JPH0339740Y2 - - Google Patents

Description

[Detailed description of the invention] (Field of industrial application) The present invention relates to a device that measures the leakage current of a varistor used in a lightning arrester, etc., and determines whether or not it needs to be replaced. Regarding portable improvements.

(Prior Art) A lightning arrester is inserted into the ground wire or wiring of an electronic meter to limit the lightning surge voltage generated by a lightning strike to a voltage below which does not cause damage to the meter. A varistor is used as a discharge element in this lightning arrester, but since the varistor deteriorates due to surge voltage, it must be replaced if this deterioration becomes significant.

The present applicant has proposed Utility Application No. 61-34342 as a device for measuring leakage current of such a varistor.
FIG. 2 is a block diagram of the structure of the invention disclosed in this proposal. A conventional example will be explained below.

In the figure, a DC voltage is supplied from a commercial power supply 1 via a transformer 2 and a rectifier circuit 3, and is smoothed by a capacitor 4 to become 600 Volt DC. A voltage is applied to the varistor via a constant current circuit consisting of transistors Q1, Q2 and comparator U1.

The operation of the device configured as described above is such that a specified current is passed through the varistor, and the quality of the varistor is determined based on whether or not the voltage value at that time is greater than or equal to the specified value.

(The problem that the idea attempts to solve) However, the conventional device has the following problems.

Since it uses commercial power, it is inconvenient to use. In other words, commercial power must be supplied via cable.

Since 600 Volt of DC is constantly generated, there is a large loss.This invention solves this problem.
The purpose of the present invention is to provide a varistor leakage current measuring device that is easy to handle and has high energy usage efficiency.

(Means for solving the problem) The present invention achieves this purpose by connecting a battery, a switch, and a transistor in series on the primary side.
A transformer with a rectifying element and a smoothing element connected to the secondary side, a varistor to which the DC voltage is applied on the secondary side of this transformer, a current detection resistor connected in series with this varistor, this varistor or the varistor and the current The circuit was constructed with a voltmeter that measures the voltage generated across the detection resistor.

Furthermore, as a feedback loop, the voltage generated across the current detection resistor is detected and a pulse width signal of a predetermined frequency is applied to the base of the transistor, so that the voltage generated across the current detection resistor is constant when the switch is on. A pulse width signal control circuit is added to control the pulse width.

(Function) Each component of the present invention has the following function. The transformer converts the battery voltage into AC by switching, boosts the voltage, rectifies and smoothes it, and then applies a test signal to the varistor. The pulse width signal control circuit controls the pulse width so that a predetermined DC voltage is applied to the varistor.

(Example) The present invention will be explained below using the drawings.

FIG. 1 is a block diagram showing an embodiment of the present invention. In the figure, T1 is a step-up transformer, B is a battery connected to the primary side of the transformer T1, and SW is a switch inserted between the battery B and the transformer T1, which is turned on only when necessary. Q1 is a transistor inserted between the primary side of transformer T1 and battery B, and is used as a switching element.

D1 is a diode connected to the secondary side of the transformer T1, and is used as a rectifying element. C1 is a capacitor inserted between the diode D1 and the secondary side of the transformer T1, and is used as a smoothing element. VA is the varistor to be tested, R1 is a resistor connected in series with the varistor VA, and is used to detect the current flowing through the varistor VA.
V is a voltmeter that measures the voltage generated across the varistor VA and the resistor R1, and is used to determine the quality of the varistor VA.

U1 is a pulse width signal control circuit, which uses a power IC such as TI's TL494, inputs the voltage generated across resistor R1, applies a pulse width signal to the base of the transistor, and keeps the voltage across resistor R1 constant. This keeps the current flowing through the varistor VA constant.

The operation of the device configured in this manner will be described next. Connect the varistor VA to be tested and turn on the switch.
When the SW is turned on, the pulse width signal control circuit U1 oscillates at the set frequency. Then capacitor C
1 rises and reaches the discharge voltage of the varistor VA, causing current to flow into the resistor R1. The pulse width signal control circuit U1 controls on/off of the transistor Q1 so that the voltage across the resistor R1 is constant. This is so-called PWM control.

That is, since constant current control is performed so that the voltage across the resistor R1 is constant, it is possible to accommodate varistors VA having different discharge voltages.

Also, the voltage of capacitor C1 varies depending on the discharge voltage of varistor VA, but
In VA, the voltage generated across the capacitor C1 may be low, so it can be tested efficiently.

(Effects of the invention) As explained above, the invention has the following effects.

Since a switching regulator type constant current source is used, current consumption is low and battery drive is possible.

A switching regulator is used to generate the minimum voltage required for inspection, resulting in high efficiency and long battery life.

Since it uses batteries, it is small, lightweight, and portable.

[Brief explanation of drawings]

FIG. 1 is a block diagram showing an embodiment of the present invention, and FIG. 2 is a block diagram of a conventional device. B...Battery, C1...Capacitor, D1...Diode, Q1...Transistor, R1...Current detection resistor, SW...Switch, T1...Transformer, U1...Pulse width signal control circuit, V...Voltage Total, VA...barista.

Claims (1)

[Claims for Utility Model Registration] A transformer in which a battery, a switch, and a transistor are connected in series on the primary side, and a rectifying element and a smoothing element on the secondary side. A DC voltage is applied on the secondary side of this transformer. A current detection resistor connected in series with this varistor, a voltmeter that measures the voltage generated in this varistor or the varistor and the current detection resistor, and a pulse width of a predetermined frequency that detects the voltage generated in this current detection resistor. a pulse width signal control circuit that applies a signal to the base of the transistor so that the voltage generated across the current detection resistor is constant when the switch is on; Current measuring device.