SE453704B - THREE-PHASE TRANSMISSION AIR CONDITION WITH DISTRIBUTED PHASES - Google Patents

Description

1 453 704 to provide alternating current transmission lines with increased phase splitting radius for line conductors ", the magazine" Elektresheskie stanzii "," Energija ", Moscow, No. 8, 1979, pp. 48-55). This known electric power transmission line comprises conductors which are attached to spacers, which are arranged to form in a plane perpendicular to the center line of the electric power transmission line cross-sectional contours for the split phases, support brackets and insulators intended to attach the phases to the support brackets. In this known electric power transmission line, the contours of the split phases have the shape of laterally spaced circumferences of the same diameter, and between them the legs of the support brackets are arranged. In each phase of this known electric power transmission line the number of conductors, as in the case of the other known conventional electric power transmission lines with split phases, is equal, the conductors in each phase being separated from each other at equal distances, which in other words means that a sk phase splitting steps are constant in each phase and the same size for all phases. However, the number of conductors in each phase of the power transmission line described above has increased compared to the number of conductors in the phases of the other known conventional power transmission lines to nine conductors instead of the usual four to five conductors, for the single power transmission line. of 750 kV and to twelve-thirteen conductors instead of the usual eight conductors for the electric power transmission line for a voltage of 1150 kV. In accordance with the increase in the number of conductors in the phases, the radii r of the circular paths along which the conductors in each phase are distributed were also increased, in order to maintain the conventional splitting step (splitting division) between the conductors. A distance S between the phases in the above-described known electric power transmission line is equal to that of the known conventional electric power transmission lines, i.e. 17-20 m for the electric power transmission line with a voltage of 750 kV and 23-25 m for the electric power transmission lines with a voltage of 1150 kV. The increase of the radii of the circular paths along which the conductors in each phase are m, 455 704 are arranged, i.e. the increase in the phase splitting radii has made it possible to reduce the wave impedance to 150 ohms and thereby increase the natural power of the electric power transmission line with a voltage of 750 kV from 2 mill. kW to 3.5 mill. kW respectively of the electric power transmission lines with a voltage of 1150 kV from 5 mill. to 9 mill. kW, i.e. by 70-80%.

In the case of the known electric power transmission line described above, the distance between the conductors in all the adjacent phases is different, whereby it varies between S and S + 4 rp. This circumstance, as well as the large distance between the phases and the occurrence of earthed support trusses between them, results in the electric field appearing in all the spaces between the phases not becoming uniform.

In such an electric field, an electric surge occurs between the phases, when the occurring overvoltages exceed the permissible ones, in the so-called the conductor shape, which is characterized by the formation of an air duct in the space between the phases, over which electrical discharge takes place. In order to be able to ensure the necessary impact strength under these conditions, the phases must be separated from each other by a relatively large distance. All factors lead to a significant increase in the dimensions of the support trestle and consequently to the manufacturing cost of the support trestle and to an increase in the width of the transmission line path, which is not economically advantageous, given that the increase in natural effect is relatively small.

Another way to increase the transmission power of an electric power transmission line is to increase the number of phases. A six-phase transmission line for a voltage of 462 kV is known, for example (compare, for example, "Electra", no. 61, 1978 (Paris): LO Barthold "Round table on transmission of electricity in the beginning of the 21st century, p 32-35). Each phase of this known electric power transmission line is split into four conductors, which are uniformly arranged on spacers of metal around the center of the phase. The phases in this power transmission line are moreover arranged around a common center, while elements belonging to support trusses are arranged outside a space which is occupied by the phases and air gaps therebetween. The distance between the center lines of the adjacent phases is 4.9 m, while the distance between the nearest conductors in the adjacent phases is 4.4 m. The field strength of an electric field, which occurs in the distance between the phases of this known electric power transmission line, is equal to 1.5 kV / cm, when the operating voltage has an amplitude value.

The conductors in all the adjacent phases of this known electric power transmission line are, as with the known electric power transmission line described above, different distances from each other, so that the electric field operating between the phases is also non-uniform.

The support trestles of this known electric power transmission line have relatively small dimensions, while its natural effect is high and amounts to 6 mill. kW. However, the six-phase power transmission line requires the use of transformers with switching circuits useful in rectifier technology, which makes such an electric power transmission line more complicated and more expensive. Another way of increasing the transmission capacity of an AC transmission line with split phases is known (compare, for example, U.S. Pat. No. 3,249,773), which is based on the formation of a slightly non-uniform electric field in gaps between the phases. This known patent describes two electric power transmission lines. One consists of a single-phase transmission overhead line consisting of a single circuit with split phases, which comprises two rows of conductors, which are attached to the spacers of metal, and U-shaped intermediate support brackets. and on the other hand insulators, the insulators which are intended to attach the lower row of conductors to the support bracket being constituted by suspended chains of insulators, while the insulators which are intended to attach the upper row of conductors are constituted by rod insulators. In this known electric power transmission line, the rows of conductors are arranged symmetrically with respect to the horizontal cross beam of the support bracket, so that the support bracket is located in the space occupied by the air gap between the phases. The number of conductors in each row is equal, the conductors being separated from each other by equal distances.

The arrangement of an element belonging to the support bracket in the space between the phases of this known single-phase transmission line leads - as in the case of the other known electric power transmission lines with similarly arranged support brackets - to a lower so-called degree of uniformity of the electric field between the phases and to the need to increase the distance between the phases. All the circumstances limit the transmission capacity of such an electric power transmission line, which is already low by itself, since this transmission line is of a single-phase type. Because the known electric power transmission line described above is provided with closing insulators, which have relatively low strength when longitudinal stresses occur in the conductors, it is also necessary to reduce the span and consequently increase the number of support trusses, thereby increasing the manufacturing cost of the electric power transmission line.

The three-phase transmission transmission line with split phases known from the said U.S. patent is almost similar to the split-phase power transmission line proposed according to the present invention. This known electric power transmission line comprises on the one hand conductors which are attached to spacers of metal, which are arranged to form in a plane which is perpendicular to the center line of the electric power transmission line, cross-sectional contours for the split phases, and support brackets, whose elements are arranged outside the space occupied by the phases and the air gaps between them, and insulators which are intended to attach the phases of the electric power transmission line to the support trestles of this line, an electric field appearing in the greater part of the spaces between the phases being weak. olíkfor- migt. The contour of the phases of this known transmission line is V-shaped, the apex angle being equal to 1200, which makes it possible to group the phases around a common center so that in each phase one straight half of the V-shaped 453 704 contour for this phase is arranged parallel to one straight half of the V-shaped contour of the second phase, while the other straight half of the V-shaped contour of the first phase is arranged parallel to the one straight half of the V-shaped contour of the third phase. In all phases the conductors are separated from each other by equal distances, one of the conductors in each phase being arranged at the tip of the V-shaped contour of the phase. In order to reduce capacitive connection to earth under these conditions, all phases of the above-described known electric power transmission line are arranged above the support stand and fastened to it by means of rod insulators.

In such a three-phase transmission line, the split phases are separated from each other by a shorter distance compared with the other known electric power transmission lines of this kind. However, because all three split phases converge adjacent to the common center and the distance between the conductors in each phase is equal, the electric field in the area of the common center is not slightly uniform, with overlaps occurring therein when overvoltages are generated. over the electric power transmission line, which is why it is necessary to limit the transmission power of such an electric power transmission line. The use of pole insulators also makes it necessary, as stated above, to reduce the span and increase the number of intermediate support beams, which increases the manufacturing cost of the electric power transmission line and makes it unsuitable for the electric power transmission lines for very high voltages and high power, which include a large number of heavy conductors in each phase. The object of the present invention is to provide a single-circuit three-phase transmission air line with split phases for high, very high and extremely high voltage, in which transmission line the split phases have such cross-sectional contours and are arranged relative to each other and the conductors are distributed in the split the phases in such a way that the electric field becomes as uniform as possible and the energy concentration in the gaps between the phases becomes as high as possible, which contributes to increasing the transmission capacity and improving the economy of electric power transmission over this electric power transmission line.

This is achieved according to the present invention by means of a single-phase three-phase transmission overhead line with split phases, which comprises conductors which are attached to metal spacers which are arranged to form, in a plane perpendicular to the center line of the electric transmission line, cross-sectional contours for the split phases, on the one hand support brackets, the elements of which are arranged outside the space occupied by the phases and air gaps therebetween, and on the other hand insulators, which are intended to attach the phases of the power transmission line to its support brackets, while an electric field, which occurs in the greater part of the spaces between the phases of the electric power transmission line, is slightly uneven, the distances between the adjacent split phases suspended at the support trusses, according to the invention, being, seen in cross section through the electric power transmission line, over at least the greater part of the length of said phases is equal, while the conductors in at least one split phase of the electric power transmission line is separated by different distances in such a way that the electric charges of the conductors are equal to each other, while the electric, generated by the mentioned position of the phases and conductors, the field is slightly uniform in the whole volume of the gaps (spaces) between the phases, in which field electrical flux over the gaps between the phases can only occur in so-called streamer form, when overvoltages are generated across the electric power transmission line, which are higher than the permitted ones. As is well known, flash streamer form consists of a successive series of reproducible electron avalanches in the space between the phases, which electron avalanches are displaced relative to each other in time and in space. In such a form of flashover, something similar to a waveform is generated, in which an area with the highest possible ionization intensity moves at a speed of 108 cm / s by the dominant influence of the photoionization process. The average discharge strength of the electric field is higher in the case of a streamer of an estimate of 453,704 than in the so-called the leader form (conductor form) of discharge and constitutes 4-5 kV / cm. The streamer shape of flashover thus constitutes a quantitative measure that characterizes the degree of uniformity of the electric field. . In that electric flashover in the entire volume of the spaces between the phases can only occur in streamer form, the present invention contributes to optimally increasing the degree of uniformity of the electric field, whereby the transmission capacity of electric power transmission lines for high, very high and extremely high voltage can be significantly increased.

However, it is suitable that the distance between the adjacent phases is chosen so that the electric field strength in the gaps between the phases at the operating voltage is between 1.65 kV / cm at a maximum so-called overvoltage ratio and 3.15 kV / cm at a minimum overvoltage ratio for the electric power transmission line.

In the case of the electric power transmission line according to the present invention, all the contours along which the conductors belonging to the split phases are arranged in the cross section of the transmission line can be closed. Such an embodiment of the electric power transmission line may comprise the maximum number of conductors to which the phases are split, so that it is suitably used with electric power transmission lines over which the highest possible natural power must be transmitted. In this embodiment, the number of conductors in the lower half of the contour for at least one outer split phase must be greater than that in the upper half of the contour for this phase. If it is taken into account that the lower part of the contour of the outer split phase is close to earth and has increased capacitance, such a distribution of the conductors is more preferred for equalizing charges and currents in the conductors, increasing the uniformity of the electric field and reduction of losses in the leaders.

It is suitable that the closed contours of the split phases are in the form of concentric circular paths (perimeters).

In the power transmission line according to the invention, the conductors in one of the split phases can be divided into two equal 453 704 large phases, the contour of each half phase, seen in the cross section of the power transmission line, being in the form of a circumference located within the circumference one of the other two split phases is arranged. Such a design makes it possible to reduce the height of the support trusses with an insignificant reduction (by almost 10%) of the natural effect compared with the embodiment of the electric power transmission line, in which all split phases are represented by a closed contour, for example a circumference, and arranged around or inside each other.

In the main embodiment of the electric power transmission line according to the invention, one of the contours along which the splitters of the split phases are arranged in the cross section of the electric power transmission line may be closed, while the other contours may be open and may surround the first contour. This makes it possible to provide a desired ratio between the contour length and the distance between the split phases at lower natural power compared to the embodiment of the transmission line according to the invention, in which all those contours are closed. In said embodiment, it is suitable that the distance between the conductors in the middle portion of the contour for at least one open outer phase is smaller than those in the outer portions of the contour for this phase. This makes it possible, as already stated above for the first embodiment (the main embodiment), to very easily equalize charges and currents in the conductors, reduce the losses in these and increase the degree of uniformity of the electric field (ie make the field more uniform).

Another possible embodiment, in which one of the split phases is formed with a closed contour and the other split phases are formed with an open contour, is one in which the contour of the upper split phase has the shape of an oval, while the contours of the lower split phases are in the form of curves, the convex part of which is turned downwards, which makes it possible to hang the split phases very easily at the support trusses.

In the contour of all the split phases, the embodiment can preferably be used with electric power transmission lines with relatively lower natural power compared to the other two (apart from the first embodiment) embodiments of the electric power transmission line according to the invention. In this embodiment, it is preferable that the conductors in the middle portions of the contour for the split phases - in order to partly prevent local corona discharge from occurring at the edges (ends) of the open contours of the phases and at the same time ensure the same charge and the same current in the conductors - are spaced apart by a greater distance than the conductors located adjacent to the outer portions of the contours.

The open contours of the split phases can take the form of curves, the convex parts of which are turned downwards in order to simplify the suspension of the split phases at the support blocks.

In order to minimize the electric field strength emanating from the power transmission line and reduce the width of the transmission line path, the contours of all the split phases can be placed substantially vertically, the ends of the outer split phases having to be folded in outer (relative to the split or center phase). directions, while at the ends of the split central phase one must place the conductors arranged in lines which, seen in the cross section of the power transmission line, are perpendicular to the main part of this split phase.

The open contours for split phases can mainly have the shape of straight (straight) lines, whereby the contours for all split phases, which have the shape of straight lines, can be located horizontally or vertically. Such an embodiment of the electric power transmission line according to the invention is suitably used when the transmission line is dimensioned for relatively lower voltage and free from local corona discharge along the edges of the phases.

In order to equalize the capacitances of all the three phases and to ensure an equal voltage drop across these phases, it is suitable that the contour of the split middle phase in the embodiments of the transmission line according to the invention, in which the contours of the split phases are mainly in the form of straight lines, have a shorter length compared to the contours of the outer split phases.

It is furthermore suitable that if the open contours of the split phases are located vertically, the lower ends of these contours are attached by means of insulators to the further lower cross-beam with which the support bracket is provided. This makes it possible to attach the split phases better, prevent them from swinging and thereby reduce the width of the intermediate support trestles.

In the embodiment of the electric power transmission line according to the invention, in which the contours of the split phases are in the form of concentric perimeters, the intermediate support brackets can be formed with a V-shaped leg, which is hingedly connected to a base part, which is built up of three inclined legs. , which, in plan view, diverge from a common center at an angle of 1200 and whose lower ends are supported by foundation plates. The upper ends of the V-shaped legs of the intermediate support bracket so formed are connected to each other by means of a flexible connecting link and to the lower ends of the inclined legs of the base part, which are connected to each other by means of a second common flexible connecting link, which is so that it can be tensioned from a single point. The support bracket so designed is very light and at least metal-demanding compared with the other support brackets, whereby it can be used in that the contours for split phases are designed and arranged according to the basic principle of the invention.

In order to be able to comfortably guide the conductors from one split phase in those embodiments of the invention, in which the contours of the split phases are mutually surrounding or surrounded, it is suitable that each end, anchoring and corner support bracket comprises at least one three-legged portal with crossbeams, struts and rigid connecting links, while the conductors in each split phase by insulators are alternately attached to the struts and crossbeams of each part, starting from the phase conductors located along the curve with larger diameter.

The invention is described in more detail below with reference to the accompanying drawings, in which Fig. 1 for comparison shows the relationship between the natural effect Pn of three-phase transmission overhead lines with split phases and the number n of conductors in the split phase, Fig. 2 ad shows different embodiments and different mutual positions of the split phases (a, b and c) of single-circuit three-phase transmission overhead lines with split phases and diagrams corresponding to said embodiments and positions (d) of the natural effect Pn attributed to the width B of the transmission line path, Fig. 3 shows connection between 50% discharge voltages and 50% discharge strengths and the length of air gaps between the split phases, the contour of which is in the form of straight lines, at switching overvoltage pulses with a leading edge position of 3000 us, Fig. 4 shows a single-circuit three-phase transmission overhead line according to the invention with split phases, whose account Fig. 5 shows the electric power transmission line shown in Fig. 4 with intermediate support brackets in the same embodiment, Fig. 6 shows the electric power transmission line shown in Figs. 4 and 5 in another embodiment, Fig. 7 shows the one shown in Fig. 4. Fig. 8 shows a three-phase transmission overhead line according to the invention with split phases, one of which is split into two half-phases, Fig. 9 shows another embodiment of the electric power transmission line. according to the invention, in which the contour of one of the split phases is closed, while the contours of the other split phases are open (unlocked), Fig. 10 shows another embodiment of the electric power transmission line according to the invention, in which the contours of all split phases have the shape of unfinished curves, Fig. 11 shows the electric power transmission line shown in Fig. 10, where all the the contours of the split phases consist mainly of straight, horizontally located lines, Fig. 12 shows the electric power transmission line shown in Fig. 11, where the contours of the split phases are located vertically, Fig. 13 shows a unit for locking the position of the split phases at the Fig. 12 shows the embodiment in the span of the electric power transmission line, Fig. 14 shows the electric power transmission line shown in Fig. 11 intended for transmission of lower voltage, Fig. 15 shows the electric power transmission line shown in Fig. 12 intended for transmission of lower voltage, Fig. 16 shows a distribution of conductors in the split phases of the electric power transmission line shown in Fig. 12, Fig. 17 shows a relationship between the relationship between the natural power Pn of the electric power transmission line according to the invention and the natural power P of the conventional known electric power transmission line for the same voltage and the ratio between the length L of the split center phase and refrain Fig. 18 shows a relationship between the wave impedance Zv and the working capacitance C of the electric power transmission line according to the invention with split phases and the ratio š, Fig. 19 shows an electric power transmission line according to the invention with an intermediate support bracket provided with a V-shaped leg for fastening of the split phases, the contours of which are in the form of concentric perimeters (circular paths), Fig. 20 shows an electric power transmission line according to the invention with end support bracket and Fig. 21 shows a section along the line XXI through the electric power transmission line shown in Fig. 20 and an axial view thereof.

In order to better understand the basic principle of the invention, it is suitable before considering the description of the embodiments of the invention to consider certain theoretical considerations which form the basis for providing the electric power transmission line according to the invention.

In order for three-phase transmission overhead lines to be able to operate with high economic performance, the transmission line conductors must be used efficiently, which in other words means that electricity must be transmitted at an economic current density in the line conductors. 455 704 14 According to the condition for limiting corona discharge in order to maintain corona discharge losses, radio interference, noise level, etc., within the permitted limits, the electric field strength at the conductors surface must not exceed a permissible field strength Etill, which depends on a radius of peace of the individual conductors, of which the split phases of an electric power transmission line are made up.

If this condition is taken into account as well as the requirement to most efficiently utilize the surface of the conductors, a permissible charge at the conductor can be determined from the following formula: 27722 ”fo Eriii qtnfï-ï <1), D qtili where n is the number of individual conductors in a split phase , Öb air dielectric constant, Kn a so-called distribution non-uniformity factor of the electric field strength at the surface of the conductors.

The factor Kn is equal to the product of two factors: K = K .K (2), where K is a non-uniformity factor for charge distribution across individual conductors in the split phase equal to the ratio between the maximum charge and the mean ~ charge, K is a non-uniformity factor for the electrical the distribution of the field strength over the surface of a conductor with the maximum charge equal to the ratio between the maximum electric field strength and the average field strength of the conductor in question.

In order for the surface of the conductors to be fully utilized, the working capacitance C of the electric power transmission line must be such that the charge occurring at the conductor at a phase voltage Ufas is equal to the allowable charge q to: 453 704 15, __ C = grill = ZAK Etiil (3) Ufas Kn Ufas It is clear from formula (3) that the work capacity must be increased when the number of conductors in the split phase increases.

The path impedance ZV of the electric power transmission line is determined by the following relation: 'Z = (4) there. VV is the propagation speed (propagation speed) of the electromagnetic path, which is almost equal to the speed of light and is approximately 3-108 m / s.

By inserting the expression (3) to determine the working capacitance C in the relation (4) it is obtained that Z _ Kn Ufas 60 'Kn' Ufas (5) v zjfß vv n roEtill n - ro - still The natural power of the electric power transmission line Pn can be determined from the known formula taking into account the formula (5), i.e. I 3 'U phase _ n' ro 'Etill' Ufas (6) V zo- rn It appears from the formula (6) that the power to be transmitted over a three-phase AC transmission line, if the surface of the conductors is used most efficiently, which in turn is determined by uniform charge and current distribution across the conductors, is directly proportional to the number of n individual conductors and can be increased theoretically infinitely at the same voltage. A s.k. specific natural effect Pn Sp_, which is dimensioned per single conductor, is equal to P -. ^ U P - 7? = .í_fL_iëÉÅÄ ___ ÉÉÉ_ (7) “SP _ 20 Kn 453 704 16 The connections shown in Fig. 2 are now considered below, the number n of individual conductors in a split phase being deposited along the abscissa, while along the ordinate axis the natural effect Pn i is deposited. mill. kW of single-phase three-phase transmission overhead lines for, for example, the same rated voltage of 500 kV. Individual conductors of all transmission lines are considered to be made of steel and aluminum, with the conductors' part of aluminum having a cross-sectional area of 240 mmz, an outer diameter of 2.24 cm, while the steel core of the conductors has a diameter of 0.96 cm.

A straight line t shown in Fig. 1 represents the theoretical natural boundary effect of the electric power transmission lines when the number of conductors in the split phase increases and these conductors are distributed optimally along circumferences with optimal diameters, while the conductors of the transmission lines are hung at the same height. Curve a represents the natural power of transmission lines with conventionally arranged split phases and conductors therein (Fig. 2a), the conductors in each phase being arranged along a circumference with a split radius rp = 0.4 m. Curve a (Fig. 1) shows that the natural effect of these electric power transmission lines increases to a small degree when the number of n conductors in these lines increases. If the number of n conductors is equal to 10, the natural power is 1.125 million kW, ie. this increases by only 26% compared with the standard electric power transmission line, in which the number of conductors in the split phase is equal to three and which has a natural power of 900 MW at a voltage of 500 kV. When the splitting radius rp increases to 0.7 m (Fig. 2b) and the split phase comprises ten conductors, the natural power Pn increases slightly larger (the curve in Fig. 1) compared with an electric power transmission line with a phase splitting radius of 0, 4 m, i.e. by 53%. However, such an increase in the natural effect is also relatively insignificant and makes it impossible to make optimal use of the conductors' cross-sections. The theoretical natural limit effect of the electric power transmission line can only be provided when the phase split radius increases to 2.5 m and the number of conductors increases to 10, which limit effect is approximately equal to 2.7 mill. kW, which value is three times as high compared to the conventional known electric power transmission line (Fig. 2a) for a voltage of 500 kV. However, when the diameter of the split phases increases to 5 m, the support brackets have considerably larger outer dimensions compared with the conventional known electric power transmission lines, namely that the height and width of the support brackets become 5 m and 15 m larger, respectively. Such a power transmission line becomes too space-consuming and expensive and consequently economically unprofitable.

Based on the above considerations, one can come to the conclusion that it is economically disadvantageous to increase the natural effect of the power transmission line by simply increasing the number of conductors in the split phase or by even increase the number of conductors and the phase splitting radius at the conventional known electric power transmission line.

From formulas (6) and (4) it can be deduced that P = 3 U2 n phase vv c (8).

It appears from this connection that the natural power of the power transmission line is directly proportional to its working capacity. During application to the conventional known electric power transmission lines, in which the conductors in the split phases are distributed laterally separated from each other by different circuits, the working capacitance C can almost be determined by the following relationship: 2 "'E Cæ // o D nrflff p * VÅ ___ 4e_ r P (9) L where D is the geometric mean distance between the center lines of the conductors in different split phases.

It appears from the relationship (9) that the working capacitance C - when the number of conductors in the split phases increases individually or at the same time as the phase splitting radius rp is made larger - increases depending on the logarithm of a change in the number of n conductors and the radius rp, in other words, it changes relatively slowly. The natural power of conventional power transmission lines, as already stated above, therefore changes insufficiently to be able to compensate for additional costs when increasing the number of conductors in the split phase individually or at the same time as the phase split radius is made larger.

The conclusions drawn show that the increase in the number of conductors in the split phases in order to increase the natural effect of the conventional known power transmission lines, regardless of the theoretical justification did not lead to the desired results, as such power transmission lines do not give good economic results.

The present invention is based on another way of increasing the natural power of electric power transmission lines.

As stated above, it appears from the connection (8) that the natural power of the electricity transmission line is directly proportional to its working capacity. In conventional designs and in a normal mutual position of the split phases, the working capacity increases slowly when the number of conductors in these phases increases. However, it is known that the working capacitance also depends on the design (shape) and the mutual position of the split phases of an alternating current transmission line.

It appears from this that with a certain design and with a certain mutual position of the split phases it can be ensured that the working capacity of the power transmission line in accordance with the relationship (3) is directly proportional to the number of conductors in the split phases.

A single solution to the problem has been found in the six- and three-phase transmission lines known from U.S. Pat. No. 3,249,773, where this solution has been realized by combining the phases. However, these known power transmission lines did not completely solve this problem, since the design (configuration) and mutual position of the phases were not optimal as stated above.

In accordance with the above-described basic principle of the present invention, the adjacent split phases are not only joined (i.e., arranged close to each other), but are also substantially spaced apart by an equal distance along the entire length of the phases, while the conductors in the phases, such a distance is separated from each other that they receive almost equal charges and currents. The investigations carried out have shown that the average working capacity C of such an electricity transmission line is almost equal to cf - 1.9s å ° (-Iš + o, 9). . (10), where S is the distance between the adjacent split phases, L the length of the space measured for the center phase according to the contours of the merged phases.

It appears from the formula (10) that the working capacitance of the electric power transmission line according to the invention is inversely proportional to the distance between the adjacent split phases.

The slightly non-uniform electric field, which is generated in the whole space between the split phases of the electric power transmission line proposed according to the present invention, which is determined by the connections (8 and 10), is quantitatively characterized by electric discharge in this field occurring in so-called streamer-like form (compare, for example, English: streamer discharge), when voltages exceed the impact strength of the air gap between the phases.

Fig. 3 shows the results provided in experimental investigations of the air gaps between the phases in one of the embodiments of the power transmission line according to the invention, in which the contours of the split phases mainly have the shape of vertical straight lines (Fig. 2c). Along the abscissa in Fig. 3, the distance S (in m) between the adjacent split phases is plotted, while 50% discharge voltages U5o% in mill. V (MV) and the electric field's 50% discharge strength E50% in kV / om are deposited along the ordinate axis.

The curve U in Fig. 3 represents a function relationship U50% = f (S). As can be seen from Fig. 3, the 50% discharge strength of the electric field (curve E) in the investigated electric power transmission line varies between 4.9 and 4.1 kV / cm depending on the distance S. If so-called marginal factors for the overvoltage level occurring over the power transmission line, which i.a. considering the convergence of the split phases under the influence of wind and ice, the adjacent split phases of the electric power transmission line according to the invention can be combined (brought closer together) to the distance S, at which the electric field strength in the gap between the phases varies between 1, 65 kV / cm, for electric power transmission lines with a maximum so-called overvoltage ratio, and 3.15 kV / cm in electric power transmission lines with a minimum overvoltage ratio. At the operating voltage, the electric field strength Earb is determined from the formula: E = __íílíJE¶E (11) work 5 'where U is the nominal voltage (rated voltage) across the electric power transmission line,' Vï 'the so-called the amplitude factor of the effective operating voltage.

Thus, according to the above considerations, according to the invention, the lower field strength limit Earb is preset equal to 1.65 kV / cm for electric power transmission lines with a rated voltage of 150 kV and an overvoltage ratio of 3: 1, while the distance between the adjacent the split phases of this transmission line are equal to 128 cm. For the electric power transmission line according to the invention for a rated voltage of 1150 kV, at an overvoltage ratio of 1.3: 1, the upper field strength limit E is preset equal to 3.15 kV / cm, while the distance between the adjacent split phases is 515 cm .

For comparison, the following data can be provided. In the conventional known three-phase transmission lines with split phases, in which the conductors are distributed laterally separated from each other, the field strength Earb is equal to 0.65 kV / cm at a voltage of 500 kV and at a distance of 11 m between the adjacent phases; 0.69 kV / cm at a voltage of 220 kV and a distance of 4.5 m between the adjacent phases and 1.08 kV / cm at a voltage of 500 kV and a distance of 6.5 m between the adjacent boundary phases. At the above-described known six-phase transmission line for a voltage of 462 kV, the field strength Earb at a distance of 4.4 m between the adjacent phases is equal to 1.48 kV / cm.

The distances between the adjacent phases of the electric power transmission line according to the invention, which are preset according to the above-described basic principle, ensure a sufficient impact strength of the air gap between the phases, e.g. in cases where wind stresses occur, which lead to the phases being brought together within the limits determined by the assumed calculated wind stresses. In order to ensure a higher functional safety of the three-phase transmission line with combined split phases according to the invention by preventing the phases from being combined to an unauthorized degree under the influence of wind, the conductors '"bounce" during de-icing and the conductors' "dancing" (galloping), in addition, take the following known measures: arranging spacers of metal in the span of the line, to which spacers the phase conductors are intended to be attached, arranging insulating spacers between the phases, and fixing the phase conductors in the span at anchors in ground by means of phase-insulated rods For example, thanks to the large number of possible combinations of contours for split phases and their relative positions, it is possible, according to the invention, to choose such combinations for the current conditions and parameters at which wind will occur. affect the merging of the phases as little as possible a grad.

All measures make it possible to combine the phases of the power transmission line to shorter distances, these measures being further benefited by reducing the overvoltage ratio in the power transmission line, for example by applying overvoltage limiters such as those described in Soviet inventors' certificates 504270 and 453 704 224 652637.

The three-phase transmission lines according to the invention, which are based on the theoretical justification described above, show the following technical and economic performance.

Fig. 1 shows a straight line c, which represents the natural power, which at a voltage of 500 kV can be transmitted over the electric power transmission line according to the invention shown in Fig. 2c, depending on the number of n conductors in each split phase. As can be seen from Fig. 1, the natural effect of the electric power transmission line according to the invention, when each split phase comprises ten conductors, is 2.6 mill. kW, which value is almost equal to the theoretically possible limit of 2.7 mill. kW, whereby the natural power can reach this limit, when the Kn factor is optimal.

Fig. 2d shows a comparison diagram of the natural power of the electric power transmission line according to Figs. 2a, b, c, which power is stated in relation to the width of the electric power transmission line path. Along the abscissa in Fig. 2d, the width B of the transmission line path is plotted, while a density Pn / B of the power to be transmitted over the electric power transmission line is plotted along the ordinate axis. The area of the rectangles represents the natural power of the electric power transmission lines in accordance with their designation in the upper part of Fig. 2. As can be seen from the diagrams in Fig. 2d, the natural power of the electric power transmission line 2c according to the present invention is considerably higher than that. of the conventional known electric power transmission lines 2a and 2b, at the same time as the web width of the electric power transmission line 2c according to the invention is considerably smaller than that of the conventional known electric power transmission lines 2a and 2b.

Fig. 4 shows a possible embodiment of the single-phase three-phase transmission overhead line with split phases according to the invention, which can be used for the transmission of high, very high and extremely high voltage.

This electric power transmission line comprises three split phases 1, 2 and 3, each of which comprises twelve individual conductors 4. The conductors 4 in each phase are attached to spacers 5, which are made of light metal, for example aluminum. alloy. The spacers 5 are arranged to form contours for the split phases in a plane which is perpendicular to the center line of the power transmission line. In the embodiment shown in Fig. 4, the spacers 5 are annular, the contours of the split phases 1, 2, 3 being closed and having the shape of circumferences. The spacer members 5 of metal are connected to each other by means of insulators 6 so that a single common construction is formed, the most closely suspended chains 7 of insulators being attached to an intermediate support bracket 8, the elements of which, as can be seen from the drawing, are arranged outside the space occupied by the phases and air gaps therebetween.

All the perimeters representing the contours of the split phases are concentric with each other so that the distances S between the split phases in two pairs, which are suspended at the support brackets for the adjacent split phases 1-2 and 2-3, are equal along the entire length of the contours of these phases. The distance S should be chosen so that the electric field strength between the split phases in each phase pair at the operating voltage varies between 1.65 kV / cm (at a maximum overvoltage ratio) and 3.15 kv / cm at a minimum overvoltage ratio across the power transmission line.

In this embodiment, the number of conductors 4 is, as stated above, equal in all split phases 1, 2 and 3.

The conductors 4 are, however, distributed along the contour of these split phases in different ways. In the split phases 2 and 3, the conductors 4 are, for example, separated by an equal distance (an equal division or an equal step). In the outer split phase 1, however, the conductors 4 are spaced apart by a different distance, as shown in Fig. 4, which shows that the upper half of the contour of the outer split phase 1 comprises five conductors, while the lower half thereof comprises seven conductors, which in other words means that the conductors in the lower half of the contour of the outer split phase 1 are separated from each other a shorter step than the conductors in the upper half of the contour. When the conductors 4 are distributed in this way, electric charges and currents therein are substantially equal to the average charge and the mean current, respectively.

In this embodiment, the electric field which occurs in the whole space between the phases is slightly non-uniform, whereby electric, flashover in this field, at overvoltages over the electric power transmission line, which exceeds the permissible ones, can only occur in "streamer-like" form.

The insulators 7 can consist of chains of plate-type insulators or of rod insulators, for example of porcelain or glass-plastic material (glass-reinforced plastic material). The insulators 6 can not be attached to the nearest points but to the most remote points on the annular spacers 5 of metal to ensure the desired insulation strength (overlay strength) via air and along the leakage path via an insulating rod , which can be designed with a corrugated surface or arranged analogously with bicycle wheels in order to increase the length of the leakage path.

The strength of the spacers 5 and insulators 6, 7 must be dimensioned taking into account the weight of all conductors in a single transmission line span and the weight of ice on the conductors. The intermediate support bracket shown in Fig. 4, to which the split phases 1, 2 and 3 are suspended, is formed with two legs 8, which slope outwards from the center line of the power transmission line and are supported by hinge members 9 attached to the foundation 10. At the top, the legs 8 are connected to each other by means of a cross beam or a flexible connecting link 11. The legs 8 are intended to be held in the desired position by means of outer and inner clamping means 12, 13 and 14, 15, respectively. The outer clamping members 12 and 13 are arranged on two floors and with their lower ends attached to anchors 16. The upper ends of the clamping means 12 are connected to the upper ends of the legs 8, while the upper ends of the clamping means 13 are connected to center parts of the legs 8. The lower ends of the clamping means 15 and 16 are attached to the foundations 10, while their upper ends are connected to the center parts of the legs 8 at the same level as the connection point for these center parts to the upper ends of the clamping means 13. As can be seen from the drawings, the chains 7 of insulators are attached to the upper ends of the legs 8 and arranged at an angle of 1200 relative to each other, which makes it possible to reduce the pivoting movement of the split, suspended at the support bracket caused by wind stresses and thereby reduce the distance between the legs 8. The spacers 5 of metal and the insulators 6 also prevent the conductors 4 of the split phases 1, 2 and 3 from being brought together (brought closer together).

In order to prevent the conductors of different phases from being connected to an impermissible degree and that the conductors in one phase are intertwined in electric power transmission line spans, spacers of metal and insulators can be provided in these, which are identical to the spacers 5 of metal and insulators 6, respectively. but are lighter, because they are not exposed to stresses arising from the weight of the leaders and the forces acting on them are small. The distance between such spacers and the insulators in the span should be chosen so that the phases are brought together to a very small extent along the length of the power transmission line, when the conductors are de-iced, galloping (dancing) under the influence of wind and other factors, the remaining distance between the phases in all case is sufficient to ensure the insulation strength.

In the above-described embodiment of the electric power transmission line according to the invention, the support brackets are provided with one or two legs, not shown in the drawings, of ropes. One or more conductors in this transmission line can be electrically isolated from the metal structures for the purpose of using said conductors as communication lines. In addition, other conventional additional devices can be used, which are useful with the known conventional electric power transmission lines.

The above-described, single-circuit, three-phase transmission overhead line with split phases shows high working capacitance and consequently lower wave impedance and higher natural power in that the distance between the adjacent split phases is short due to a slightly non-uniform 453 704 I 453 704 26 electric field is generated between said split phases.

As a concrete example, an electric power transmission line for a voltage of 500 kV is considered below, in which the contour of the inner split phase has a diameter of 1 m, the distance between the adjacent split phases is equal to 2.5 m and the contour of the split center phase has a diameter of 6 m and a length of 18.9 m. In this power transmission line, each split phase is made up of 26 conductors of steel and aluminum, with an outer diameter of 2.9 cm, whereby the part of the conductors of aluminum has a cross-sectional area of 400nm2 and the steel core of the conductors has a diameter of 1.25 cm, while the so-called economic current density is equal to 1 A / mmz. The electricity transmission line so designed according to the invention has a natural effect of 9 mill. kw, which value is ten times higher than the natural power of the known conventional power transmission line for a voltage of 500 kV, which power is 0.9 mill. kW.

A second concrete example relates to the electric power transmission line shown in Fig. 4 according to the invention for a voltage of 330 kV, where the contour of the inner split phase has a diameter of 0.7 m, the distance S between the adjacent split phases is 1, 5 m and the contour of the split center phase has a length of 7 m. In this transmission line, each split phase is made up of 13 conductors of steel and aluminum with an outer diameter of 2.24 cm, the conductors' part of aluminum has a cross-sectional area of 240 mmz and the steel core has a diameter of 0.94 cm, while the current density is 1 A / mmz. The natural effect of this transmission line is equal to almost 1.8 mill. kW or 5.9 times higher than the known conventional electric power transmission line for a voltage of 330 kV, whose natural power is 360 MW.

The above examples show that the single-circuit three-phase transmission overhead line according to Fig. 4 has a natural power which is considerably higher than the power of all known alternating current transmission lines, at the same time as it has a very compact construction, so it becomes very economical. In the embodiment of the electric power transmission line according to the invention described with reference to Fig. 4, only a single type of intermediate support brackets was used.

It should be noted, however, that in the above-described arrangement of split phases and the above-described method of suspending them at the intermediate support bracket, support brackets of other types can be used while maintaining the high technical properties of the good economy typical of the the above-described embodiment of the electric power transmission line according to the invention. Fig. 5 shows, for example, the use of a U-shaped support bracket 17 with a straight horizontal cross beam, while Fig. 6 shows a substantially U-shaped support bracket 18 with a rounded cross beam. Fig. 7 shows a V-shaped support bracket 19 with converging legs adjacent to the base part.

In all and subsequent embodiments of the invention, the conductors 4 are attached to the spacers 5 of metal by means of clamping means 20 (in Fig. 4 only one clamping means is shown).

The position and number of insulators 6 and 7 can - like the support brackets of different types described in the example above - depending on the voltage across the power transmission line and the climatic conditions of the transmission line path differ from what is shown in the drawings and described in the examples given above. but they must in any case be chosen so that the conductors and their insulation are attached functionally safe.

Fig. 8 shows a second embodiment of the electric power transmission line according to the invention. The elements analogous to those in Fig. 4 have the same reference numerals.

In this embodiment (Fig. 8) the contours of the split phases - as in the first embodiment - are closed and have the shape of circumferences. However, in this embodiment, one of the split phases is divided into two half-phases 3a and 3b, the contour of which also consists of a circumference. Each half-phase 3a, 3b comprises equal numbers of individual conductors 4, for example six conductors, while each split phase comprises a total of twelve conductors 4. The half-phases 3a and 3b are, as can be seen from Fig. 8, arranged inside the contours of the split phases 1 and 2 respectively split the contour perimeters of the half-phases 3a and the split phase 1 and the contour perimeters of the half-phases 3b and the split phase 2 are arranged concentrically with each other. The distance S and the distribution of the phase conductors in the outer split phases 1 and 2 are the same as in the embodiment described above, which contributes to generating a slightly non-uniform electric field, in which electric flashover can only occur in streamer form, when over - voltages across the power transmission line exceed those permitted.

At the ends of the power transmission line or at other suitable places, the half-phases 3a and 3b are electrically connected to each other.

The other components of this electric transmission line are similar to the respective components in the first embodiment.

This (second) embodiment of the electric power transmission line can have a natural effect, which is almost 10% lower than that of the first embodiment. However, this embodiment of the electric power transmission line makes it possible to reduce the height of the support brackets compared with the first embodiment. Fig. 9 shows another embodiment (a third one) of the electric power transmission line according to the invention, wherein the components in this transmission line which are identical to the respective components of the electric power transmission line according to Fig. 4 have the same reference numerals.

In this embodiment, one of the contours along which the conductors in the split phases are distributed in the cross section of the power transmission line, for example the contour of the inner split phase 3, is closed, taking the shape of an oval, while the contours of the other two split phases 1 and 2 are unlocked (open) and have the shape of curves which surround the contour of the split phase 1. The contours of the split phases 1 and 2 are, as shown in Fig. 9, up to located in such a way , that their convex parts are facing downwards. It is further apparent from Fig. 9 that the embodiment of the electric power transmission line shown in Fig. 9 as provided by cutting and disassembling the two outer phases in the embodiment according to Fig. 4.

In the embodiment shown in Fig. 9, each split phase 1, 2, 3 comprises fifteen individual conductors 4. However, the number of conductors in the split center phase 2 and in the lower split phase 1 or in either phase 2 (or 1) may be greater than the number conductor in the upper split phase 3, which may be suitable due to the fact that the lower split phase 1 has a high capacitance due to the fact that the phase has considerable dimensions and / or due to the fact that the split center phase 2 has a relatively high capacitance. capacitance due to the fact that the center phase 2 is arranged between the two split phases 1 and 3. Such a phase split into different large numbers of conductors 4 makes it possible to distribute the currents over these conductors 4 most uniformly and thereby reduce the electric power losses in the electric power transmission line.

As can be seen from the drawing, the conductors 4 in the split center phase 2 and in the outer lower split phase 1 are spaced apart by a different size along the contours of these phases. In the center part of the contours of the split phases 1 and 2, the conductors 4 are spaced apart by a smaller distance compared to the mutual position of the conductors 4 in the outer parts of the contours of said phases. This contributes to a uniform charge and current distribution in the conductors 4.

The reduction of the distance between the conductors in the vicinity of the ends of the unopened contours of the split phases also makes it possible to equalize the electric field strength in the vicinity of these ends and consequently reduce the so-called the end effect, which prevents local corona discharge from occurring at the outer conductors in the contours of the split phases 1 and 2. For the same purpose, near the edges of the contours of the split phases 1 and 2 individual conductors 4 are arranged on both sides of the spacer of metal.

Taking these measures against desirable end effects is of particular importance for electric power transmission lines for the transmission of very high and extremely high voltages. The distances S between the adjacent split phases 1-2 and 2-3 are preset in the same way as in the previous embodiments of the invention. This circumstance as well as the said design and positions of the split-up phases and the individual conductors in them contribute to the electric field appearing in the whole space between the phases, in this embodiment, as well as in the embodiments described above, being slightly different, in which field electrical surge can only occur in streamer form when overvoltages across the power transmission line exceed those permitted.

The suspension chains 7 of insulators are in this embodiment connected to the ends of the spacers 5 of metal of the split phases 1 and 2, the chains 7 being guided towards the corners of the cross beam 11 of the intermediate U-shaped support bracket in lines, which are close to the tangent at the ends of the contours of the split phases 1 and 2.

The other components in this embodiment of the electric power transmission line are designed in the same way as in the first embodiment.

The electric power transmission line shown in Fig. 9 has a lower transmission capacity compared to the electric power transmission lines according to Figs. 4 and 8, since the ratio between the length L of the contour of the split center phase 2 and the distance S between the adjacent split phases in this embodiment of the electric power transmission line (Fig. 9) is lower than in the first and second embodiments, however, this embodiment is preferred in many cases, for example when an excessively high natural power is not required, so that the first and second embodiments of the power transmission line, economically, are not suitable for use.

Fig. 10 shows a further embodiment (a fourth embodiment) of an electric power transmission element according to the invention. The components of this transmission line which are identical to the respective components in the embodiment according to Fig. 4 are denoted by the same reference numerals.

In this embodiment (Fig. 10), all the contours, along which the conductors 4 in the split phases 1, 2 and 3 are arranged in the cross section of the electric power transmission line, are not closed, these contours, as shown in Fig. 10, being - actually has the shape of curved lines, the convex part of which is turned downwards. It can also be seen from Fig. 10 that the electric power transmission line designed according to Fig. 10, seen in cross section through it, as if provided by cutting the upper phase 3 in Fig. 9 and separating the ends of all phases.

In the embodiment shown in Fig. 10, each split phase 1, 2, 3 comprises twelve individual conductors 4. However, the number of conductors in the split center phase 2 and in the lower split phase 1 or in either phase 2 or 1 may be larger. than that in the upper split phase 1 in order to be able to distribute the currents in these conductors most uniformly.

As can be seen from Fig. 10, the conductors 4 in the center parts of the phases 1 and 2 are spaced apart by a greater distance than the conductors 4 in the outer parts of these phases, i.e. in exactly the same way as in the previous (third) embodiment.

The distances S between the adjacent split phases in pairs 1-2 and 2-3 are selected in the same way as in the embodiments described above, the electric field appearing in the entire space between the phases of this embodiment of the electric power transmission line being slightly non-uniform, in which field electrical surges can only occur in streamer form, when overvoltages across the transmission line exceed the permissible ones.

The upper cross beam 11 shown in Fig. 10 is polygonal.

The spacers 5 of metal with the conductors 4 are suspended at the inclined sides of the crossbeam 11 by means of the chains 7 of insulators, the angle of inclination of which towards the horizon decreases in the direction from the upper split phase 3 to the lower phase 1. In this embodiment the spacers 5 are not connected to each other by means of insulators, as is the case with the preceding embodiments, which is made possible by the fact that wind stresses are not dangerous when the contours of the split phases 1, 2 and 3 are formed in the manner shown in Fig. 10 and the chains 7 of insulators are arranged in the manner shown in Fig. 10. Under specific conditions of use of the electric power transmission line, insulators between the spacers of metal and spacers can also be used, if required, in this embodiment as well as in the previous embodiments. metal stand means with insulators in between in the power transmission line span.

The transmission line shown in Fig. 10, like the line shown in Fig. 9, is intended to be used at a lower transmission capacity compared with the electric power transmission line according to Fig. 4.

Fig. 11 shows another embodiment of the electric power transmission line according to the invention. The elements in this line which are analogous to the respective elements in the transmission line according to Fig. 4 are denoted by the same reference numerals.

The cross-sectional shape of the power transmission line shown in Fig. 11 is almost similar to that of the line shown in Fig. 10 but differs from this by further straightening the contours of the split phases 1, 2 and 3. The contours of phases 1 shown in Fig. 11 -3 consists, along most of the contour length, of straight, horizontal lines.

In this embodiment, the number of individual conductors 4 in each split phase 1, 2, 3, the distribution of the conductors 4 and the distance S between the adjacent split phases in pairs 1-2 and 2-3 are the same as in the embodiment shown in fig. therefore, the electric field in the entire space between the phases, even in the embodiment according to Fig. 11, is slightly non-uniform, in which field overflow can only take place in streamer form, when overvoltages over the electric power transmission line exceed those permitted.

The intermediate support trestles of the transmission line shown in Fig. 11 are built up of two vertical legs 8, which are supported by the hinge members 9 on the foundations 10. The upper ends of the legs 8 are connected to each other by means of the flexible connecting link 11 and fastened by the anchors 14 the tensioning means 12 and 13. On the upper ends of the legs 8 and on the flexible connecting link 11, lightning protection lines 21 are arranged. The number of lightning protection lines 21 can be changed depending on the concrete conditions. The spacers S with the conductors 4 are attached to the embodiment shown in Fig. 11 by means of the chains 7 of insulators at the legs of the support frame 8. In this embodiment the shape of the contours for the split phases 1-3 and the position of the chains 7 of insulators even more favorable compared with the transmission line shown in Fig. 10, which makes it possible in many cases to do without insulators for fastening the spacers 5 of metal.

The electric power transmission line shown in Fig. 11, like the line shown in Fig. 10, is intended to be used at a lower transmission capacity compared with the electric power transmission line according to Fig. 4. However, the line shown in Fig. 11 is easier to manufacture compared to the line according to Fig. 10.

Fig. 12 shows an electric power transmission line according to the invention, in which the contours of the split phases are not closed and have, mainly, the shape of straight vertical lines. The components shown in Fig. 12, which are analogous to the respective components in Figs. 4-11, are denoted by the same reference numerals.

The cross-sectional shape of the conduit shown in Fig. 12 is provided as if, by the conduit shown in Fig. 4, vertically cut all the circumferences along which the conductors in the split phases are distributed, with subsequent straightening of three halves of the half-circumferences.

In the embodiment shown in Fig. 12, the contour of the split center phase is formed by a straight line segment, at the ends of which are arranged further spacers 22 of metal, of short length, which are perpendicular to the main spacer 5 of metal. The contours of the two outer split phases 1 and 3 consist, along most of their length, of straight lines, but their ends are bent outwards in relation to the center phase 2.

In this embodiment, the metal spacers 5 are attached to the support bracket by means of their two ends, the upper ends of the spacer members 5 being, as a rule, by means of the chains 7 of insulators being attached to the upper cross beam 11, ..1. Of the U-shaped support bracket. ,,,,,. 453 704 34 while their lower ends by means of insulators 23 are attached to the further, lower cross beam 24 of the U-shaped support frame. The insulators 23 can be provided with damping means 25, for example of spring type, in order to prevent the insulators 23 from being damaged when one of the conductors 4 are broken.

As can be seen from Fig. 12, the conductors 4 in the center portions of the contours of the split phases 1-3 are spaced apart by a greater distance than the conductors 4 at the ends (edges) of the contours of these phases. To prevent the formation of local corona discharge, an additional conductor is arranged at each end of the contours of the split phases 1 and 3, which is located at the side of the spacer 5, which is opposite all the other conductors in the respective split phase. In the split center phase 2, the additional conductors are attached to the ends of the spacers 22 of metal. All measures against undesirable. end effects become particularly necessary for electric power transmission lines for the transmission of very high and extremely high voltages.

The distance S between the adjacent split phases in pairs 1-2 and 2-3 is along the majority of the contour length chosen in the same way as in the embodiments described above. This circumstance as well as the said design and mutual position of the split phases and the individual conductors in them contribute to the electric field in the whole space between the phases in the embodiment according to Fig. 12 as in all previous embodiments being slightly different, in which field electrical surge can only occur in streamer form when overvoltages over the power transmission line exceed those permitted.

In the embodiment according to Fig. 12, in contrast to the two previous embodiments, the insulators 6 must be arranged between the spacers 5 of metal, which insulators are intended together with the chains 7 and 23 of insulators to prevent the split phases 1-3 brought together to an impermissible degree under the influence of wind. In order to prevent the phases from being brought together to an impermissible degree and the conductors in one of the split phases being intertwined in the electric power transmission line bucket, the same spacers 5 of metal and insulators 6 can be arranged in them, but more easily such, since they are not subjected to gravity. from the leaders. Instead of the insulators 6, in the electric power transmission line span, phase-voltage-insulated, at anchors 27 (Fig. 13), fixed rods 26 can be arranged. The transmission line according to Fig. 12 has a narrower path compared to the other embodiments, while its natural effect can amount to to that of the electric power transmission lines shown in Figs. 9-11.

Figs. 14 and 15 show embodiments of the electric power transmission line according to the invention, in which the contours of the split phases along their entire length are constituted by straight lines. The cross-sectional shape of the transmission lines shown in Figs. 14 and 15 differs, as can be seen from the drawings, from the cross-sectional shape of the lines shown in Figs. 11 and 12 in that the ends of the contours of the split phases are straightened.

In these two embodiments, each split phase 1, 2, 3 comprises five individual conductors. Such power transmission lines can be used at a relatively low rated voltage, for example 150-220 kV, when it is possible to use conductors with such a diameter as the conductors in transmission lines for such voltages usually have, whereby at this diameter local corona discharge does not occur at the individual leaders. In the embodiments according to Figs. 14 and 15, the distance S between the contours of the adjacent split phases 1-3 is selected in the same way as in all embodiments, which contributes to the electric field, which is effective in the entire space between the phases. , can only occur in streamer form, when overvoltages over the power transmission line exceed the permissible ones.

The contours of the split phases 1-3 of the electric power transmission lines according to Figs. 14 and 15 are arranged in different ways.

In the line according to Fig. 14, the contours of phases 1-3 have the shape of straight, horizontal line segments, while the spacers 5 of metal at both ends are attached to the legs 8 of the support frame by means of the insulator chains 7. In most cases removed - falls the need to install insulators between the spacers 5 of metal in such electric power transmission lines, i.a. in the transmission line span, after-wind, as a rule, blows parallel to the ground surface, so the conductors are practically not brought together.

In the electric power transmission line according to Fig. 15, the contours of the split phases 1-3 have the shape of straight, vertical line segments, while the spacers 5 of metal with one end are suspended at the crossbeam of the support bracket by means of the chains 7 of insulators. In this embodiment, the spacers 5 are connected to each other by means of the insulators 6. In the span of this transmission line one can also place light spacers 5 of metal and insulators 6. By increasing the number of conductors in the split phases and the contour length of these ring lower is small, the lower ends of the spacers 5 do not need to be fastened by means of insulators, unlike what is the case with the embodiments of the transmission line shown in Figs. 12 and 13.

In the embodiments of the electric power transmission line according to. the invention, where the contours of all the split phases are open (unlocked) in accordance with what is shown in Figs. 10-15, it is suitable that the contours of the split center phases 2 have a shorter length than the contours of the outer split phases 1 and 3, which is required to equalize the capacitances and voltage drops in all phases of the electric power transmission line, at which the capacitance of the split center phase 2 is higher than that of the outer split phases 1 and 3, which contributes to the number of so-called transposition cycles are reduced to what corresponds to the known conventional electric power transmission lines of this kind.

Fig. 16 shows in the longitudinal scale of the contours of the split phases 1-3 the position of the conductors 4 in these in the embodiment of the electric power transmission line according to the invention shown in Fig. 12 for a voltage of 500 kV. As can be seen from Fig. 16, the distance between the conductors 4 in the center portions of the split phases 1-3 is greater than those in the outer portions of these phases. Placing the conductors in the split phases thus makes it possible, as stated above, to equalize charges and currents in the conductors, which is why a fairly uniform electric field can be generated in the air gaps between the split phases. Such a distribution of the conductors in the split phases also makes it possible to reduce power and energy losses. By joining the conductors 4 at the ends of the contours of the split phases, the formation of local corona discharges can also be prevented.

In the contour length of the split center phase 2 is 3 m, while the contour length of the outer split phases 1 and 3 is 3.5 m, which in other words means that the contour length of the center phase 2 is less than the contour length of the outer split phases 1 and 3. This makes it possible to equalize the capacitances and voltage drops in all phases of the electric power transmission line and consequently reduce the number of transposition cycles for the electric power transmission line to what is typical of the known electric power transmission lines of this kind.

Fig. 16 further shows that the number of conductors 4 in the ° split center phase 2 is twelve, while the number of conductors 4 in the outer split phases 1 and 3 is nine. Because the number of conductors 4 in the center phase 2 is thus greater than that in phases 1 and 3, it is possible to equalize the currents in the conductors, since the current in the center phase 2 is greater than that in the outer phases 1 and 3 by the two outer phases 1 and 3 have a capacitive effect on the center phase 2.

All features considered with reference to Fig. 16 are highly significant when the number of conductors in the split phases is very large.

One of the ehua transmission lines shown in Figs. 12 and 16 according to the invention has the following properties.

The voltage across this transmission line is 500 kV. The total number of conductors 4 in the transmission line is 30, the conductors 4 being made of steel and aluminum and having a surface diameter of 2.24 cm. The part of the conductors 4 of aluminum has a cross-sectional area of 240 mm2, while the steel core of the conductors 4 has a diameter of 0.94 cm. The distance between the split phases is 3 m and the length of the contour of the outer split phases 1 and 3 is 3.5 m, while the contour length of the split center phase 2 is 3 m. The center phase 2 has twelve conductors, each outer the phase includes nine conductors. The effective (effective) electric field strength at the surface of the conductors is 21.1 kV / cm, while the electric field strength under the electric power transmission line, at the same level as the human growth, is 9 kV / cm. The corona discharge losses over this transmission line are 14 kV / km. The width of the transmission line path under the conductors is approximately 6.5 m. The natural effect of the line is 2.6 mill. kW, i.e. three times higher than the natural power (equal to 900 MW) of the known conventional power transmission line for the same voltage.

In the case of three-phase transmission lines according to the invention with open contours for the split phases (Figs. 10-16), it is possible to select any contour length L of the split phases in accordance with the distance S between them. This makes it possible to provide an arbitrary natural power within a wide range, for example equal to 1 to 5 times the natural power of the known conventional electric power transmission lines for the same voltage.

In all embodiments of the electric power transmission line according to the invention, the important parameters are the distance S between the adjacent split phases, the contour length L of the split phases and the ratio å.

It appears from the connection (10) that the working capacitance C of the electric power transmission line according to the invention is almost directly proportional to the ratio L / S. This relationship is shown in Fig. 17, where the ratio L / S is plotted along the abscissa, while along the ordinate axis is plotted the ratio (ratio) between the natural power Pn of the power transmission line according to the present invention and the natural power Pn conV_ of the known conventional power transmission lines of this kind, i.e. Pn / P whereby P n conv. ' The convection values are given in the table below, depending on the rated voltage across the transmission lines, with which the line according to the invention has been compared.

U 150 220 330 500 750 1150 nom kV Pn conv. ao 160 360 soø zooo ssoo Mw Electric power transmission line average 200 200 300 800 1000 1500 part length, km It appears from Fig. 17 that the relationship Pn / Pn konV_ = = f (L / S) is almost rectilinear and that it the natural power of the transmission line according to the invention can be changed within wide limits, whereby it can be increased several times compared with the natural power of the known conventional electric power transmission lines for the same voltage.

After selecting the optimal distance S between the split phases for the predetermined voltage across the line, the length L of the contour of the center phase is determined depending on the desired natural power of the line and the power ratio compared to the known conventional transmission line. - ningen. It is then preferable to use the electric power transmission line according to the invention with open contours for the split phases, for which transmission line one can select an arbitrary ratio Pn / Pn conv. from 1: 1 to 5: 1, i.e. in the area that in most cases is of practical interest, or in an even broader area.

Fig. 18 shows the relationship between the main quantities C and ZV, which affect the natural power of the transmission line, and the ratio L / S.

The number of n conductors in the split phases of the electric power transmission line according to the invention is determined from formulas (10) and (3) by the following relationships: 453 704 40 = Kn - 1.95 (L / s + 0.9) Ufas H2) (__ ZJL ro Etill Based on the above considerations, it can be concluded that the power transmission line should be dimensioned as follows: At a predetermined natural power Pn and a predetermined phase voltage U, the current is determined, after which, depending on the: ïëkne economic current density. determines the required sum cross-sectional area of the conductors in each phase of the transmission line, according to Fig. 3 the distance S is then determined taking into account the allowable overvoltage level, after which the L / S ratio is determined using the curve shown in Fig. the length L of the contours of the split phases is selected, and the number of n conductors is then determined in accordance with the relationship (12).

Then a more accurate calculation is made taking into account the electric field strength at the surface of all conductors, the factor Kn and the other parameters at the selected cross-sectional shape of the electric power transmission line depending on the L / S value and n. It should be noted that the conductors in the transmission line according to the invention should be selected with the same cross-sectional area in order to ensure an equal degree of deflection of the conductors in the span of the transmission line.

It appears from the above that the electric power transmission line according to the invention has the very important advantage that the increase in the number of conductors in the split phases without any significant increase in the cross-sectional dimensions of the transmission line makes it possible to increase the natural effect in a ratio , which is almost equal to the theoretical.

Fig. 19 shows an electric power transmission line according to the invention, in which, thanks to the contours of the split phases being in the form of concentric perimeters, an intermediate support bracket of a different type can be used compared with the 453 704 41 types shown. and described above. The components which are identical to the respective components shown earlier in the drawings are indicated in Fig. 19 by the same reference numerals.

The support bracket shown in Fig. 19 comprises two V-shaped legs 8, which are supported by the hinge member 8 of the base part. The base part comprises three inclined legs 28, which diverge, seen in a plan view, at an angle of 1200 and are supported by three surface foundation plates 29.

One of the inclined legs 28 is, as shown in Fig. 19, arranged along the center line of the electric power transmission line, which is preferred taking into account any stresses which may affect the support bracket, as well as the possibility of lifting the support bracket while aligning it. i. the axis direction of the transmission line.

The upper ends of the legs 8 are connected to each other by means of the flexible connecting link 11 and to the lower ends of two of the inclined legs 28. These lower ends 28 of these legs 28 are connected to each other by means of a common flexible connecting link 30, which is guided so that it can be energized (transferred to voltage state) from a single common point. Such a clamping contributes to all parts of the flexible connecting link 30 and of the flexible connecting link 11 being clamped in a ditch-shaped manner, at the same time as the legs 8 and the inclined legs 28 of the base part are clamped. This makes it possible to give the support frame the desired rigidity of shape and to profitably use the material for the production of all the legs, since the forces acting in these are directed axially.

The support bracket described above is stable, since it is pressed against the ground by a considerable force of gravity from all the conductors in the transmission line according to the invention. The foundation slabs 29 can, if required, be embedded in the ground.

This support bracket makes it possible to reduce metal consumption by 30-60% compared with the other known support brackets, e.g. with those described above. The second advantage of this support bracket is that the entire construction can be mechanically tensioned by means of a single hoisting rope. The use of the foundation tiles also makes the production of the foundations simpler and cheaper. Figures 20 and 21 show an end support bracket of the electric power transmission line according to the invention, where the conductors in the split phases, seen in the cross section of the transmission line, are distributed along three concentric perimeters. With such a power transmission line, it is very difficult to lead the conductors in the split phases, if one uses the conventional known ä fl dS fi í fl XX * Hrna, i.a. U-shaped ones with a single pair of legs.

The U-shaped end bracket shown in Figs. 20 and 21 comprises three portal parts 31, 32 and 33 (Fig. 20), which are arranged in series one after the other in the axial direction of the transmission line. The height of the portal parts 31-33 gradually decreases towards the end of the transmission line. The upper ends of the parts 31-33 are rigidly connected to each other by means of a beam 34, while their lower ends are supported by foundation 35. In order to give the entire end support frame the desired stability and strength, the portal parts 31-33 are connected to each other by means of rigid connection links 36, together with each part 31-33 are provided with rigid, connecting links 37 and 38 (fig. 21) arranged between the legs 8 and struts 39.

The conductors 4 in the split phases, the contours of which are constituted by circumferences, are attached in phase, by means of tension chains 30 of insulators (Fig. 20) (for each conductor a single chain 40) to each of the portal parts 31, 32 and 33, respectively. the first, seen in the direction of electric transmission of the line, the portal part 31, the conductors in the outer split phase 1 are attached, while the conductors in the split center phase 2 are attached to the second portal part 32. The conductors in the inner split phase 3 are attached to the third portal part 33.

Fig. 21 shows the end support bracket in a section along the line XXI-XXI, seen in the direction of the second portal part 32. Fig. 21 shows how the inner split phase 3 is carried and how the conductors in the split center phase 2 are fastened by means of tension the chains 40 of insulators. Fig. 21 also shows how conductors from the phases of the transmission line to a substation are designed (the conductors from the inner split phase 3 are not shown in the drawing, for the sake of simplicity). Because all conductors in one phase are kept at the same potential and are attached to the metal spacers common to each split phase on the intermediate support trestles and in the span, all the phases in one phase do not need to be electrically insulated from each other. but they must be isolated from the scapegoats and conductors in the other phases. Therefore, at each portal part 31-33, by means of chains 41 of insulators, a spacer 42 of metal is suspended, which is common to all the conductors in one of the split phases. In each split phase, the conductors 4 are connected to the spacer 42 of metal by means of loops 43, the upper end of which is fastened to the conductors by means of clamping means and is freely guided downwards. After all the loops 43 in one phase have been connected to each other, their upper end is fastened by means of a spacer 44 of metal (Fig. 20) to respective spacers 42 of metal suspended from the support stand. Fig. 21 shows that the upper conductors can be connected by means of clamping means and conductor pieces 45 to the adjacent underlying conductors, from which the loop 43 is led. In this case, the number of loops 43 decreases, but the loops 43, which are intended to connect several conductors to the spacer 42, may have to be designed with a larger cross-sectional area. From each metal spacer 42, the conductors in each phase can be easily routed to the substation by means of horizontal rows 46, 47 and 48 (Fig. 20) for phases 1, 2 and 3, respectively.

Similarly, anchoring and corner support brackets can be designed, each of which must include two portals, each of which in turn is provided with three interconnected portal parts, as described above for the end. - the scapegoat.

The mounting anchors for the conductors described above can be used not only for the electric power transmission line, where the contours for split phases consist of concentric perimeters, but also for the transmission lines shown in Figs. 9 and 10. 45zp7o4 44 The natural power or transmission power of the single-circuit three-phase transmission overhead lines according to the invention may be several times (ten times and above) higher than the power of the known conventional electric power transmission lines for the same voltage, at which the split phases are separated from each other in a conventional manner. Because the transmission line according to the invention has a high capacitance, it can be called a cable-type overhead line, which can replace several conventional lines for the same voltage with their sum-transmitting capacity. The transmission lines according to the invention also provide good economy.

The manufacturing costs of the conductors of the electric power transmission line according to the invention and the known transmission line are in fact equal, since the conductors in both cases are selected depending on the economic current density, why their sum cross-sectional area and weight will be equal for the two power transmission lines. This circumstance is very important, since the manufacturing cost of the power transmission line is 25-55% of the total manufacturing cost of the power transmission line depending on the voltage across it.

In addition, since the transmission line according to the invention and the known conventional transmission line are built up of the same conductor, the two transmission lines have the same span.

The manufacturing cost of the spacers of metal and the insulators in the gap inside the support trestles of the transmission line according to the invention will be higher than that of a single conventional electric power transmission line but is equal to or lower than that of several conventional transmission lines with the same natural sum power, as the only transmission line according to the invention has. Because the conduit according to the invention is provided with light spacers made of metal and insulators arranged in the conductor span, the manufacturing cost of this conduit increases to a small degree, at the same time as these spacers and insulators do not affect the deflection and span of the conductors. The total manufacturing cost of the support trestles and the foundations of the transmission line according to the invention is lower than that of the known conventional line of this kind.

For the conventional known power transmission overhead lines, the weight ratio between the support trusses is known to depend on the relationship between the stresses (loads) acting on the support trusses, the two conditions being related to each other: (13), where G1 the mechanical load is the weight of the support bracket with a lower load, G2 the weight of the support bracket with the weight G1, and N2 the mechanical load on the support bracket with the weight G2.

It appears from this connection that the weight of a single support bracket in the transmission line according to the invention, which replaces four conventional known lines, constitutes 2.52 times the weight of the single support bracket in this known transmission line, but is 37% lower compared to the total The weight of the four support brackets required for the known line. The intermediate support brackets of the transmission line according to the invention also have smaller dimensions and lower weight compared to those of the known transmission lines, which can be confirmed by the following examples. The transmission line according to the invention shown in Fig. 16 for a voltage of 500 kV and with a natural power of 2,600 MW is characterized in that the distance between the external phases is approximately 7 m, while this distance of the known line for the same voltage and with a natural power of 900 MW is about 24nn, ie it is 3.4 times larger. The height of the transmission line according to the invention is slightly greater than that of the known line, but this for ash protection of the outer phases requires two legs made of ropes, while a single leg of ropes with less height in the transmission line according to the invention can ensure the same lightning protection angle. which almost evens out the height of the support brackets in the two lines. Because the width of the support trusses 45s_7o4 46 and the loads resulting from the weight of the outer phases are considerably smaller and lower compared with the known transmission line, the metal consumption and the manufacturing cost of the intermediate support trestles in the line according to the invention are significantly lower compared to the known the transmission lines, in particular when using the intermediate legs with legs with the clamping means described above. The end, anchorage, corner and transposition support brackets of the transmission line according to the invention can become more complicated and more expensive with their determined cross-sectional shape. Because the number of transposition cycles and consequently the number of transposition support brackets at the transmission line according to the invention and at the known transmission lines (if it is taken into account that the number of end, anchorage, corner and transposition support brackets is small compared to the number of intermediate support brackets) referred to above with reference to the embodiment shown in Fig. 16, however, the manufacturing cost of said support brackets in most cases does not appreciably affect the manufacturing cost per running kilometer of the electric power transmission line.Because the support brackets of the electric power transmission line according to the invention are considerably lighter than the known conventional ones. the power transmission lines, the foundations for supporting these support trestles will also be lighter and cheaper, especially when the foundation plates 29 (Fig. 19) are used.

Taking into account the general trend of technological development, according to which the increase in the power and capacity of the plants makes these plants more economically viable, there is no doubt that the only power transmission line, which can replace a few conventional power transmission lines, requires lower material consumption, less labor input and lower construction costs than the known conventional electric power transmission lines do. The preparatory average calculations show that the production cost per running kilometer of the electric power transmission line according to the invention is 1/3 lower compared to that of the three known conventional electric power transmission lines, which are to be replaced by the transmission line according to the invention.

In addition, when a few known conventional electric power transmission lines are replaced with a single electric power transmission line according to the present invention for the same voltage, a further saving is achieved by reducing the number of switches and other devices at the end stations. For the electric power transmission line according to the invention, one can use both switches for high currents at higher natural power, which is cheaper compared to the use of a few switches for relatively low currents, and conventional switches, the number of which can be equal to two or three per electric transmission line. how these switches are connected.

The functional reliability of the electricity supply system with a single electric power transmission line is generally lower than that of the system with several parallel-connected electric power transmission lines for the same voltage. However, long-standing practical experience in the use of electric power systems in the Soviet Union, which are connected to each other by a single-circuit high-power power transmission line, such as a 750 kV power line between Moscow and Leningrad, shows that such power transmission lines equipped with modern automatic control systems have a fairly high level of functional reliability and practically do not cause any complicated problems.

The electric power systems, sonx, are intended to be connected to each other, also have a reserve power, which can be used for repairs or when the high-power power transmission line is damaged.

In order to increase functional reliability, it is possible in individual cases to build two parallel-connected electric power transmission lines according to the invention, the manufacturing cost of which will in any case be lower than that of the known conventional electric power transmission line for the same voltage and with the same sum power. 453 704 48 When the conventional electric power transmission lines are replaced with the transmission lines according to the invention, these thus undoubtedly provide economic advantages.

If the electric power transmission line according to the invention is compared with the known six-phase transmission line described above for a voltage of 462 kV, the following results can be stated.

The total cross-sectional area of the part of aluminum in each split phase of the six-phase transmission line is almost 4,900 mmz, ie twice as large compared to the electric power transmission line according to the invention for 500 kV with ten conductors, whose part of aluminum has a cross-sectional area of 240 mm2. It appears from this that the power of the electric power transmission line 2 of the conductor according to the invention, which is to be transmitted per mm cross-sectional area, after voltage equalization is 1.08 * thousand kW / mmz, while that of the six-phase transmission line is approximately 0.68 thousand kW / mmz, i.e. with 60% lower. Because the electric power transmission line according to the invention is of the three-phase type, it is usually installed at. voltage-increasing and voltage-lowering substations on such an overhead line are switched-off mains transformers with a phase shift of 120 electrical degrees, while for the known six-phase transmission line considerably more expensive transformers usable in rectifier technology are required. The electric power transmission line according to the invention is thus, economically speaking, more advantageous than the known six-phase transmission line.

The other important advantages of the electric power transmission line according to the invention are manifested when this is used in a common electric power system.

The electric power transmission lines according to the invention for relatively low voltage can in many cases, while ensuring the desired natural effect, replace electric power transmission lines for higher (with 1-2 s 1 <voltage levels) voltage. This makes it possible to postpone the construction of electric power transmission lines for higher voltage for a long time, regardless of a continuous increase in the power of electric power systems.

In the Soviet Union, the following so-called voltage levels are used: 220-500-1150 kV and 150-330-750 kV. The same or nearly 453,704 49 same voltage levels were used in all countries around the world. Based on all the considerations, it can be stated that instead of building a first electric power transmission line for 750 kV with the electric power system, the electric power transmission line according to the invention can be built with the same natural effect but for a voltage of 330 kV. At the same natural effect, instead of the electric power transmission lines of the conventional type for a voltage of 500 or 1150 kV, the electric power transmission lines according to the invention can be used for a voltage of 220 kV and 500 kV, respectively.

In accordance with a project, the Soviet Union intends to build a single-circuit power transmission line of conventional design and with conventional parameters, for a voltage of 1150 kV, which transmission line is intended to transmit 4 million kW over a distance of almost 1,100 km using a single intermediate substation for 1,150 / 500 kV. The calculations performed have shown that in this case it is more economical to build the single-circuit power transmission line according to the invention for a voltage of 500 kV. Although the actual power transmission line according to the invention for 500 kV will be somewhat more expensive to build and entails higher losses of fairly expensive electricity, the manufacturing cost for three substations for 500 kV is considerably lower than that for three substations for 1,150 / 500 kV. This results in the entire power transmission line according to the invention proving to be more profitable not only in terms of investment costs but also in accordance with the economic criterion useful in the Soviet Union, which takes into account both investment costs and annual expenses, ie in accordance with the minimum "reduced" or "estimated" costs P: P = E + 0,15 K (14), where E is the annual cost of the power transmission line according to the invention, which includes the cost of energy losses and amortization deductions from the manufacturing cost of the power transmission line and substations, and K the costs of electricity transmission line. 453 704 50 In cases where, on the basis of the energy considerations, an electric power transmission line can be built for a lower voltage, selected from the entire voltage scale usable in the Soviet Union 150-220-330-500-750-1 150 kV, it is it is almost always advantageous to build the electric power transmission line according to the invention instead of the known conventional electric power transmission line for the next, higher voltage level, if the length of the electric power transmission line corresponds to the voltage level of the line. The construction of this transmission line is more advantageous, the higher the power to be transmitted over the electric transmission line. In some cases, the electric transmission line which is being built and which is intended to connect two electric power systems to each other must normally operate in the operating state at which it transmits it. power, which is lower than its natural power, whereby the natural power of this transmission line is only utilized when the power of the receiving electric power system falls through dangerous operating conditions. Under the dangerous operating conditions, it is permissible for the power transmission lines - because of the dangerous operating conditions. are short-lived - are loaded with a higher current than with the economic current density. These events are also favorable for the electric power transmission line according to the invention to be used.

The single-circuit three-phase transmission overhead line according to the invention eliminates, as already stated above, the limitations with regard to the power to be transmitted which were hitherto considered to be unavoidable for alternating current. Such electric power transmission lines can therefore in a number of cases be used instead of direct current transmission lines for high voltage. In addition, it is taken into account in this case that the bandwidth required for the electric power transmission lines according to the invention does not exceed and in some cases is less than that required for the direct current transmission overhead lines.

The electric power transmission line according to the invention further makes it possible in a number of cases to simplify transitions over water areas, since transition support brackets with a high height at this transmission line are cheaper to manufacture. The path width of the electric power transmission line according to the invention is, as already stated above, considerably smaller than that required for the conventional known electric power transmission lines of this kind. If the electric power transmission line according to the invention is intended to replace a few circuits for the conventional electric power transmission lines at the same natural power and voltage, the path width of the electric power transmission line according to the invention will be 4-10 times less than the total bandwidth of all the circuits of the conventional electric power transmission line. , which makes it possible to significantly reduce the ground area required for the power transmission line. In countries where the land value of areas for laying power transmission lines is high and sometimes comparable to the manufacturing cost of the power transmission line itself, the use of the power transmission lines according to the invention becomes particularly advantageous and topical, giving a considerable saving. In cases where the bandwidth is limited by certain conditions, the construction of the electric power transmission line according to the invention may be the only acceptable, technical solution.

The electric power transmission line according to the invention helps to significantly reduce the undesirable ecological impact exerted by electric power transmission lines for very high and extremely high voltages and which is expressed in the fact that the electric field strength occurring under the transmission line is very high, which creates an unpleasant zone for humans and animals. The favorable properties of the electric power transmission line according to the invention are manifested in this respect from three points of view.

First, the electric field strength under the electric power transmission line is kept at a low permissible level, whereby for the electric power transmission line according to the invention for a voltage of for example 500 kV with vertically located contours for the split phases is the field strength / level 9 m. The electric field strength occurring at the conductors is limited by a permissible value (the effective value is 21.1 kV / cm), while the losses caused by corona discharge are 14 kw / km, which ensures permissible radio interference and noise levels.

Secondly, the reduced path width of the transmission line according to the invention contributes to substantially reducing the surface of the part of the transmission line path where the highest possible electric field strength occurs below the conductors. This area is limited by the narrow. part in the center area for the span of the transmission line, which has a width of, for example, 7 m and which in extreme emergencies can be protected by means of ropes arranged on light support means or fenced.

Thirdly, the voltage reduction from, for example, 1,150 kV to 750 kV or even up to 500 kV means that the transmission line for very high or extremely high voltage can be replaced by an electric power transmission line for high voltage, whose impact on the environment is considerably weaker and not causes some problems.

Finally, it should be emphasized once again that the three-phase power transmission overhead line consisting of a single circuit with split phases according to the invention, where between the split phases there is a slightly non-uniform electric field acting along the entire length, makes it possible to combine the split the phases to as short a distance between them as possible, so that the transmission line according to the invention has the most compact dimensions and the highest possible transmission capacity, which are considered to be the limit dimensions and the limit transmission capacity, which are typical of electric power transmission overhead lines.

Claims (20)

453 704 53 P a t e n t k r a v A three-phase transmission overhead line with split phases (1, 2, 3), which comprises on the one hand conductors (Ä), which are attached to spacers (5) of metal, which are arranged to form a cross-contour in a plane perpendicular to the center line of the electric power transmission line. for the split phases, on the one hand support brackets (8), the elements of which are arranged outside the space occupied by the phases and the air gaps therebetween, and on the other hand insulators (7), which are intended to fasten the phases of the electric power transmission line to its support brackets , the electric field appearing in the majority of the spaces between the phases of the transmission line being slightly uneven, characterized in that the distances (S) between the adjacent phases (1, 2, 3) which are suspended in the support trestles (8 ) by means of the insulators (7), seen in the cross section of the electric power transmission line, are at least along the greater part of the length of the phases equal, while the conductors (H) in at least one phase of the electric power transmission line the conductors are separated from each other by different distances, whereby the conductors receive equal amounts of electric charges, while the electric field generated by said placement of the phases and the conductors becomes slightly uneven in the whole volume of the gaps between the phases, in which field electrical flashover over the gaps between the phases can only occur in a streamer-like shape, when overvoltages occurring over the power transmission line exceed the permissible ones. 2. A line as claimed in Claim 1, characterized in that the split phases (1, 2, 3) of the electric power transmission line are separated from each other by such a distance (S), at which the electric, occurring between the split phases at the operating voltage, the field strength varies between 1.65 kV / cm, at a maximum so-called overvoltage ratio across the transmission line and 3.15 kV / cm, at a minimum overvoltage ratio across the line. 3. A line as claimed in Claim 1 or 2, characterized in that all the contours along which the conductors (U) in the split É phases (1, 2, 3) are arranged in the cross section of the power transmission line are closed. 4. A conductor according to claim 5, characterized in that the number of conductors (H) in the lower half of the contour for at least one. outer split phase is larger than that in the upper half of the contour of this phase. 4ss_7n4 54 5. A line according to claim 3 or U, characterized in that the conductors (U) in the split phases are, seen in the cross section of the power transmission line, distributed along concentric circles. Line according to Claim 5, characterized in that the conductors (H) in one (3) of the split phases are divided into equal parts into two half-phases (Ba, Bb), the contour of each half-phase, seen in the cross section of the electric power transmission line, being of a circle, which is located concentrically inside the circle, along which one of the two other split phases (1, 2) is arranged. Line according to Claim 1 or 2, characterized in that one of the contours, along which the conductors (Ä) in the split phases are distributed, seen in the cross section of the power transmission line, is closed, while the other contours are open and partially enclose the first the contour. Cable according to claim 7, characterized in that the distance between the conductors in the center part of the contour of at least one open outer phase is shorter than that in the outer parts of the contour for this phase. Line according to Claim 7 or 8, characterized in that the contour of the highest split phase, seen in the cross section of the transmission line, has the shape of an oval, while the contours of the underlying split phases consist of open curves which are convex downwards. . 10. A line as claimed in Claim 1 or 2, characterized in that all the contours along which the conductors in the split phases are distributed in the cross section of the electric power transmission line are open. 11. A conduit according to claim 10, characterized in that the conductors in the center parts of the contours of the split phases are spaced apart by a greater distance than the conductors in the outer parts of the contours. Line according to Claim 10 or 11, characterized in that the contours of all the split phases, seen in the cross section of the transmission line, consist of open curves which are convex downwards. 13. A line according to claim 10 or 11, characterized in that the contours of all the split phases, seen in the cross section of the power transmission line, are mainly located vertically, the edges of those on either side of The phases located in an intermediate phase are bent in opposite directions relative to the split intermediate phase, while at the edges of the intermediate phase there are conductors which are distributed along lines (22) which, seen in the cross section of the electric power transmission line, are perpendicular to the the turn for the most part of this split phase. k e n n e t e c k - that the contours of the split phases, seen in A line according to claim 10 or 11, n a d a v the cross-section of the transmission line, consists essentially of straight lines. Line according to Claim 1U, characterized in that the contours of all the split phases, which mainly consist of straight lines, are located horizontally. A line according to claim 1N, characterized in that the contours of all the split phases, which have the shape of straight lines, are located vertically. Line according to one of Claims 13 to 16, in that the length (L) of the contour of the split intermediate phase is shorter than that of the contours of the phases lying on either side thereof. Cable according to Claim 13 or 16, characterized in that the lower ends of the split phases are fastened by means of insulators (23) to a further lower cross beam (2U), to which the support bracket (8) is provided. 19. A conduit according to claim 5, characterized in that the split phases are attached by means of insulators to the upper ends of intermediate support brackets, which, each, comprise a V-shaped leg (8), which is hingedly connected to a base part, which is made up of three inclined legs (28), which, seen in a plan view, diverge from a common center at an angle of 1200 and whose lower ends are supported by foundation plates (29), the upper ends of the V-shaped leg being connected to to each other by means of a flexible connecting link (11) and to the lower ends of the inclined legs of the base part, which are connected to each other by means of a second common flexible connecting link (30), which is guided so that it can be tensioned from a single point. Cable according to claim 5 or 9, characterized in that each end, anchoring and corner support bracket comprises at least one three-legged portal (31, 32, 33) with crossbeams (BH), characterized in - š 4ss_7o4 56 struts (39) and rigid connecting means (37, 38), while the conductors in each split phase by means of insulators (H0) are alternately attached to the struts and crossbeams of each part of the portal, starting from the phase conductors distributed along the curve with the largest diameter.