KR0133067Y1 - Polarity checking circuit of electrolytic condenser - Google Patents

Abstract

The present invention is a constant voltage generating means for supplying a constant voltage to the first coupling terminal electrically coupled to the + terminal of the electrolytic capacitor, and the second coupling terminal and the case of the electrolytic capacitor electrically coupled to the-terminal of the electrolytic capacitor Amplifying means for amplifying the voltage applied to the coupled third coupling terminal as an input, analog / digital converting means for converting the analog signal output from the amplifying means into a digital signal, and outputted from the analog / digital converting means. It consists of a microcomputer that compares the data value with the reference data value and checks whether the two terminals of the electrolytic capacitor are inserted in the forward position by circuit. Is the electrolytic capacitor inserted on the printed circuit board inserted in the circuit forward direction? The microcomputer judges and displays the result, so the polarity check of the inserted part is performed automatically. Can according to improve the yield and productivity of airborne.

Description

Polarity check circuit of electrolytic capacitor

1 is a view showing an internal cross section of the electrolytic capacitor.

2 is an equivalent circuit diagram of an electrolytic capacitor.

3 and 4 is a view showing the polarity check principle of the electrolytic capacitor according to the present invention.

5 is a polarity check circuit diagram of an electrolytic capacitor according to the present invention.

* Explanation of symbols for main parts of the drawings

10: constant voltage generating means 20: electrolytic capacitor

30: amplification means 40: analog / digital conversion means

50: microcomputer

The present invention relates to a polarity check circuit of an electrolytic capacitor, and more particularly, to a polarity check circuit of an electrolytic capacitor that checks whether the polarity of the electrolytic capacitor mounted on the printed circuit board is inserted in the forward direction.

The electrolytic capacitor used in the power terminal of all electronic products is inserted at a predetermined position on the printed circuit board by an operator or an automatic inserter. For example, the + terminal and-terminal of the electrolytic capacitor change positions so that the reverse direction When inserted, the electrolytic capacitor may explode when the power is supplied, thereby causing the peripheral circuit device to be destroyed.

Accordingly, the present invention has been made in view of the above problems, and an object of the present invention is to provide an electrolytic capacitor for checking whether the + and-terminals of the electrolytic capacitor are inserted in a predetermined position on the printed circuit board in a forward direction. It relates to a polarity check circuit.

In order to achieve the above object, a polarity check circuit of an electrolytic capacitor according to the present invention includes a constant voltage generating means for supplying a constant voltage to a first coupling terminal electrically coupled to a + terminal of an electrolytic capacitor, and an electrical terminal to a-terminal of the electrolytic capacitor. Amplification means for amplifying the voltage applied to the second coupling terminal coupled to the third coupling terminal electrically coupled to the case of the electrolytic capacitor as an input, and an analog signal for converting the analog signal output from the amplification means into a digital signal. And a digital computer for checking whether two terminals of the electrolytic capacitor are inserted in the circuit forward direction by comparing the digital and digital conversion means with the data value output from the analog and digital conversion means.

Hereinafter, the present invention will be described in more detail with reference to the illustrated drawings.

1 is a diagram showing an internal cross-section of an electrolytic capacitor, in which an electrolytic capacitor 20 is composed of a terminal 3, a + terminal 5, and an aluminum case 1, and an equivalent circuit of the electrolytic capacitor 20. As shown in FIG. 2, the capacitor C is present between the-terminal 3 and the + terminal 5, the impedance Z1 is present between the + terminal 5 and the case (1). Impedance (Z2) is present between the terminal (3) and the case (1), the electrolytic capacitor (20) has a larger area of the terminal (3) than the area of the + terminal (5), the case (1) Since the distance between the terminal and the terminal 3 is made closer, the impedance Z1 between the + terminal 5 and the case 1 is larger than the impedance Z2 between the terminal 3 and the case 1.

3 and 4 show the principle of checking the polarity using an equivalent circuit of an electrolytic capacitor. FIG. 3 shows a small voltage Vs between the + terminal 5 and the-terminal 3 for the forward measurement. Measure the voltage between the case (1) and -terminal (3) located between the impedance (Z1), (Z2) in the state that is applied. The measured voltage at this time is called V1.

And between the case (1) and the + terminal (5) located between the impedance (Z1) (Z2) in the state of applying a small voltage between the-terminal (3) and the + terminal (5) for the reverse measurement as shown in FIG. Measure the voltage of If the measured voltage at this time is V2, V2 is always larger than V1. If V2 is smaller than V1, the two terminals 3, 5 of the electrolytic capacitor 20 are reversed on the printed circuit board. It is easy to determine what is inserted into the.

5 is a circuit for automatically checking the polarity of the electrolytic capacitor using the above characteristics, the constant voltage generating means 10 is a first voltage electrically coupled to the + terminal 5 of the electrolytic capacitor 20, It is configured to supply two coupling terminals (a) and (b).

The amplification means 30 has a third coupling terminal (C) electrically coupled with the case 10 of the electrolytic capacitor 20 and a second coupling terminal electrically coupled with the -terminal 3 of the electrolytic capacitor 20 ( It consists of an operational amplifier (OP) and a resistor (R1 R4) to differentially amplify the voltage of b) as an input.

The analog / digital converting means 40 is configured to convert the analog signal output from the amplifying means 30 into a digital signal, and the microcomputer 50 outputs the data value output from the analog / digital converting means 40. Is compared with the reference data value to automatically check whether the two terminals of the electrolytic capacitor are inserted in the circuit forward state.

Referring to the operation of the subject innovation having the configuration as described above in detail.

As shown in FIG. 5, the first and second coupling terminals (a) and (b) are electrically connected to the + terminal 5 and the-terminal 3 of the electrolytic capacitor 20 inserted into the printed circuit board. In a state where the third coupling terminal c is coupled to the case 1 of the electrolytic capacitor 20, a voltage of a predetermined value output from the constant voltage generating means 10 is transmitted through the first coupling terminal a. When supplied to the + terminal 5 of the 20), the voltage induced in the case 1 of the electrolytic capacitor 20 through the third coupling terminal (C) the inverting terminal of the operational amplifier (op) of the amplification means (30) It is supplied to (-) and differentially amplified with the voltage supplied to the non-inverting terminal (+) (voltage induced on the-terminal 3), and is then supplied to the analog / digital converting means 40.

The analog / digital converting means 40 converts the input analog signal into a digital signal and supplies it to the microcomputer 50 to determine whether the electrolytic capacitor 20 is inserted in the forward direction by comparing with the reference data described later. In the microcomputer 50, as described with reference to FIGS. 3 and 4, the + terminal 5 and the-terminal 3 of the electrolytic capacitor 20 are inserted in the forward direction on the printed circuit board and the + terminal 5 When a predetermined value voltage (Vs = constant voltage) is supplied to the circuit, the voltage V1 between the case 1 and the ground terminal is digitalized and stored as reference data.

Therefore, when the input voltage is less than the reference data value, the microcomputer 50 determines that the electrolytic capacitor 20 is inserted in the reverse direction and displays the result so that the operator separates the electrolytic capacitor 20 from the printed circuit board. To correct it in the forward direction.

According to the present invention, which operates as described above, the microcomputer determines whether the electrolytic capacitor inserted on the printed circuit board is inserted forward so that the polarity check of the inserted part is performed automatically. It can provide the effect of improving the yield and productivity of airborne.

Claims (1)

A constant voltage generating means for supplying a constant voltage to the first coupling terminal electrically coupled to the + terminal of the electrolytic capacitor, and a second coupling terminal electrically coupled to the-terminal of the electrolytic capacitor and a case electrically coupled to the case of the electrolytic capacitor. An amplifying means for amplifying the voltage applied to the three coupling terminals as an input, an analog / digital converting means for converting the analog signal output from the amplifying means into a digital signal, and a data value output from the analog / digital converting means; A polarity checking circuit of an electrolytic capacitor, comprising a microcomputer for comparing two reference data values to check whether two terminals of the electrolytic capacitor are inserted forward in a circuit forward direction.