RU2205513C1 - Method of information transmission - Google Patents

Abstract

FIELD: communication equipment. SUBSTANCE: characteristic feature of invention consists in that signal is transmitted over ferromagnetic communication line. In process of transmission ferromagnetic communication line is subjected to effect of magnetic field. In point of signal reception output inductance which is mutually inductively coupled to input inductance located at transmission side of communication line is subjected to action of magnetic field. EFFECT: potential for information transmission over underground or above-ground pipe-line. 2 cl, 4 dwg

Description

 The invention relates to communication systems, and more specifically to methods of transmitting information through communication lines, which use existing guide lines constructed for other purposes not related to the transmission of information, for example, through a rope of a mine lifting installation, through cables from wells, through lightning cables, through power lines, through the main pipeline of a gas pipeline or oil pipeline. The invention can be used to increase the technical and economic efficiency of a communication system in which the communication line is a gas pipeline or oil pipeline, taking into account all components, affecting the total cost and technical performance of the communication system.

 Known methods of transmitting information in communication systems in which the information received from the source, for example, voice, telemetry, are converted into an electrical signal, this signal is injected into the communication line, which is used as coaxial trunk cables (invention of the USSR class. N 04 V 5/00 438128), power lines inside the mines (US Pat. USSR class. The same 2115239), power and telephone cables laid in the mines (US Pat. USSR class. The same 1548857) with the conversion of the transmission frequency to an intermediate one and its restoration when receiving, transmitting via tightrope shaft hoisting device (US Pat. USSR N 04 B 7/00 661828), on a cable from a well (US Pat. England N 04 B 3/54 2110904) or on lightning cables of power lines (US Pat. USSR cl. the same 488352). Then it is transported via a communication line, a signal is received, it is isolated from interference, amplified, relayed, if necessary, converted into an output signal in a form convenient for the consumer.

 The listed methods are intended for short communication lines, mainly for the transmission of departmental information. Similar methods of transmitting information, mainly departmental, are used in communication systems using trunk transmission lines, in which it is a difficult task to filter out a powerful 50 Hz power signal.

 A known method of transmitting information (Kayatskis A.A. "Fundamentals of Radio Electronics". M., VSh, 1988, p.10, 11), the signs of which are implemented, essentially, in all communication systems and which is an analogue of the proposed technical solution and which consists in that the information coming from the source, as a rule, of non-electric origin, is converted into an input electrical signal, encoded if necessary, converted into a signal suitable for transmission over a given communication line, the converted signal is introduced into the communication line, transported along it, p inimayut signal distinguish it from noise, amplified, decoded if necessary, is converted into an output signal in a convenient form (e.g., in telephone communication systems) and deliver it to the consumer.

 The disadvantage of this method compared to the claimed one is that it is oriented to a radio communication system and provides for the use of only the space between the transmitting and receiving antennas as communication lines, as well as wired (cable), waveguide and fiber-optic communication lines. The construction and operation of long lines is a complex and expensive task.

 Closest to the claimed method of transmitting information on a set of features and obtaining the required technical results is a method of transmitting information in which information from a source is converted into an input variable electrical signal, encoded if necessary, converted into a signal suitable for transmission over a given communication line, the converted signal is introduced into the communication line, which can be used as a pipeline of a gas pipeline or oil pipeline, transport it through a communication line receive the signal coming through the communication line, isolate it from interference, amplify, if necessary, at least part of the signal is relayed, the other part of the signal is decoded if necessary, converted into an alternating output signal designed to present information in a convenient form for the consumer, and delivered to the consumer (V.T. Sergovantsev, V.A. Artemov, K.A. 1, p. 4-7).

 In this method, a pipe-to-ground circuit is used as a communication line (a two-wire line, one wire of which is a gas pipe covered with insulation, and the other is ground), through which an electrical signal is transported.

 The use of a method of transmitting information using gas pipelines as ready-made long-distance communication channels whose network covers all of Russia, including northern and mountainous regions, tundra, swamps, etc. is of great importance. The prototype method is intended mainly for the organization of departmental centralized data transfer, maintenance of controls and control of the linear part of the main gas pipelines.

 The disadvantage of this method is that it can only use an underground pipeline as a communication line, while there are gas lines with a large length of land location (mainly in our northern regions, Alaska, deserts, etc.) for which this method is not applicable. In addition, violation and aging of the insulation gives rise to both current leakage and the effect of stray currents on the signal; The underground pipeline itself is an electrochemical system under the influence of the potential of cathodic protection and the natural potential of the pipe with respect to the ground, which also complicates the transmission of the signal.

 Also, the known method is suitable only for transmitting a low-frequency signal from 3 to 1000 Hz (depending on the insulation condition and soil conductivity for 3 Hz, the signal transmission range without relaying is 10-60 km, for 1000 Hz - 1-5 km), which is significant limits its use.

 The essence of the invention is aimed at increasing the technical and economic efficiency of information transfer when using a gas pipeline (oil pipeline) as a communication line due to the possibility of transmitting a signal through a pipeline of any design - underground, bulk laying or underwater and above-ground location, increasing the transmission distance without intermediate signal amplification, eliminating dependences of transmission quality on the state of isolation, transition to a wider frequency range, expansion of the field ia, expanding the arsenal of technical means of transmitting information.

 A distinctive feature of the claimed invention from the prototype is the transmission of an information signal not via a two-wire (pipe-to-ground), but via a single-wire line (pipe). In the known method this cannot be done, because An electrical signal is transmitted through the communication line. In the inventive method, the signal is converted into a form suitable for input and transmission on such a communication line, namely, an alternating magnetic field suitable for transmitting a signal in the form of an alternating magnetic flux through a single-wire line (pipe) made of ferromagnetic material (pipe steel), which is a magnetic circuit directing magnetic flux along a designated path.

 The claimed method contains all the essential features of the prototype: the information received from the source is converted into an input electrical signal, if necessary, it is encoded, converted into a signal suitable for transmission over a given communication line, the converted signal is input into a communication line, which can be used as a gas pipeline or an oil pipeline, transport it via a communication line, receive a signal received through a communication line, separate it from interference, amplify, if necessary, at least part of the signal p broadcast, another part of the signal is decoded if necessary, is converted into alternating output signal intended to represent information in a form convenient for the consumer, and deliver to the consumer.

 Other significant distinguishing features from the prototype are the following: before entering into a line made in the form of a pipeline, mainly a gas pipeline or oil pipeline, from an ferromagnetic material an alternating electric signal in the form of an alternating electric current is passed through an input inductance and an alternating magnetic field suitable for signal transmission on the specified ferromagnetic communication line, they act on the ferromagnetic communication line, during transportation, the signal is inductively transformed by the ferromagnetic communication line at the place of signal reception is affected by the variable reaching the place of reception by the magnetic field on the output inductance mutually inductively coupled along the ferromagnetic communication line to the input inductance, and the signal is received from the output inductance.

 Also, if necessary, relay at least part of the signal after separation from interference and amplification is converted, introduced into the ferromagnetic communication line, transported and received the signal in accordance with the actions. carried out during the transmission of the signal information, and the signal is relayed the necessary number of times along the length of the pipeline in the same way.

 In addition, the signal is transported from one gas or oil pumping station to another pumping station and relayed to it at the same stations.

 Below the invention is described in more detail, including the example of its implementation with reference to the drawings, schematically illustrating an information transmission system that implements the claimed method.

 Figure 1 shows a diagram of an information transmission system that explains the implementation of the method of information transfer, figure 2, 3, 4 - the results of measuring the transmission of a signal through a magnetic circuit in a model experiment.

 The essence of the method is as follows (figure 1).

 The information coming from the source, for example, speech, is converted into an input alternating electric signal in the input converter 1, it is encoded if necessary (encoder 4), then it is converted into alternating electric current in the converter of the electric signal into electric current 2, the latter is passed through a transmitting device 3 with encoder 4 and transmitter 5. The signal is input into the communication line 7 through an input inductance 6, in which an alternating magnetic field is created, suitable for transmitting a signal through ferromagnetic the communication line is a magnetic circuit in the form of a steel pipe 7. At the place of signal reception, the output inductance 8 is located, which is affected by the magnetic field that has reached the ferromagnetic communication line 7. Both inductors (input and output) are mutually inductively coupled through a ferromagnetic communication line. In the output inductance, an alternating magnetic field creates an alternating electrical signal. Then the information signal is isolated from interference, amplified, if the signal was encoded, then decoded in the receiving device 9 by the receiver 10, amplifier 11, decoder 12.

 And finally, the received, isolated from interference and amplified signal is converted in the output Converter 13 into an alternating output signal. designed to present information in a convenient form for the consumer, and delivered to the consumer.

 If necessary, relay at least part of the signal after isolation from interference and amplification is selected in the form of an alternating electric current through the selection device 14 to the relay 15, then inductance 16 is converted into an alternating magnetic field suitable for transmitting a signal through a ferromagnetic communication line 7, and then a signal is transmitted along it to the next place of reception of the signal. In the same way, the signal is relayed the required number of times along the length of the pipeline.

 The input of the information signal into the communication line and the output from it, as well as the relay, is preferably carried out at the gas or oil pumping station, where there is electricity and personnel.

 The equivalent magnetoelectric circuit of a transmission system that implements the claimed method is reduced to a four-terminal device - a transformer - a common element of electronic circuits (Kayatskis A.A., cit., Chap. 7).

The basic principles of the method are tested on an experimental model. At the ends of a steel pipe 2.5 m long, 60 mm in diameter, ≈4 mm thick, identical inductors of 14 turns of copper wire with a diameter of 2 mm were installed. An electric current of 50 MHz with a power of 10 ^-5 W was supplied to the input coil from the output of the HEWLETT / PACKARD spectrum analyzer generator E4405 V. Current from the output coil was fed to the input of the same analyzer.

 Figure 2 shows the power supplied to the input inductance. In FIG. 3 - measured power at the output inductance, the distance between the coils 120 cm, figure 4 is the same, the distance between the coils 250 cm

The transmitted power decreases with distance approximately proportional to L ^-2 , where L is the length of the transmission line.

 The calculation of the technical and economic efficiency of the communication system that implements the inventive method gives the following.

 Using this method of existing communication lines — gas pipelines or oil pipelines — provides significant cost savings when creating communication systems, since there is no need to build communication lines.

 For example, now laying 1 km of fiber-optic (fiber-optic) cable costs $ 5,000, excluding related equipment.

 Radio relay communication with a range of 40 km costs $ 20,000, the cost of building a mast costs $ 1,000 per 1 m of height, on average, masts of 30-40 m in height are used. The cost of radio relay communication per 100 km will be approximately $ 80,000. The cost of operating communication lines is 5-10% per year of the cost of construction. Compared with the prototype, the claimed method is suitable for transmitting information not only through underground pipelines, but also for an overhead, underwater and bulk installation pipeline. The state of pipeline insulation does not affect the transmission of information; the range of transmission frequencies is expanding.

 An example implementation of the inventive method is illustrated by the transmission system shown in figure 1. Transceiver and relay kits are installed at gas or oil pumping stations, the distance between which is 100-130 km. At the pumping station there are all the possibilities for inexpensive and reliable operation of the transceiver station.

Estimates show that according to the claimed method, the transmission of an information signal without intermediate amplification is possible for 100-150 km. Note that modern means of reception allow you to select signals with a power of 10 ^-12 watts.

 Thus, the distinctive features of the claimed method provide the emergence of new properties that are not achieved in the prototype and analogues, and also expand the capabilities and arsenal of technical means of communication.

Claims (3)

 1. A method of transmitting information in which the information received from the source is converted into an input variable signal, encoded, converted into a signal suitable for transmission over a given communication line, the converted signal is introduced into the communication line, which can be used as a gas pipeline or oil pipelines, transmit a signal through a communication line, receive a signal arriving on a communication line, separate it from interference, amplify and, if necessary, decode and convert it into an output signal intended for presenting the information in a form convenient for the consumer, and deliver to the consumer, characterized in that when the signal is introduced into the communication line, an alternating magnetic field is created that acts on the communication line, made in the form of a ferromagnetic pipeline, by passing the signal through the input inductance and receiving the signal by outputting it at the receiving location by the output inductance mutually inductively coupled to the input inductance.  2. The method according to p. 1, characterized in that, if necessary, relay at least. parts of its signal after separation from interference and amplification are converted, injected into the ferromagnetic communication line the required number of times along the length of the pipeline.  3. The method according to p. 1 or 2, characterized in that the signal is transmitted from one pumping station of gas or oil to another pumping station and relaying it at the same stations.

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