JPH0750137B2 - Grounding Surge Impedance Measuring Device - Google Patents

Description

Description: TECHNICAL FIELD The present invention relates to an improvement of a measuring device for measuring ground surge impedance of a steel tower or the like of a transmission line.

[Prior Art] FIG. 5 shows the configuration of a ground surge impedance measuring device according to the prior art. In the figure, in order to measure the grounding surge impedance of the auxiliary grounding electrode (7) provided on the tower leg (1) of the transmission line, etc., a pulse is generated at an appropriate connection point (16) of the tower leg (1). The output terminal of the device (9) is connected via a resistor (R). The oscilloscope (15) is capable of observing two phenomena at the same time, and the voltage induced in the resistor (R) is input to one of its input terminals. The voltage induced in the resistor (R) is proportional to the pulse current flowing from the pulse generator (9) to the tower leg (1). A wire (17) for detecting the voltage induced in the tower (1) is connected to the base of the tower (1), and the other end of the wire (17) is connected to the other input terminal of the oscilloscope. ing. To measure the ground surge impedance with this conventional ground surge impedance measuring device, a pulse voltage of, for example, 5 KV is applied to the tower leg (1) from the pulse generator (9). In this case, the current normally flows by several amperes, and the voltage generated across the resistor (R) by the current is input to the oscilloscope (15) and the voltage is measured.
The resistance (R) is calculated from the measured voltage value and the resistance (R) value.
The current value flowing through is calculated. In addition, the voltage at the base of the tower (1) passes through the lead wire (17) and the oscilloscope (1
It is input to the other input terminal of 5) and the voltage value is measured. The oscilloscope display is typically photographed and the voltage and current are determined from the photographs. The surge impedance was calculated by dividing the former by the latter.

[Problems to be Solved by the Invention] In the conventional ground surge / impedance measuring device, in order to measure impedance, the display surface of the oscilloscope must be photographed and the impedance value must be calculated from the peak value. Not only is it very busy, but the pulse generator (9) applied to the tower stake (1)
Pulse current is divided into one that flows from the connection point (16) to the auxiliary grounding electrode (7) connected to the base of the steel tower and one that also flows in the upper direction of the tower leg (1) shown by the arrow (B). Therefore, even if the induced voltage is divided by the pulse current flowing through the resistor (R), the ground surge impedance cannot be accurately measured. Further, since it is not possible to continuously measure by the method of measuring from the photographic image, it is not possible to know the temporal change of the ground resistance of the auxiliary ground electrode (7). In addition, it has been impossible to detect disconnection of the auxiliary ground electrode by the conventional method.

[Means for Solving the Problems] The ground surge impedance measuring device of the present invention uses a pulse generator at a position above a connection point of the auxiliary ground electrode to a tower leg having an auxiliary ground electrode of a steel tower such as a transmission line. A current measuring means for applying a pulse voltage and providing a toroidal coil on the tower between the application point of the pulse voltage on the tower and the connection point of the auxiliary ground electrode to measure the current flowing through the tower by the output of the integrating circuit. The current value of the output of the column is provided with first sampling means for obtaining data of a predetermined number of current values sampled in a predetermined cycle, and a first memory for storing the data of the predetermined number of current values. Second sampling means for sampling the voltage value of the output of the voltage measuring means for measuring the voltage at the predetermined cycle to obtain a predetermined number of sampled voltage value data, and the second sampling means. A second memory for storing a predetermined number of voltage value data is provided, and based on the predetermined number of current value data stored in the first memory and the predetermined number of voltage value data stored in the second memory. , A recorder for displaying the predetermined number of impedance values and a recorder for displaying the predetermined number of impedance values obtained by the calculation unit in time sequence.

[Operation] Since the toroidal coil that detects the current flowing through the tower is wound around the tower between the point where the pulse voltage is applied to the tower and the base that fixes the tower to the ground, the toroidal coil detects and measures the tower. The current flowing through is exactly the same as the current flowing from the tower leg to the ground via the auxiliary ground electrode and is not affected by the current flowing from the application point of the pulse voltage to the upper part of the tower, but based on this measured current and applied voltage. Calculate the impedance.

[Embodiment] FIG. 1 shows the configuration of an embodiment of the present invention. In the figure,
An output line (10) of a pulse generator (9) that generates a pulse voltage of 5 KV, for example, is connected to a tower leg (1) of a transmission line or the like. The other terminal of the pulse generator (9) is grounded. An auxiliary ground electrode (7) for grounding the tower leg (1) is connected to the tower leg (1) in the vicinity of the base (17) for fixing the tower leg (1) to the ground. A toroidal coil (2) is wound around the tower leg (1) between the connection point of the output line (10) for applying the pulse voltage to the tower leg (1) and the connection point of the auxiliary ground electrode (7). ing. The output of the toroidal coil (2) is connected to one input terminals (3) and (4) of a surge impedance measuring instrument (20) for measuring surge impedance, respectively. The other input terminal (5) of the surge / impedance meter (20)
Is connected to the tower pier by a lead wire (5 ').

FIG. 2 shows the structure of the toroidal coil (2). The toroidal coil (2) is formed by winding a coiled electric wire into a circular shape, and a series connection body including a resistor (11) and a capacitor (12) is connected between both terminals of the electric wire. The resistor (11) and the capacitor (12) form an integrating circuit, and lower the detection voltage of high peak level. As a result, the lead wire of the toroidal coil can have a relatively low breakdown voltage. The output of the toroidal coil (2) is output from both ends of the capacitor (12) and is connected to the input terminals (3) and (4) of the surge impedance measuring instrument (20).

Next, the operation of the present invention will be described.

The pulse generator (9) generates a pulse voltage of, for example, 5 KV, and the pulse voltage is applied to the tower (1) via the output line (10). As a result, the pulse current is indicated by the arrow (A) in FIG.
Flow in the direction indicated by. This pulse current is detected by the toroidal coil (2) and input to the input terminals (3) and (4) of the surge impedance measuring instrument (20). On the other hand, the voltage generated in the tower leg (1) is input to the input terminal (5) of the surge impedance measuring instrument (20) via the lead wire (5 '). Fig. 3 shows a surge impedance meter (20)
The block diagram of is shown. In the figure terminals (3)
The output of the toroidal coil (2) input to (4) and (4) is divided by the voltage divider (22), amplified by the amplifier (23), converted into a digital signal by the AD converter (24), and stored in the memory (25). Memorized in. On the other hand, the voltage of the tower (1) input to the input terminal (5) of the surge / impedance measuring instrument (20) is divided by the voltage divider (28) and the amplifier (2
The signal is amplified by 9), converted into a digital signal by the AD converter (30), and stored in the memory (31). A-
The D converters (24) and (30) are clock generators (3) provided via a control circuit (34).
It operates by the clock signal of 3). The amplifier (2
The outputs of 3) and (29) are both sampled at a cycle of 0.02 microseconds or 0.04 microseconds and are controlled by the output of the auto-trigger circuit (35) which is triggered by the output of the amplifier (29) to control the control circuit (34). A / D conversion is performed and stored in memories (25) and (31) each having a capacity of 256 bits, for example.
That is, when the analog outputs of the amplifiers (23) and (29) are sampled at 0.02 microseconds, for example, changes in current and voltage between 5.12 microseconds (0.02 × 256 = 5.12) occur in the respective memory (25). And (3
It is stored in 1). After the application of pulse voltage is completed,
The data once stored in the memories (25) and (31) is converted into an analog signal again by the DA converter (26) and input to the divider (42). The divider (42) divides the data in the memory (31) by the data in the memory (25) and outputs the result to the recorder (39) via the recorder control (38). The recorder (39) is, for example, a pen recorder that writes on a roll paper with a pen, and records the impedance value obtained by the divider (42). The recorder (39) can also record the current and voltage output from the DA converter (26).

An example of the waveform of the ground surge impedance recorded by the recorder (39) is shown in FIGS. 4 (a), 4 (b) and 4 (c). In each figure, the horizontal axis represents time and the vertical axis represents impedance. The waveform in FIG. 4 (a) represents the current flowing through the tower (1) by the application of the pulse voltage, and the waveform in FIG. 4 (b) represents the voltage generated in the tower (1). The waveform shown in FIG. 4 (c) is the result of dividing the voltage shown in the waveform of FIG. 4 (b) by the current shown in the waveform of FIG. 4 (a) by the divider (42). Yes Represents impedance. In the waveform of FIG. 4 (c), for example, the peaks (40) and (41) have a particularly high impedance and show maximum values. The corresponding times (T1) and (T2) on the horizontal axis indicate the passage of time from the time (T0) when the pulse voltage was applied. For the peak (40), for example, from the tower leg (1) to the auxiliary ground electrode (7)
This means that the pulse current flowing in was blocked at the position reached at time (T1), and the ground surge impedance increased accordingly. From this result, it is predicted that the auxiliary ground electrode (7) is broken at that position. Regarding the peak (41), the auxiliary ground electrode (7) is generally buried in the ground for a length of several tens of meters, and the impedance in the ground becomes high at the position where the pulse current reaches at the time (T2). It indicates that The speed of the electric signal flowing through the auxiliary grounding electrode (7) buried in the ground is about 250 m / 1 microsecond as known data in the field of power transmission and distribution. Therefore, since the pulse current advances by about 5 m during the predetermined sampling period 0.02 microseconds of this embodiment, the number of
The state of the auxiliary ground electrode (7) of 10 meters can be detected about every 5 meters. That is, by knowing the times (T1) and (T2) from the display of the recorder (39), the location where the auxiliary ground electrode (7) has a failure can be determined with an accuracy of about 5 m.

[Effects of the Invention] The ground surge impedance measuring device of the present invention detects the current flowing through the tower pier by the toroidal coil wound between the tower pier and the base for fixing the tower pier to the ground. Since it measures, only the current flowing through the tower is detected. As a result, the impedance value obtained by dividing the voltage measured by the voltage measuring means by the current detected by the toroidal coil accurately indicates the impedance of the auxiliary ground electrode of the tower. Also, a few 10m
The voltage and current are sampled at a predetermined period (for example, 0.02 microseconds) that is sufficiently short for the speed at which an electrical signal is transmitted through the auxiliary grounding electrode buried in the ground over the length of (5m / 0.02 microseconds). Therefore, the value of the impedance can be continuously known. Therefore, by analyzing the value of the continuous impedance, it is possible to detect a change in the ground resistance of the auxiliary ground electrode or a disconnection of the auxiliary ground electrode. Further, since the calculation for dividing the voltage by the current is automatically performed by the calculation means, the surge impedance can be promptly and continuously obtained.

[Brief description of drawings]

FIG. 1 is a block diagram showing the configuration of a ground surge impedance measuring device of the present invention, FIG. 2 is a circuit diagram showing the configuration of a toroidal coil used in the present invention, and FIG. 3 is a surge of the embodiment of the present invention. Block diagrams of impedance meters, Figures 4 (a), 4 (b) and 4
FIG. 5 (c) is a diagram showing the current, voltage, and ground surge impedance obtained by the ground surge impedance measuring device of the present invention, and FIG. 5 is a block diagram showing the structure of the conventional ground surge impedance measuring device. It is a figure. 1: Tower leg 2: Toroidal coil 7: Auxiliary ground electrode 9: Pulse generator 20: Surge / impedance meter 25: Memory 31: Memory 39: Recorder 42: Divider

Claims (1)

[Claims] 1. A pulse generator for applying a pulse voltage to a tower leg having an auxiliary ground electrode of a steel tower of a transmission line or the like at a position above a connection point of the auxiliary ground electrode, and an application point of the pulse voltage of the tower base. A toroidal coil wound around the tower leg between the connection points of the auxiliary ground electrodes, an integrating circuit connected to the output terminal of the toroidal coil and integrating the output of the toroidal coil, and measuring the current flowing through the tower leg by the output of the integrating circuit. Current measuring means, first sampling means for sampling the current value of the output of the current measuring means in a predetermined cycle to obtain a predetermined number of sampled current value data, and first storing the predetermined number of current value data Memory, voltage measuring means for measuring the voltage of the tower, voltage value of the output of the voltage measuring means is sampled at the predetermined cycle, and a predetermined number of times sampled Second sampling means for obtaining the voltage value data of, a second memory for storing the predetermined number of voltage value data, the predetermined number of current value data stored in the first memory and the second memory A grounding surge impedance comprising a calculating means for obtaining the value of the predetermined number of impedances based on the predetermined number of voltage value data, and a recorder for displaying the value of the predetermined number of impedances obtained by the calculating means in time sequence. measuring device.