KR101593527B1 - Apparatus for seperating multi layer ceramic capacitor - Google Patents

Abstract

The present invention relates to an MLCC sorter capable of sorting MLCCs by using a self-heating temperature characteristic generated by applying an alternating current to an MLCC using a zero-crossing control and causing a current to flow in the dielectric of the MLCC. An AC source supply unit for allowing the MLCC to generate heat by allowing a current to flow through the dielectric of the MLCC; A thermal camera disposed to be spaced apart from the AC source and measuring the temperature of the MLCC; And a controller connected to the AC source supplier and the thermal camera to apply AC to the MLCC at the zero crossing point and to compare the temperature measured by the thermal camera with a preset reference temperature to determine good products of the MLCC .

Description

[0001] MLCC selector [0002] Apparatus for separating multi-

The present invention relates to an MLCC sorter, and more particularly, to an MLCC sorter capable of sorting MLCCs by using a self-heating temperature characteristic generated by causing an electric current to flow through a dielectric of an MLCC by applying alternating current to the MLCC using zero crossing control.

Multilayer Ceramic Capacitor (MLCC) is a mass-produced product, and an MLCC sorter is used to improve the productivity of the test process when conducting electrical tests.

Korean Patent Registration No. 1271326 (Patent Document 1) relates to an MLCC sorter for sorting balls and MLCCs. The MLCC sorter includes a feed cylinder, a diffuser plate, a diffuser plate vibrator, a beveling plate, a sorting plate, A lower ramp and a ball collecting barrel.

The feed cylinder of the MLCC sorting machine disclosed in Patent Document 1 is disposed on the upper portion of the base, and the diffusion plate is horizontally installed below the feed cylinder to feed the MLCC and the ball gradually diffused through the opening of the feed cylinder while diffusing. The diffusion plate vibrator vibrates the diffusion plate, and the inclined fly plate is slanted at one side of the diffusion plate, and is transported by the diffusion plate to transport the MLCC and the ball downward to the outside. The separating separator is installed at an inclined lower portion of the inclined transfer plate to separate the MLCC and the ball falling from the inclined transfer plate so that the MLCC is transferred to the upper side and the ball is transferred to the lower side. The separating plate vibrator vibrates the separating plate, and the upper inclining plate is inclined at one side of the separating plate to transfer the MLCC discharged from the separating plate to the outside. The MLCC collector collects the MLCC discharged from the upper ramp, and the lower ramp is sloped on the other side of the separator to transfer the balls discharged from the separator to the outside. The ball collector collects the balls discharged from the lower ramp .

The MLCC sorter disclosed in Patent Literature 1 is a sorter for removing balls used in the MLCC manufacturing process. The MLCC, which has been manufactured, is inspected for electrical characteristics such as capacity, loss and insulation resistance by using an MLCCC sorter to produce good and defective products Select. Such a conventional MLCC sorter charges an MLCC with only a DC voltage and measures and selects electrical characteristics such as capacitance, loss, and insulation resistance.

The MLCC selected by the MLCC sorter as good and defective is applied to the DC circuit or the AC circuit. Especially, MLCC applied to AC circuit is used for DC-link (direct current-link), so dielectric thickness is reduced to 2 μm or less for high capacity and large size.

When MLCC is manufactured by stacking high dielectric constant thin film dielectrics for AC-link or DC-link use, MLCC can be cracked during normal impact or sintering, or after MLCC is mounted on printed circuit board . Cracks generated in the MLCC lower the insulation resistance of the MLCC, and if the electric energy applied to the MLCC from the outside is large, the MLCC is destroyed and the product is damaged. That is, when electric energy is applied to the MLCC for a long time in a state where a minute crack is generated in the MLCC, the power saving resistance of the dielectric of the MLCC is lowered due to the crack of the minute size. As a result, Can be gradually carbonized and broken.

If a microcrack is generated in the MLCC by measuring only the DC voltage, the microcrack changes the insulation resistance of the MLCC, causing current to flow to the MLCC, which causes the MLCC to slowly carbonize and break Electrical characteristics can not be selected. That is, the conventional MLCC sorter has a problem that it is difficult to select whether the electrical characteristics of the MLCC are defective depending on the micro cracks generated in the MLCC by measuring only the DC voltage.

Patent Document 1: Korean Patent No. 1271326 (Registered on May 31, 2013)

SUMMARY OF THE INVENTION An object of the present invention is to solve the above-mentioned problems, and an object of the present invention is to provide an MLCC selector which can select an MLCC by using a self-heating temperature characteristic generated by applying an AC to an MLCC using a zero crossing control, .

It is another object of the present invention to provide an MLCC sorter capable of detecting minute cracks generated in an MLCC by allowing MLCCs to be selected using a self-heating temperature characteristic generated by causing a current to flow in a dielectric of the MLCC.

It is still another object of the present invention to provide an MLCC sorter capable of detecting a minute crack generated in an MLCC, thereby improving the product reliability of the MLCC.

The MLCC sorter according to an embodiment of the present invention includes an AC source supplier for applying an AC to an MLCC (Multi Layer Ceramic Capacitor) to cause a current to flow in the MLCC, thereby allowing the MLCC to generate heat by itself; A thermal camera disposed to be spaced apart from the AC source and measuring the temperature of the MLCC; And a controller connected to the AC source supplier and the thermal camera to apply AC to the MLCC at the zero crossing point and to compare the temperature measured by the thermal camera with a preset reference temperature to determine good products of the MLCC .

According to another aspect of the present invention, there is provided an MLCC sorter comprising: a preliminary measurement stage for measuring and selecting at least one of electrostatic capacity, loss, and withstanding voltage of an MLCC (Multi Layer Ceramic Capacitor); An AC measurement stage disposed at one side of the preliminary measurement stage for measuring a self-heating temperature of the MLCC; A DC measurement stage disposed at one side of the AC measurement stage to measure a direct current (DC) characteristic of the MLCC; A transfer stage disposed at one side of the preliminary measurement stage for simultaneously transferring at least one MLCC to a preliminary measurement stage and an AC measurement stage and a DC measurement stage; The transfer stage being coupled to the transfer stage to control the transfer stage so that the one or more MLCCs are simultaneously transferred to the preliminary measurement stage and to the AC measurement stage and to the DC measurement stage and to transfer the measured values measured in the preliminary measurement stage, And a controller that compares defective MLCCs and good products by comparing the reference values stored in advance.

The MLCC sorter of the present invention is advantageous in that MLCC can be selected by using the self-heating temperature characteristic generated by allowing current to flow in the MLCC by applying alternating current to the MLCC using the zero crossing control, The MLCC can be selected by using the self-heating temperature characteristic generated by flowing the MLCC, and it is possible to detect a minute crack generated in the MLCC. By detecting the minute crack generated in the MLCC, the MLCC There is an advantage that the reliability of the product can be improved.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a view showing a configuration of an MLCC sorter of the present invention,
FIG. 2 is a view showing another embodiment of the MLCC sorter shown in FIG. 1;
3 shows another embodiment of the ac measurement stage shown in Fig. 2, Fig.
4 shows another embodiment of the DC measurement stage shown in Fig. 2. Fig.
5 is a table showing the measurement results of MLCC using the MLCC sorter shown in FIG.

Hereinafter, an embodiment of the MLCC sorter of the present invention will be described with reference to the accompanying drawings.

1, the MLCC sorter according to an exemplary embodiment of the present invention includes an AC source supply unit 121a, a thermal camera 121c, and a controller 150. As shown in FIG.

The AC source supply unit 121b applies AC to the MLCC (Multi Layer Ceramic Capacitor) 1 so that current flows through the fired body 1a which is the dielectric of the MLCC 1, thereby causing the MLCC 1 to generate heat by itself . That is, the AC source supply 121b varies the level, frequency, and application time of the AC effective voltage according to the electrostatic capacity of the MLCC 1 and applies it to the MLCC 1 to increase the ripple current generated by the MLCC 1 So that the MLCC 1 generates heat by itself and uses a zero crossing control method when AC is applied to the MLCC 1. Here, the variable frequency range of the alternating current is set to 10 kHz to 1 MHz.

The AC source supply 121b generates an effective voltage level, a frequency and an application time of a sinusoidal wave or a square wave of a high frequency at or below a threshold voltage of the MLCC 1 when the alternating current is variable, (1) to lower the capacitive reactance of the MLCC (1) and increase the amount of current passing through the dielectric of the MLCC (1), thereby raising the self heating temperature of the MLCC (1). The zero crossing control method is implemented through the programming of the controller 150 and allows the AC output from the AC source feeder 121b to be applied to the MLCC 1 at the time of zero crossing under the control of the controller 150.

The effective voltage level or frequency is varied according to the electrostatic capacity of the MLCC 1. The larger the electrostatic capacity of the MLCC 1 is, the greater the effective voltage level, the frequency, and the application time are applied to the MLCC 1. The thermal camera 121c is disposed so as to be spaced apart from the AC source feeder 121b and measures the self heating temperature generated in the MLCC 1. The controller 150 controls the AC source feeder 121b and the thermal camera 121c And the alternating current is applied to the MLCC 1 at the time of zero crossing. The self-heating temperature measured by the thermal camera 121c is received and compared with the reference temperature to judge whether the AC is good or not. 5, when an alternating current having an effective voltage of 20 V and a frequency of 15 KHz is applied to the MLCC 1 in the AC source supply 121b for 10 seconds, the effective current in the case of the good MLLC (1) 5.2 A and a self-heating temperature of 59 ° C, whereas for a defective MLCC (1) the effective current was 5.7 A and the self-heating temperature was measured at 60 ° C. That is, the good MLCC 1 is measured to have its own heating temperature lower than the defective MLCC 1 by about 1 ° C, and the controller 150 measures the temperature of the MLCC 1 measured by the thermal camera 121c The self-heating temperature is received and compared with the reference temperature to determine whether it is good or not.

The controller 150 controls the temperature of the MLCC 1 such that alternating current generated by varying at least one of the effective voltage level of AC, the frequency, and the application time according to the capacity of the MLCC 1 is applied to the MLCC 1, Is measured by the thermal camera 121c, the temperature measured by the good MLCC 1 among the measured temperatures is set as a reference temperature and stored. The setting of the reference temperature is performed by applying AC to the MLCC 1 from the AC source supply unit 121b, and then, when the temperature of the heat generated by the MLCC 1 is photographed by the thermal camera 121c, And then stored in the controller 150 after setting the result of the test whether the electrical characteristics of the tested MLCC 1 are stable for a long time. That is, the controller 150 changes the at least one of the effective voltage level, the frequency, and the application time of the AC according to the capacity of the MLCC 1 by the AC source supply unit 121b, and the generated AC is applied to the MLCC 1 When the self-heating temperature of the MLCC 1 is measured by the thermal camera 121c, the temperature measured by the good MLCC 1 among the measured temperatures is set as the reference temperature.

An MLCC sorter according to another embodiment of the present invention is shown in FIG. 2, the MLCC sorter according to another embodiment of the present invention includes a preliminary measurement stage 110, an AC measurement stage 120, a DC measurement stage 130, a transfer stage 140, and a controller 150 .

1, the preliminary measurement stage 110 measures and selects at least one of the electrostatic capacity, the loss and the withstand voltage of the MLCC 1, and the AC measurement stage 120 is disposed at one side of the preliminary measurement stage 110 The self-heating temperature of the MLCC 1 is measured. The DC measurement stage 130 is disposed on one side of the AC measurement stage 120 to measure DC direct current characteristics of the MLCC 1 and the transfer stage 140 is disposed on one side of the preliminary measurement stage 110 And simultaneously transports one or more MLCCs 1 to the preliminary measurement stage 110, the AC measurement stage 120, and the DC measurement stage 130. The controller 150 is coupled to the transfer stage 140 so that one or more MLCCs 1 are simultaneously transferred to the preliminary measurement stage 110 and the AC measurement stage 120 and the DC measurement stage 130, And compares the measurement values measured in the preliminary measurement stage 110, the AC measurement stage 120 and the DC measurement stage 130 with the previously stored reference values to select defective and good products of the MLCC 1.

Hereinafter, the configuration of an MLCC sorter according to another embodiment of the present invention will be described in detail.

The preliminary measurement stage 110 is constituted by a capacitance and loss measurement stage 111 and a withstand voltage measurement stage 112 as shown in FIG.

The capacitance and loss measurement stage 111 is disposed on one side of the transfer stage 140 and applies a direct current (DC) voltage to one or more MLCCs 1 transferred by the transfer stage 140, And a jig 111a and an LCR (elongation) measuring device 111b. The jig 111a supports one or more MLCCs 1 transferred by the transfer stage 140. [ The LCR measuring device 111b measures the capacitance and loss of the MLCC 1 connected to the jig 111a and supported by the jig 111a.

The withstand voltage measurement stage 112 is disposed on one side of the capacitance and loss measurement stage 111 and is connected to the MLCC 1 via the MLCC 1 when the MLCC 1 whose electrostatic capacity and loss are measured is transferred by the transfer stage 140. ), That is, about 3 to 4 times the rated voltage, to measure the withstand voltage characteristic, and comprises a jig 112a and an withstand voltage measuring device 112b. The jig 112a supports one or more MLCCs 1 transferred by the transfer stage 140 and the withstand voltage meter 112b is connected to the MLCC 1 supported by the jig 112a in connection with the jig 112a. The breakdown voltage characteristic is measured by applying a voltage equal to or higher than the rated voltage of the MLCC 1.

The AC measurement stage 120 is composed of an AC charging stage 121 and one or more AC discharging stages 122 as shown in FIG.

The AC charging stage 121 measures the self-heating temperature generated in the MLCC 1 by applying an alternating current to the MLCC 1 and supplies the jig 121a, the AC source supply 121b, And a thermal camera 121c. The jig 121a supports one or more MLCCs 1 transferred by the transfer stage 140 and the AC source supply 121b is connected to the MLCC 1 So that the MLCC 1 is allowed to generate heat by itself due to an increase in the ripple current generated by the current flowing through the dielectric of the MLCC 1. [ The thermal camera 121c is disposed so as to be spaced apart from the AC source feeder 121b and measures the self-heating temperature generated in the MLCC 1 and transmits the measured temperature information to the controller 150. [

One or more AC discharge stages 122 are disposed on one side of the AC charging stage 121 so that when the MLCC 1 whose self heating temperature is measured is transferred by the transfer stage 140, And comprises a jig 122a and a conductive discharge tube 122b as shown in FIGS. 2 and 3, respectively. The jig 122a supports one or more MLCCs 1 transferred by the transfer stage 140 and the conductive discharge tube 122b is connected to the MLCC 1 To discharge the alternating current charged.

The DC measurement stage 130 includes at least one DC charge stage 131 and an IR (Insulation Resistance) measurement stage 132 as shown in FIG. 2 and FIG.

One or more dc charging stages 131 are arranged on one side of the transfer stage 140 so as to be spaced apart from each other and a direct current is applied to one or more MLCCs 1 transferred by the transfer stage 140 to sequentially transfer the MLCC 1 And comprises a jig 131a and a DC source supplier 131b. The jig 131a supports one or more MLCCs 1 transferred by the transfer stage 140 and the DC source supplier 131b is connected to the MLCC 1 ) Is applied to the MLCC 1 to charge the MLCC 1 with a DC voltage that is two to three times the rated voltage of the MLCC 1.

The IR measurement stage 132 is disposed on one side of the DC charging stage 131 and measures a leakage current when the MLCC 1 charged with DC is transferred by the transfer stage 140 after the temperature of self- And selects a faulty insulation resistance of the MLCC 1, and comprises a jig 132a and an IR measuring device 132b. The jig 132a supports one or more MLCCs 1 transferred by the transfer stage 140 and the IR measuring device 132b is connected to the MLCC 1 supported by the jig 132a in connection with the jig 132a. The MLCC 1 is selected.

The transfer stage 140 is constructed using a linear transfer mechanism or a turntable (not shown) and a rotating mechanism as shown in FIG. 2, and the jigs 111a, 112a, 121a, 122a, 131a, (Not shown) so as to support the MLCC 1.

The controller 150 generally controls the MLCC sorter of the present invention and receives measured measurement information from the preliminary measurement stage 110, the AC measurement stage 120 and the DC measurement stage 130, And determines whether the MLCC 1 is good or not. This controller 150 controls the transfer stage 140 so that one or more MLCCs 1 are simultaneously transferred from the AC measurement stage 120 to the DC measurement stage 130, The temperature of the MLCC 1 is measured after completion of the temperature measurement of the MLCC 1 to complete the measurement of the temperature of the MLCC 1 and the transfer stage 140 so that the MLCC 1 having completed the temperature measurement is transferred to the DC measurement stage 130 in a stepwise manner.

An MLCC selecting apparatus according to the present invention having the above-described configuration will now be described.

1, the MLCC 1 includes a fired body 1a as a dielectric and an internal electrode layer 1b so as to be alternately staggered inside the fired body 1a. The internal electrode layer 1b includes a fired body 1a, And the external electrode layer 1c is formed on one side and the other side of the external electrode layer 1c. First, one or more MLCCs 1 are transferred to a preliminary measurement stage 110 and an AC measurement stage (not shown) by using a transfer stage 140 in order to select the good and defective products after the MLCC 1 is manufactured, 120 and the DC measurement stage 130 in sequence.

The transfer stage 140 includes a transfer plate 141 and a plurality of guide members 142 spaced apart from the transfer plate 141 by a predetermined distance. The MLCC 1 is supported by the guide member 142 and transported in conjunction with the conveyance of the conveyance plate 141. [ The feed plate 141 is formed with grooves (member number non-base material) so that the jigs 111a, 112a, 121a, 122a, 131a, and 132a are lifted and elevated by an elevating mechanism (not shown) to support the MLCC 1 . 2, the jigs 111a, 112a, 121a, 122a, 131a and 132a are formed of a pair of conductive plates 11 and 12, and the pair of conductive plates 11, Is elevated to support the MLCC 1. When the MLCC 1 is supported on the conductive plate 12, the conductive plate 11 is moved up and down so that the pair of conductive plates 11 and 12 are electrically connected to the external electrode layer 1c of the MLCC 1, So that alternating current or direct current is applied to the MLCC 1 through the conductive plates 11 and 12 or the output is transmitted to the measuring devices 111b, 112b and 132b.

When one or more MLCCs 1 are transferred to the preliminary measurement stage 110 by the transfer stage 140, the capacitance and loss measurement stages 111 of the preliminary measurement stage 110 are coupled to the MLCC 1, And an LCR measuring device 111b is used to measure the capacitance and the loss. The loss of the MLCC 1 is caused by the direct current flowing through the sintered body 1 of the MLCC 1 when the DC current is applied to the MLCC 1 to prevent current flow by the sintered body 1 of the MLCC 1 The value of the lost current generated due to the reception is shown.

When the electrostatic capacity and the loss of the MLCC 1 are measured, one or more MLCCs 1 are again transferred to the withstand voltage measurement stage 112 to measure the withstand voltage. The withstand voltage measurement stage 112 selects whether or not the DC voltage is normally operated even if a direct current corresponding to three to four times the rated voltage of the MLCC 1 is applied to both ends of the sintered body 1 of the MLCC 1. [

When the withstand voltage measurement of the MLCC 1 is completed, the MLCC 1 is transferred to the AC measurement stage 120 by the transfer stage 140. When the MLCC 1 is transferred to the AC measurement stage 120, the AC charge stage 121 of the AC measurement stage 120 applies an AC with an input condition to the MLCC 1 as shown in the table of FIG. For example, as shown in FIG. 5, if an alternating current having an effective voltage of 20 V and a frequency of 20 KHz is applied to the MLCC 1 for 10 seconds, the MLCC 1 self-generates heat and the heated state is transmitted to the thermal camera 121c And the temperature of the MLCC 1 is measured.

The measurement results are shown in FIG. 5. In the case where AC is applied to the MLCC (1) under the above conditions, the good MLCC (1) has an effective current of 6.7 A (amperes) and a temperature of 70 ° C. On the other hand, in the case of the defective MLCC (1) in which a fine crack occurred, the measurement result is measured at a temperature of 72 占 폚 with an effective current of 7.1 A as in Fig. That is, the good MLCC 1 without fine cracks is measured by 1 to 3 ° C lower than that of the defective MLCC 1 having a fine crack, and is received by the controller 150 to determine whether the MLCC 1 is good or bad . The controller 150 discriminates the good and bad of the MLCC 1 using the AC measurement result described above in the AC measurement stage 120 or determines defects with the good product after the IR selection process described below.

When the self-heating test of the MLCC 1 is completed in the AC charging stage 121, the MLCC 1 is sequentially transferred to the one or more AC discharge stages 122 by the transfer stage 140, . The MLCC 1, which has completed the discharge of the AC, is sequentially transferred to the at least one DC charging stage 131 step by step by the transfer stage 140 so that the DC according to the rated voltage of the MLCC 1 is charged repeatedly.

Once DC is repeatedly filled in the MLCC 1, the MLCC 1 is transferred to the IR measurement stage 132 by the transfer stage 140. The IR measurement stage 132 measures the leakage current using the DC charged in the transferred MLCC 1 and compares it with a previously stored leakage current to select the MLCC 1 as good or defective. The MLCC 1 is subjected to stress or the like due to its own heat while the MLCC 1 passes through the AC measurement stage 120 when a good product or defect is selected in the IR measurement stage 132 in the MLCC 1, There is a possibility that a leakage current may increase and a failure may occur. That is, the controller 150 selects the good and bad of the MLCC 1 using the AC measurement result in the AC measurement stage 120, and finally selects the good and bad of the MLCC 1 in the IR measurement stage 132 .

As described above, the MLCC sorter according to the present invention uses alternating current to the MLCC by using the zero crossing control in addition to the IR measurement, so that current flows through the dielectric of the MLCC, thereby increasing the self-heating temperature due to the rise of the ripple current. It is possible to easily detect defects of the MLCC 1 due to the minute cracks that are generated.

The MLCC sorter of the present invention can be applied to a test industry field of a passive device such as an MLCC.

110: preliminary measurement stage 111: capacitance and loss measurement stage
112: withstand voltage measurement stage 120: AC measurement stage
121: AC charging stage 122: AC discharge stage
130: DC measurement stage 131: DC charge stage
132: IR measurement stage 140: transfer stage
150:

Claims (15)

An AC source supplier for applying an alternating current to an MLCC (Multi Layer Ceramic Capacitor) to allow a current to flow through the dielectric of the MLCC, thereby causing the MLCC to generate heat by itself;
A thermal camera disposed to be spaced apart from the AC source and measuring the temperature of the MLCC;
And a controller connected to the AC source supplier and the thermal camera to apply AC to the MLCC at the time of zero crossing and to compare the temperature measured by the thermal camera with a preset reference temperature to determine good products of the MLCC ,
The AC source supply generates a sinusoidal wave or a square wave having a high frequency below the limit voltage of the MLCC and applies it to the MLCC to lower the capacitive reactance of the MLCC and increase the amount of current passing through the dielectric of the MLCC, thereby raising the self- Wherein the MLCC selector is a MLCC selector. The method according to claim 1,
The AC source supply unit alternately generates AC by varying at least one of an AC voltage level, an AC voltage level, and an application time according to the capacity of the MLCC, and applies the generated AC to the MLCC. The frequency is 10 kHz to 1 MHz Featured MLCC selector. delete The method according to claim 1,
The controller adjusts the AC voltage of the AC power supply according to the capacity of the MLCC, the frequency and the application time of the AC voltage, and generates the AC power of the MLCC. When the temperature of the MLCC is measured by the thermal camera, Wherein the temperature measured by the MLCC is set to a reference temperature. A preliminary measurement stage for measuring and selecting at least one of electrostatic capacity, loss and withstand voltage of an MLCC (Multi Layer Ceramic Capacitor);
An AC measurement stage disposed at one side of the preliminary measurement stage for measuring a self-heating temperature of the MLCC;
A DC measurement stage disposed at one side of the AC measurement stage to measure a direct current (DC) characteristic of the MLCC;
A transfer stage disposed at one side of the preliminary measurement stage for simultaneously transferring at least one MLCC to a preliminary measurement stage and an AC measurement stage and a DC measurement stage;
The transfer stage being coupled to the transfer stage to control the transfer stage so that the one or more MLCCs are simultaneously transferred to the preliminary measurement stage and to the AC measurement stage and to the DC measurement stage and to transfer the measured values measured in the preliminary measurement stage, And a controller for comparing the pre-stored reference value with the defective MLCC and selecting a good product,
Wherein the loss of the MLCC is a lost current value generated when a direct current is applied to the MLCC due to the direct current interfering with the current flow by the sintered body of the MLCC due to passing through the sintered body of the MLCC. 6. The method of claim 5,
Wherein the preliminary measurement stage comprises: a capacitance and loss measurement stage arranged at one side of the transfer stage for applying a direct current (DC) voltage to one or more MLCCs conveyed by the transfer stage to measure capacitance and loss respectively;
And a dielectric voltage measurement stage arranged at one side of the capacitance and loss measurement stage and measuring an withstand voltage characteristic by applying an MLCC rated voltage or more to the MLCC when the MLCC whose electrostatic capacity and loss are measured is transferred by the transfer stage MLCC selector. The method according to claim 6,
The capacitance and loss measurement stage comprising: a jig supporting one or more MLCCs carried by the transfer stage;
And an LCR (elongation) measuring unit connected to the jig for measuring capacitance and loss of the MLCC supported by the jig. The method according to claim 6,
Wherein the withstand voltage measuring stage comprises: a jig supporting one or more MLCCs transferred by the transfer stage;
And an inrush voltage meter for measuring a withstand voltage characteristic by applying a voltage equal to or higher than a rated voltage of the MLCC to the MLCC connected to the jig and supported by the jig. 6. The method of claim 5,
Wherein the AC measurement stage comprises: an AC charging stage for measuring a self-heating temperature generated in the MLCC by applying an alternating current to the MLCC;
And at least one AC discharge stage disposed at one side of the AC charging stage and discharging an AC applied to the MLCC when the MLCC whose self heating temperature is measured is transferred by the transfer stage. 10. The method of claim 9,
The AC charging stage comprising: a jig supporting one or more MLCCs transferred by the transfer stage;
An AC source supplier for causing the MLCC to generate heat due to an increase in ripple current generated by applying an alternating current to the MLCC connected to the jig and causing current to flow through the dielectric of the MLCC;
And a thermal camera arranged to be spaced apart from the AC source and measuring a self-heating temperature generated in the MLCC. 10. The method of claim 9,
The one or more AC discharge stages each having a jig supporting one or more MLCCs transferred by a transfer stage;
And an electric discharge chamber connected to the jig for discharging the alternating current charged in the MLCC supported by the jig. 6. The method of claim 5,
The DC measurement stage comprising: at least one DC charging stage arranged at one side of the transfer stage for applying DC to one or more MLCCs conveyed by the transfer stage to charge the MLCC;
An IR (Insulation Resistance) circuit for measuring the leakage current of the MLCC when the MLCC having the DC charged therein is transferred by the transfer stage after the self-heating temperature is measured, And a measurement stage. 13. The method of claim 12,
The one or more dc charging stages each comprising a jig supporting one or more MLCCs carried by the transfer stage;
And a DC source supplier connected to the jig to charge the MLCC by applying DC to the MLCC supported by the jig. 13. The method of claim 12,
The IR measurement stage comprising: a jig supporting one or more MLCCs carried by the transfer stage;
And an IR measuring device connected to the jig for measuring an insulation resistance of the MLCC supported by the jig. 6. The method of claim 5,
When the temperature of the MLCC is completed after a certain time delay so that the temperature measurement of the MLCC is completed in the AC measurement stage, the temperature measurement is performed when the temperature of the MLCC is measured And controls the transfer stage so that the completed MLCC is step-transferred to the DC measurement stage.

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