RU2479084C1 - Method to detect ice formations on wires and thunderstorm ropes of power transmission lines - Google Patents

Abstract

FIELD: electricity.

SUBSTANCE: according to the method, radio pulses are sent from the start of the line to the end of the power transmission line, such pulses have a bell-shaped form of an envelope, the reference parameters include time of propagation and attenuation of radio pulses as they propagate from the start of the limited section of the wire to its end, the average value of temperature is determined for this section of the wire, and glaze ice appearance is determined by changes in time of propagation and attenuation of radio pulses caused by appearance of glaze ice, with account of influence at controlled parameters of temperature variation of the wire section length, at the same time radio pulses are sent into the line, which have different frequencies of filling, attenuation of received radio pulses amplitude is measured in series from the value of time delay, the central maximum peak of resulting dependence is found, which makes it possible to accurately determine the time of propagation of a narrow-band radio pulse along a line.

EFFECT: reliability improvement.

2 dwg

Description

The invention relates to electrical engineering and can be used to detect icy formations on wires and lightning protection cables of power lines (power lines) and determine the length and thickness of ice deposits.

A known method of controlling the level of ice load on the wires of power lines, implemented, for example, in devices [Copyright certificate No. 603034, H02G 7/16, publ. 04/15/78, BI No. 14; Copyright certificate No. 508843, H02G 7/16, publ. 03.30.76, BI No. 12]. The known method involves the radiation at a given frequency into the power line through the high-frequency connection of the probe pulses, the reception of probe pulses and fixation of ice formations in a controlled area by an additional reflected pulse corresponding to the ice formation site.

The disadvantage of this method is the inability to determine the wall thickness of ice on a power line.

A known method for detecting ice formations, implemented in a device for signaling ice formations on the wires of power lines [Author's certificate No. 748615, H02G 7/16, publ. July 15, 1980, BI No. 26]. The method involves the emission of signals at two frequencies, and its disadvantage is the complex technical implementation associated with the placement of equipment at different ends of the power lines.

The closest technical solution to the present invention is a method for detecting icy formations on wires and lightning protection cables of power lines, including radiation and reception of two-frequency probe pulses through a high-frequency connection of a power line, coordinated filtering of the received two-frequency pulses and a comparison of the levels of the latter, which decide on the presence of ice formations on the power line.

The prototype method is implemented by a device for detecting icy formations on wires and lightning protection cables of power lines [Patent No. 2227953, H02G 7/16, BI No. 12, publ. 04/27/2004]. The device includes an attachment device connected to the linear path, a transmit-receive switch, a power amplifier, input filters, a probe pulse shaper, amplifiers, matched filters, amplitude detectors, peak detectors, an input-output device, a personal computer, and a bi-directional data exchange line .

The device operates as follows. A personal computer through an input-output device with outputs for controlling the frequency of filling and duration programmatically controls the formation of probe pulses with a duration of T3 and frequency of filling f1 and f2, which pass one into another without phase discontinuity. The probe pulses are amplified by the power amplifier to the required power level and through the connection device enter the linear path. In this case, the transmit-receive switch disconnects the receiving path of the device, protecting it from direct exposure to radio pulses. The probe radio pulse emitted into the linear path, propagating in it, passes through all its heterogeneities sequentially, is reflected from their boundaries and the end of the linear path.

In this case, the probe radio pulse undergoes a natural attenuation in the linear path and an increase in the attenuation of the filling frequencies f1 and f2 in time due to the growth of ice formations and other factors. To analyze the nature of the phenomenon that caused a different increase in the attenuation of the filling frequencies f1 and f2, a radio pulse is received reflected from the end of the linear path. From the mixture of signal and noise, envelopes of the radio pulses of the corresponding filling frequencies are extracted, then the amplitude values and the values of the decrease in the levels of the amplitude values Δαf1 and Δαf2 corresponding to the increase in attenuation of the frequencies f1 and f2 are measured with a sufficient degree of accuracy. When the ratio Δαf1 / Δαf2 reaches a predetermined value of g, which is constant for the selected filling frequencies f1 and f2 and takes place only with an increase in the attenuation of the linear path during icing, the device, in accordance with the program, begins to measure the decrease in the level of amplitude values of only the frequency f2 (Δαf2) , which is proportional to the wall thickness of the ice formations (with the known length of the ice formations).

The disadvantages of the known prototype method and the device that implements it are low speed and complexity, which consists in a phased implementation, not universality (it is required to specify the portion of the transmission line prone to ice formation).

To overcome these drawbacks, a new method is proposed for detecting icy formations on wires and lightning protection cables of power lines, including transmission from the beginning of the line to the end of the power line of radio pulses having a bell-shaped envelope shape, leading to a minimum spectral width of each radio pulse, and control of parameters associated with changing conditions propagation of radio pulses along a section of wire when ice appears, take control time as control parameters variations and attenuation of radio pulses during their propagation from the beginning of a limited section of wire to its end, determine the average value of the temperature of this section of wire, and the appearance of ice is judged by the changes in the propagation time and attenuation of radio pulses caused by the appearance of ice, taking into account the influence of temperature changes in length on controlled parameters a wire section, characterized in that the radio pulses having different filling frequencies are transmitted to the line, the attenuation of the amplitudes of the received adioimpulsov the magnitude of the delay time, finding the central maximum peak of the resultant function which enables to accurately determine the propagation time of narrowband radio pulse on line.

The prerequisites for the implementation of the proposed and more advanced method, which allows to determine the length and thickness of ice on the analyzed section of power lines, are connected by theoretical provisions [for example, Ishkin V.Kh., Tsver II High-frequency communication on power lines 330-750 kV. - M .: Energoizdat, 1981], characterizing the influence on the high-frequency parameters of power lines of ice-frost-frost deposits and sediments.

Let us consider such an effect on the high-frequency parameters of the inner cable paths of power lines, as the ones most exposed to icy-frost-frost relations [Ishkin V.Kh., Tsver II High-frequency communication on power lines 330-750 kV. - M .: Energoizdat, 1981, S.80-87].

In particular, the additional attenuation of the intrathoracic tract, due to the influence of ice-frost-frost deposits, significantly depends on the frequency of the signal propagating through the analyzed section of the power transmission line, as well as on the ambient temperature, including the defining varieties of ice-frost-frost deposits (crystalline frost; granular frost; ice). The dependence of the additional attenuation on the frequency and temperature is clearly nonlinear and can be characterized by graphs [Ishkin V.Kh., Tsitver II. High-frequency communication on power lines 330-750 kV. - M .: Energoizdat, 1981, fig. 3.16; 3.17]. As a result, having additional attenuation of radio pulses measured at different frequencies, it is possible to estimate the thickness of ice deposits.

The second prerequisite for the proposed method is the different dependence of the additional attenuation and delay of the radio pulse on the length of the ice deposits [Khakimzyanov EF, Minullin RG, Mustafin RG A mathematical model of the delay and attenuation of high-frequency signals in power lines with icy formations. / Energy of Tatarstan. 2011, No. 2], which leads to the possibility of two measured parameters (additional attenuation and delay of the radio pulse) to calculate the length and thickness of ice deposits. Each location measurement gives two measured values: the delay dτ (measurement) and the attenuation of the amplitude K (measurement) of the high-frequency signal. It is possible to theoretically calculate the delay dτ (d, L) and attenuation of the amplitude K (d, L) of the high-frequency signal, which depend on the thickness d and the length L of ice deposits. The joint solution iteratively (by the method of successive approximations) of two equations:

allows you to uniquely determine the thickness d and the length L of ice deposits, for which both equations (1) and (2) are performed simultaneously.

In other words, using two measured values (dτ (measurement) and K (measurement)) - we can calculate two output parameters (thickness d and length L of ice deposits).

The use of radio frequency pulses with a bell-shaped envelope shape leads to a narrow spectrum of radio pulses. It is practically possible to increase the duration of the radio pulse τ to the transit time of the radio pulse from the beginning of the power line to its end and vice versa: τ≤2 · L / C, where L is the length of the power line, C is the propagation speed of the radio pulse along the power line (approximately equal to the speed of light 3 · 10 ⁸ m / s). Under this condition, the reception of reflected signals will occur after the end of the transmission of the radio pulse. Consider, for example, a power line with a length of L = 30 km. In this case, the maximum possible length of the radio pulse will be equal to τ = 0.2 milliseconds. Accordingly, the width of the spectrum of the radio pulse ΔF≈2 / τ = 10 kHz. As a result, it becomes possible to use the proposed method in conjunction with high-frequency communications equipment on power lines (operating at different frequencies).

The measurement of the propagation time of a narrowband radio pulse by a power line has a feature associated with obtaining the necessary accuracy of measuring the propagation time. At the same time, measurements at several different frequencies make it possible to increase the accuracy of measuring the propagation time of a narrow-band radio pulse along power lines. The radio frequency pulse U (t) has a periodic sinusoidal filling: U (t) = V (t) · sin (2π · F · t), where V (t) is the bell-shaped envelope of the radio pulse, F is the frequency of filling of the radio pulse, t is time. To determine the propagation time of the radio pulse from the transmitter to the end of the line, and vice versa, a search is made for the correlator maximum K of the received pulse W (t) and transmitter pulse U (t + τ), with a change in the delay time τ.

In Fig. 1, a correlator K (vertical axis) is plotted against the time delay τ (horizontal axis). It can be seen that the correlator K is also a periodic function of τ, and the peaks 1, 2, 3 of the correlator K have close amplitudes, and it is problematic to determine a maximum of 2 correlators K (relative to the side peaks 1, 3). To solve this problem, we will successively measure two correlators K1 and K2, for two radio-frequency pulses U1 (F1) and U2 (F2) having different filling frequencies F1 and F2. In this case, the correlators K1 and K2 have a coincident (in the τ parameter) central peak, and the side peaks do not coincide (due to different frequencies F1 and F2 of radio pulses). Therefore, after multiplying the two correlators K1 · K2, peaks 4, 5, 6 of the product of the correlators (Fig. 2), the central (maximum) peak 5 will retain its amplitude, and the side peaks 4 and 6 will decrease in amplitude (since the side peaks are slightly offset from each other) . This allows you to uniquely determine the maximum 5 correlator and accurately determine the propagation time of a narrow-band radio pulse on the power lines.

The practical value of the proposed method is related to the fact that in order to assess the threat of damage to the power line under the influence of ice deposits, it is fundamentally important to determine the weight of ice deposits per span (the weight of ice deposits on a wire suspended between two supports). The proposed method allows to determine the thickness d and the length L of ice deposits, from which we can calculate the mass M of ice deposits per span

M = ρ · (d2-R2) · L (span),

where ρ is the density of ice deposits, R is the radius of the wire of the power line, L (span) is the distance between the two supports.

Knowing the mass M of ice deposits per span allows you to accurately assess the degree of threat of damage to the power line.

Summing up, it can be argued that this method of determining the parameters of ice deposits on the wires of the power line allows you to really assess the degree of threat of destruction of the power line when ice appears. The above estimates show the undeniable, obvious advantages of the proposed method over the prototype.

Improving the accuracy, speed, simplifying the method for determining the formation of ice on the wires of the power line and its versatility (there is no need for a preliminary determination of the area prone to icing) will allow timely preventive heating of the wires, which will reduce the likelihood of accidents.

Claims (1)

A method for detecting icy formations on wires and lightning protection cables of power lines, comprising transmitting from the beginning of the line to the end of the power line of radio pulses having a bell-shaped envelope shape leading to the minimum spectral width of each radio pulse, and monitoring parameters associated with changing conditions of propagation of radio pulses along a wire section at the appearance of ice, as control parameters take the propagation time and attenuation of the radio pulses when they propagate about t of the beginning of the limited section of the wire to its end, determine the average temperature of this section of the wire, and the appearance of ice is judged by the changes in the propagation time and attenuation of radio pulses caused by the appearance of ice, taking into account the influence on the controlled parameters of the temperature change in the length of the wire, radio pulses having different filling frequencies are transmitted to the line, the attenuation of the amplitude of the received radio pulses from the delay in time is successively measured, and trawling the resulting maximum peak depending on which allows you to accurately determine the time of narrowband radio pulse propagation along the line.