipment. However, the voltage of the leak current measuring device 5 can be further switched to 0V, and the voltage applied to the capacitor 1 is switched to 0V after the two types of current measurement are finished, and then discharged at the same station. Good. FIG. 1C is a flowchart showing the process at this time. In this way, it is not necessary to provide a separate discharger. As will be described later, the rotation of the production line is accelerated by increasing the number of measurements at one time by increasing the number of probe terminals of the current measuring device or by providing a plurality of leak current measuring devices.
[0018]
FIG. 2 shows the relationship between the applied voltage and current when the leakage current is measured by continuously applying two kinds of voltages by the method of the present invention. In FIG. 2, when a voltage of V ₁ is first applied to the capacitor, a charging current flows and the current value I decreases exponentially. For example between the voltage V ₁ of the 20 seconds to time t ₁ is applied to measure the current value I ₁ of the elapse of time t _1. Thereafter, the voltage applied to the capacitor is immediately switched to V ₂ and left for a time t ₂ of, for example, about 32 seconds. When this voltage increases, the charging current suddenly increases again, and then the current decreases exponentially. The current I ₂ at the time when the time t ₂ has elapsed is measured, and whether or not both the currents I ₁ and I ₂ are within the specified values is determined by the controller 6 (see FIG. 1). In FIG. 2, D indicates a current flowing in the reverse direction at the moment when the voltage is set to zero.
[0019]
According to the present invention, since the measurement of two kinds of leakage currents is continuously performed with one measuring instrument, it takes a lot of time for the current measurement process, and when it cannot be balanced with the time required for other discharges, Equipment utilization rate decreases. However, in such a case, the number of probe terminals of the leak current measuring device may be increased, or two or more leak current measuring devices may be arranged to carry the capacitors for each number to be measured at a time. Rather, when the first and second current measurement times are different, throughput is improved by performing continuous measurement with two units.
[0020]
【The invention's effect】
According to the present invention, since two types of current measurement are continuously performed and there is no intermittent time between them, even if the capacitor transport line is stopped due to a failure of one of the processes, the two types of measurement are not performed. The time will not vary. As a result, even if the line breaks down and the conveyance of the capacitor is interrupted, there is no cause for variation in the measured value of the leakage current, and there is no need for re-inspection. Highly reliable inspection can be performed.
[Brief description of the drawings]
FIG. 1 is a schematic diagram and a flowchart for explaining a method for measuring a leakage current according to the present invention.
FIG. 2 is a relationship diagram between applied voltage and current when measuring leakage current by the method of the present invention.
FIG. 3 is an equivalent circuit diagram for measuring the leakage current of the capacitor.
FIG. 4 is a diagram illustrating a conventional method for measuring the leakage current of a capacitor.
FIG. 5 is a relationship diagram between applied voltage and current when measuring leakage current by a conventional method.
[Explanation of symbols]
1 Capacitor 4 Discharger 5 Leakage current measuring device

Claims (2)

Current value after each predetermined time by applying the two voltages to the capacitor is a method of measuring the leakage current of the capacitor to check whether or not within the predetermined range, a plurality of capacitors elongated frame Connected in parallel, the frame is transported so as to pass through the stations of the capacitor manufacturing processes, and a first voltage is applied to a part of the plurality of capacitors at the first station. 1 leakage current was measured, and then the second leakage current was measured by continuously applying the second voltage, and then the frame was moved to measure the leakage current at the second station. together to discharge the residual voltage of some of the capacitor, the first stearyl continuously measure the first and second leakage current for the other part of the capacitor Method of measuring the leakage current of the capacitor, which comprises carrying out in Deployment. Current value after each predetermined time by applying the two voltages to the capacitor is a method of measuring the leakage current of the capacitor to check whether or not within the predetermined range, a plurality of capacitors long coupled in parallel to the frame, conveying the frame to pass through the stations of the manufacturing process of the capacitor, the portion of the plurality of capacitors in the first station, by applying a first voltage The first leakage current is measured, the second leakage current is continuously measured by continuously applying the second voltage, the residual voltage is further discharged, and then the frame is moved, A separate process is performed for some of the capacitors for which the leakage current is measured at the station, and the first and second leakage currents of the other capacitors are measured. Method of measuring the leakage current of the capacitor, wherein the constant and discharging work continuously carried out in the first station.

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