JPS6033411Y2 - Earth fault resistance meter - Google Patents

Description

[Detailed Description of the Invention] The present invention relates to a ground fault resistance meter that measures the ground fault resistance of a battery.

Because batteries have an electromotive force, it is not possible to measure ground fault resistance using a megger, etc., as with ordinary electrical equipment.

Therefore, the circuit shown in FIG. 1 has conventionally been used to measure the ground fault resistance of a battery group.

In the figure, 1 is a DC voltage source for measurement, 2 is a switch for switching between balance and measurement, 3 is a DC ammeter that displays the ground fault resistance value, 4 is a variable resistor for balance, and 5 is for matching and measurement. 6 is a matching reference resistor, 7 is a battery group to be measured, and 8 is a ground fault resistance of the battery group 7.

The method for measuring ground fault resistance using this circuit is as follows.

First, turn the changeover switch 2 toward the side where the voltage source 1 is not needed (balanced in the figure), then turn the changeover switch 5 toward the battery group to be measured (measurement in the figure), and the DC ammeter 3 will read 0. Adjust the balancing variable resistor 4 so that

Next, the changeover switches 2 and 5 are turned in the opposite direction, and the voltage of the DC voltage source 1 is adjusted so that the indication on the DC ammeter 3 becomes equal to the resistance value of the matching reference resistor 6.

Next, when the selector switch 5 is turned again toward the battery group and the reading on the ammeter 3 at that time is read, it is the ground fault resistance value of the battery group 7.

As described above, the conventional ground fault resistance meter for battery groups has many operating points and is cumbersome to handle.

Furthermore, because the balancing variable resistor 4 is directly connected between the positive terminals of the battery group due to the circuit configuration, the resistor generates a large amount of heat, which limits its usage time.

An object of the present invention is to eliminate the above-mentioned drawbacks and to provide a ground fault resistance meter that can automatically measure the ground fault resistance of a battery group without requiring manual operation.

The gist of the present invention to achieve the above object is as follows.

That is, a voltage sensor with an internal resistance Rg detects the voltage Vx between the ground and the negative terminal of the battery group, the voltage Vy1 between the ground and the positive terminal of the battery group, and the terminal voltage 8 of the battery group, and these three voltage values are detected. Composite ground fault resistance RxRx=Rg(V
a/ (Vy Vx) t> (1)
, the ground fault position P when the ground fault resistance RX equivalently causes a ground fault at one point (however, O≦P≦1) p=Vy7' (Vy-Vx)
(2) This is a ground fault resistance meter that has the function of automatically calculating and displaying.

Equation (1) is an equation for calculating the composite ground fault resistance Rx, and this equation was obtained as follows.

FIG. 2 is a diagram showing the voltage and current at each part when a ground fault occurs at (n-1) locations.

9 is a battery group to be measured, 10 is (n-1) ground fault resistances,
11 and 13 are switches that turn on and off the voltmeter 12 having an internal resistance Rg.

In the figure, when the switch 11 is closed and the switch 13 is opened, the current flowing through each fault resistance B19 R2...Ro-1 is 11. I2...L-1, switch 13
The current when the door is closed and the switch 11 is opened is I'1゜1/
, · Tsubasa'n-1.

First, when the switch 11 is closed and the switch 13 is opened, the following equations (3) to (9) are established.

V□=RIIl +RgIx
(3) V2=R21z RIL
(4) Vk = Rklk - Rk-1 to -1 (5) Vn-l = Rn -lIn-1 - Rn-2
In-2(6)v=V1+V2+...10Vk+...
10Vn (7)Ix=11+I2+...
・+Ik+...+In-1(8)Vx=-Rglx
(9) Calculating lx from these formulas, Ix= (V, -RgIx) /R□+(V1+V2
-Rglx) /R20...+(V1+V2+...
10Vk −RgIx ) /Rk10...+(V1+V
2+...+Vk+・"+Vn-1-Rglx) /R
n −1(1(1).

Next, when the switch 13 is closed and the switch 11 is opened, the following equations (11) to (17) are established.

Vn =Rn-II'n-1+Rg13/
(11) Vn-1=Vn-2I'n-2-R
n-II'n-1(12)vy=Ri<-11'-
1-RkI'k (13)■3=R2■
'2-R3■'3 (14) V2=RII'l R2I'2
(15) Iy: I'1+I'2+-+I'+-
+I'n-1 (16)Vy=RgIy
(17) From these formulas, I
To find y, iy= (Vn-RgIV) /Rn 1 + (Vn
10Vn-1-RgIy) /Rn-2+...+(V
n10Vn-1+-+VkRgIy) /Rk 1 +
...+ (Vn ten Vn-1+...+Vk ten-+V3
Rgly) /R*+”+ (Vn 10 Vn-10-+V
k+-+V3+Vz-Rgly)/R□(18).

Here, when αG+(18) is calculated, Ix + Iy == (
vl+v2+-+vn-Rgly-RgIx) /R□
10 (Vt+Vz+”+Vn-RgIy-RgIx)/
R2+-10("i10V2+"4Vn-RgIy-RgI
x) /Rn-1(19) Substituting (7), (9), and (17) into (19) gives (V
y Vx) /Rg= (V - Vy + Vx) /R
1+(V.

Vy 10Vx) /R2+ ”・+(V Vy+VX
) / ”-1= (V-Vy+Vx) (1/R1+
1/R2+-+1/Rn-1)
(20) Here 1/R= (1/Rx
+1 /R2+"+ l /Rn-1), then R=Rg (VB/ ("y-Vx) 1)
(21) We obtain (21).

Therefore, no matter where ground faults occur at many locations and at what resistance values in the battery group, (21
), that is, equation (1), can measure the combined value of ground fault resistance.

Equation (2) is a formula for calculating the ground fault position P (0≦P≦1) assuming that a ground fault occurs at one point equivalently by the composite ground fault resistance Rx, and this formula was obtained as follows. .

FIG. 3 is a diagram illustrating the assumption that the composite ground fault resistance Rx is at a position that divides the terminal voltage VB of the battery group into Va and vb.

When switch 13 is closed and switch 11 is opened, vb
is Vb=Vy ten (Vy/Rg) ・Rx
(22).

Substituting (1) into (22) and setting P=Vb/V, p=Vb/VB=Vy/ (Vy-Vx)
(23).

Next, this invention will be specifically explained with reference to embodiments illustrated in the drawings.

FIG. 4 is a diagram showing a hardware block diagram of the ground fault resistance meter of the present invention, and the core of the configuration is an 8-bit parallel processing type microprocessor.

In FIG. 4, numeral 14 is an arithmetic unit using a microprocessor, and numeral 16 connects the ground, the positive and negative terminals of the battery group, and the terminals at both ends of the battery group in order to calculate Vx, Vy,
This is a voltage sensor with an internal resistance Rg that receives the voltage of V8 as an input, and consists of a relay and an amplifier for impedance conversion, and outputs a voltage signal proportional to the voltage values of Vx, Vy, and VB.

15 is a means for measuring the values of VX, Vy, and VB, which is composed of an oil converter that converts the analog voltage signal from 16 into a digital value that can be processed by a microprocessor.

17 is a battery group to be measured, and 18 is a ground.

Reference numeral 19 is a display section that displays the ground fault resistance value, and 20 is a display section that displays the ground fault position.

FIG. 5 is a schematic diagram of a software flowchart of the ground fault resistance meter of the present invention.

The present invention has the configuration described above, and can obtain the following effects.

Since the ground fault resistance of the battery can be automatically measured without the need for human operations, and the ground fault location is also displayed, countermeasures can be taken promptly when a ground fault occurs.

[Brief explanation of the drawing]

FIG. 1 is a circuit diagram of a conventional battery ground fault resistance meter. FIG. 2 is a diagram showing the voltage and current of each part when a ground fault occurs at (n-1) locations. Figure 3 shows that the composite ground fault resistance Rx changes the battery voltage ■8 to Va and vb.
FIG. FIG. 4 is a diagram showing a hardware block diagram of an embodiment of the present invention. FIG. 5 is a schematic diagram of the software flowchart of the embodiment. ? , 9.17...Battery group to be measured, 14...
...Arithmetic unit, 15... Means for measuring voltage value,
16...Voltage sensor, 19...Display section for displaying ground fault resistance, 20...Display section for displaying ground fault position.

Claims (1)

[Scope of utility model registration request] Voltage sensor of internal resistor UG, voltage Vx between the ground and the negative terminal of the battery group, voltage vy between the ground and the positive terminal of the battery group, and terminal voltage of the battery group ■ Voltage of 8 A method for measuring the voltage value, and a ground fault based on these three voltage values, assuming that there is an equivalent ground fault at one point due to the synthetic ground fault resistance Rx between the ground and the battery group and the synthetic ground fault resistance Rx from the battery group. The contact position P is Rx = Rg
(VB/ (”y Vx) 1) and P=Vy/ (
A ground fault resistance meter comprised of a calculation unit that calculates the calculation result of Vy −Vx) and a display unit that displays the calculation result of the calculation nose.