RU141376U1 - DEVICE FOR THREAD PROTECTION OF CURRENT CONDUCTING STRUCTURES (OPTIONS) - Google Patents

Abstract

1. The apparatus for lightning protection of conductive structures, containing the main electrode in the form of a metal rod, covered along the length of the insulating sheath of a polymer dielectric material, and additional electrodes located in series or offset in the circumferential direction on the insulating sheath along this sheath and at a distance from each other and also means for attaching the main electrode with an insulating sheath carrying additional electrodes to the conductive structure, characterized in that the attachment means is made of metal and has an element of engagement with the conductive element of the conductive structure and with sockets for fixing the ends of the arcuate bent metal rod to each other to form a common contact conductive node, additional electrodes on the insulating shell are located on a part of its length from the side of one of the ends of the metal rod, and on the other part of the insulating sheath is placed an intermediate electrode in the form of a metal sheath covering the oh sleeve or fixed to the shell plate, the area of which the outer surface is greater than the area of any one extra electrode on the insulating sheath portion, in which additional electrodes are located distantly from smescheniem.2 or sequentially. An apparatus for lightning protection of conductive structures, containing the main electrode in the form of a metal rod, covered along the length of the insulating sheath of a polymer dielectric material, and additional electrodes located in series with

Description

The utility model relates to down conductors for protection against lightning overvoltages of electrical equipment and various structures and structures, for example, high-voltage installations, insulators and other elements of high-voltage power lines, electrical equipment, as well as structural elements of other structures and devices requiring lightning protection.

A current-conducting device for lightning protection of fairings of aircraft radars is known according to the patent. This device also contains a strip of solid dielectric, which performs the function of an insulating body, with which many electrodes are located mechanically connected (by installing on it), located with mutual displacement along the longitudinal axis of the insulating body. The two outermost electrodes serve as the main electrodes, and the rest, located between them, the electrodes are intermediate electrodes (US 4506311, H05F 3/00, publ. 19.03.85).

When lightning strikes the specified device, spark gaps between the electrodes overlap and the lightning current flows through the formed channel to the metal body of the aircraft, bypassing the fairing and the electrical equipment located underneath. To reduce the discharge voltage in the analog device, rhomboid-shaped electrodes oriented vertices to each other are used; The uneven arrangement of the intermediate electrodes along the insulating body serves the same purpose. By dividing the interval between the main electrodes into many spark gaps, this downstream device has a higher arc suppression ability than devices with one or with a small number of discharge gaps. However, the discharge voltages in the known device are too high, which limits its scope only to the protection of aircraft radars . It cannot be used, for example, as a collector to protect power transmission elements from overvoltage.

These application restrictions are permitted in the known down conductor device for lightning protection of electrical components, power lines, structures or structures containing an insulating body made of a solid dielectric, at least two main electrodes mechanically connected to the insulating body, and m intermediate electrodes located on the insulating body between the main electrodes with mutual displacement, at least along the longitudinal axis of the insulating body, while inside the insulating body an additional rod electrode is installed along its axis, electrically connected to one of the main electrodes and located opposite at least one of the intermediate electrodes, the thickness Δ _{i of the} insulation body layer between the additional electrode electrically connected to the main electrode and the i-th intermediate the electrode must be more than the value obtained by dividing the discharge voltage U _{p, i} between the i-th intermediate electrode and the main electrode is electrically connected with an additional electron Odom, on the breakdown voltage E _pr insulating material of the insulating body holds (RU 2299508, H02H 3/22, H01T 4/02, publ. 08/10/2006).

This known current collector is used for power line elements requiring protection, while for such lines one main electrode is connected directly or through the spark gap to the protected power line element, and the other main electrode is connected directly or through the spark gap to the ground.

The disadvantage of this known solution is that the design of this collector is used as an element of communication between the power line and the ground, and therefore it is structurally designed as a conductor operating at high voltages. This device is suspended and hangs almost vertically. Its peculiarity is that it has two main electrodes, which must be in electrical communication with the reception line and the electric energy removal line. In practice, this is not always possible and not always justified from the standpoint of the safety of people who may be at an unfavorable moment near the arrester. Preferred is the exclusion of conductive circuits, closed to the ground, in areas where the appearance of people.

In addition, the structurally known solution is difficult, since each main electrode of this should have both means of attaching to the conductive element of the power line and a means of current reception (contact node), which is not described in the patent, but in practice these nodes provide positioning of the arrester and its functioning.

Technologically, the best solution is to make an insulating shell with a metal rod partially inserted into it along its length. That is, it is practically possible, for example, by casting or pouring a rod in the form of a molten polymer. But these operations are laborious and cost-effective only in mass production. For small volumes of products, the use of injection technology requires appropriate equipment and accessories, which increases the cost of the product itself.

This utility model is aimed at achieving a technical result, which consists in improving manufacturability and simplifying the design.

The specified technical result is achieved by the fact that in the apparatus for lightning protection of conductive structures containing a main electrode in the form of a metal rod, covered along the length of the insulating sheath of polymer dielectric material, and additional electrodes arranged in series or offset in the circumferential direction on the insulating sheath along this sheath and at a distance from each other, as well as a means of attaching the main electrode with a sheath carrying additional electrodes to the current lead of the leading structure, the attachment means is made of metal and has an element of engagement with the conductive element of the conductive structure and with sockets for fastening the ends of the arcuate bent metal rod to each other to form a common contact conductive node, additional electrodes on the insulating shell are located on part of its length on the side of one from the ends of the metal rod, and on the other part of the insulating shell an additional electrode is placed in the form of a female a shell of a metal sleeve or a plate fixed to the shell, the area of which on the outer surface is greater than the area of any one additional electrode on the part of the insulating shell on which the additional electrodes are distantly sequentially or offset.

The specified technical result is also achieved by the fact that in the apparatus for lightning protection of conductive structures containing the main electrode in the form of a metal rod, covered along the length of the insulating sheath of a polymer dielectric material, and additional electrodes located sequentially on the insulating sheath along this sheath and at a distance of from each other, as well as means for attaching the main electrode with a sheath carrying additional electrodes to a conductive structure, characterized in that the attachment means is made of metal and has an engagement element with a conductive element of the conductive structure and with sockets for fixing the ends of the arcuate bent metal rod to each other to form a common contact conductive node, additional electrodes on the insulating shell are located on the part of its length on the side of one from the ends of the metal rod and each is made in the form of a plate with opposed ears, one of which, when covering the insulation This shell is inserted into the hole on the other eye and bent to form a ring-shaped additional electrode, and on the other part of the insulating shell an intermediate electrode is placed in the form of a metal sleeve covering the shell, the area of which on the outer surface is larger than the area of any one additional ring-shaped electrode on the part of the insulating shell on which the additional electrodes are arranged in series, or in the form of covering at least two sequentially spaced spaced apart metal sleeves, each of which area of the outer surface greater than the area of any one of the additional electrode to form an annular portion of the insulating sheath, additional electrodes which are arranged in succession ...

The specified technical result is also achieved by the fact that in the apparatus for lightning protection of conductive structures containing the first electrode in the form of a metal rod, covered along the length of the insulating sheath of polymer dielectric material, and the second electrode, made in the form of a set of separate electrodes arranged in series on the insulating sheath along this shell and at a distance from each other, as well as the attachment site of the electrodes to the conductive structure, the attachment site is metallic and with sockets for fixing the ends of an arcuately bent metal rod to each other to form a common contact conductive unit, the individual electrodes forming a second electrode on the insulating shell are made annular to cover the insulating shell and are located on part of the length of this shell on the side of one of ends of the metal rod, and on the other part of the insulating shell an additional electrode is placed in the form of a metal tubular element covering the shell, flat whose area on the outer surface is larger than the area of any one additional electrode on the part of the insulating shell on which the second electrode is placed, or in the form of at least two metal bushings spanning at least two consecutively spaced apart from each other, the area of each of which on the outer surface is larger than the area any one additional ring-shaped electrode on the part of the insulating shell on which the additional electrodes are arranged in series.

The specified technical result is also achieved by the fact that in the apparatus for lightning protection of conductive structures containing the first electrode in the form of a metal rod, covered along the length of the insulating sheath of polymer dielectric material, and the second electrode, made in the form of a set of separate electrodes arranged in series on the insulating sheath along this shell and at a distance from each other, as well as the site of attachment of the electrodes to the conductive structure, the metal rod is made of a heap of sequentially arranged parts placed in a shell with an air gap between opposite ends of the rod parts, the attachment unit is made of metal and with sockets for fixing the ends of the arcuately bent metal rod brought out from the shell to form a common contact conducting assembly, separate electrodes forming the second electrode on the insulating shell, are made annular to cover the insulating shell and are located on a part of the length This sheath is on the side of one of the ends of the metal rod, and on the other part of the insulating sheath there is an additional electrode in the form of a sheath covering the air gap of the metal tubular element, the outer surface area of which is larger than the area of any one additional electrode on the part of the insulating sheath, by which is placed the second electrode, or in the form of covering the shell in the presence of an air gap of at least two sequentially spaced apart metal sleeves, each of which area of the outer surface greater than the area of any one of the additional electrode to form an annular portion of the insulating sheath, additional electrodes which are arranged in series.

The specified technical result is also achieved by the fact that in the apparatus for lightning protection of conductive structures containing the first electrode in the form of a metal rod, covered along the length of the insulating sheath of polymer dielectric material, and the second electrode, made in the form of a set of separate electrodes arranged in series on the insulating sheath along this shell and at a distance from each other, as well as the attachment site of the electrodes to the conductive structure, the attachment site is metallic and with adjacent sockets, in one of which one end of the metal rod is fixed to form a contact conductive node, and in the other, isolated from the contact conductive node, the other end of the arcuate bent metal rod is fixed, the individual electrodes forming the second electrode on the insulating shell are made ring forms for covering the insulating shell and are located on part of the length of this shell on the side of one of the ends of the metal rod, and on the other part of the insulation the second shell, an additional electrode is placed in the form of a metallic tubular element enclosing the shell, the area of which on the outer surface is greater than the area of any one additional electrode on the part of the insulating shell on which the second electrode is placed, or in the form of at least two consecutively spaced apart from each other other metal bushings, the area of each of which on the outer surface is greater than the area of any one additional ring-shaped electrode for h STI insulation shell in which additional electrodes are arranged in series.

The present utility model is illustrated by a specific example of execution, which, however, is not the only possible one, but clearly demonstrates the possibility of achieving the required technical result.

In FIG. 1 shows a General view of the apparatus for lightning protection of conductive structures;

FIG. 2 - shows an additional electrode, the workpiece in plan;

FIG. 3 - shows the fixing of the additional electrode on the insulating sheath.

In the framework of this utility model, the problem of creating a reliable and low-cost in the production and operation of a collector for lightning protection of conductive structures, characterized by low discharge voltages, is solved. The utility model can be used to solve a wide range of problems, and, first of all, not only for effective removal of lightning current when protecting electrical equipment from direct lightning strikes, but also as a thunderstorm current collector capable of extinguishing the accompanying current arc at large values of this actually encountered in practice current.

According to the present utility model, the apparatus for lightning protection of conductive structures (Fig. 1) contains a main electrode in the form of a metal rod 1, covered along the length of the insulating sheath 2 of a polymer dielectric material (for example, polyethylene). The apparatus has additional electrodes 3 located in series or offset in the circumferential direction on the insulating sheath 2 along this sheath and at a distance from each other. The optimal number of additional electrodes 3 is selected taking into account the specific form of their implementation, the calculated value of the overvoltage and other conditions of their work. This design is fixed to the attachment means 4 (attachment unit) of the main electrode with an insulating sheath carrying additional electrodes to the conductive structure (not shown).

A feature of the apparatus is that the attachment means 4 is made of metal (conductive) and is simultaneously a common contact conductive node. For this, the attachment means has an engagement element 5 (hook, clamp, etc.) with the conductive element of the conductive structure and with sockets 6 for fixing the ends 7 of the arcuate bent metal rod 1 connected to each other.

Technologically get such a part as a metal rod in an insulating shell as follows. A part of the required length is cut from a cable already having an insulating sheath of polymer dielectric material and wires are removed from it. Thus, an insulating sheath 2 is obtained. Then a metal rod 1 is introduced into the sheath 1. The metal rod can be introduced by mechanical force penetration (pushing) of the rod into the sheath (taking into account the elasticity of the sheath wall material) until its end leaves the sheath. Or, the introduction of a metal rod can be carried out by heating the shell material to the state of the onset of plastic deformation, and in this state of the shell a rod is introduced into its cavity. Then the shell cools down and tightly covers the core. Lugs are welded to the ends of the rod or lugs are fixed at their ends and a metal cup 8 is put on top of each lug, partially covering the shell in the area where the rod exits the shell partially covering the lower edge of the side wall. Then the glasses are fixed in the sockets 6 of the metal fastening means.

The fastening means 4 itself is made of metal (conductive) and has an engagement element 5, by which the apparatus is suspended, for example, on a power line. All elements of the fastening means are made of metal and in this regard, the fastening means 4 is a conductive contact node, through which the surge voltage from the conductive element of the power line is supplied to a capacitor system formed on a metal ring rod.

The capacitor system is formed due to the presence of additional electrodes 3 on the insulating shell 2, located on part of its length from the side of one of the ends of the metal rod. Each additional electrode 3. in the General case, is a metal plate of round or rectangular or other shape, which in any known manner is fixed to the outer surface of the insulating shell. For example, such a plate can be mechanically fixed to the shell, or glued to it or thermally embedded in the body of the shell with the conclusion of the outer surface of the plate open to the outside. In the framework of this utility model, each additional electrode 3 (Figs. 2 and 3) can be made in the form of a metal plate 9 with opposite ears 10, one of which, when covering the insulating sheath, is inserted into the hole 11 on the other eye and bent (pos. 12 ) to form a ring shape of the additional electrode. This design of the electrodes for a set of additional electrodes is technologically advanced, since it can significantly reduce the time required to install these electrodes on the shell, adjust the degree of connection of these electrodes with the shell by changing the degree of tightening of the ears, and repair and replace damaged electrodes without disassembling the entire apparatus (these operations at the place of suspension of the device), as well as adjust the distance between the electrodes.

Due to the implementation of the additional electrodes 3 in the form of rings, their capacitance on the rod 1 increases and, thereby, enhances the effect of the cascade of operation of the collector, i.e. its discharge voltages necessary for the breakdown of interelectrode gaps are reduced. Studies have shown that for the extinction of the arc, it is important that its individual sections (arches), which are formed due to the use of additional electrodes in the form of rings, are located as far as possible from each other. With this mutual arrangement of the arc sections, it is difficult to form a single arc channel when it is inflated during the flow of current and, therefore, the extinction of the arc is facilitated.

This set of individual electrodes 3 arranged in series on the insulating sheath along this sheath and at a distance from each other essentially forms a second electrode. Together, the metal rod and the set of individual electrodes 3 form a capacitor system, in which the distantly located additional electrodes 3 in a set of each other also form their own capacitor system. Separate additional electrodes 3 do not have direct (direct) electrical connection with the fastening means 4, communication is carried out indirectly through the air.

In this regard, the apparatus for lightning protection of conductive structures can be considered as containing the first electrode in the form of a metal rod, inside an insulating sheath of polymer dielectric material and the second electrode in the form of a set of separate ring-shaped metal electrodes located in series on the insulating sheath along this sheath and at a distance from each other, as well as the attachment unit in the form of a single conductive structure with sockets for fixing the ends connected to each other in an arcuately bent metal rod and the formation of part of the length of the shell from the side of one of the ends of the metal rod of a capacitor system with a ring-shaped metal electrodes.

Additional electrodes 3 on the insulating sheath are located on a part of its length on the side of one of the ends of the metal rod (Fig. 1), and on the other part of the insulating sheath there is an intermediate electrode 13 (another additional electrode not included in the set of additional electrodes 3). This intermediate electrode 13 can be made in the form of a metal sleeve covering the shell or mounted on the shell of a plate or tubular element or a set of tubular elements. The main thing is that the area of the intermediate electrode 13 on the outer surface is larger than the area of any one additional electrode 3 on the part of the insulating shell on which the additional electrodes are located distantly in series or with offset. This intermediate electrode 13 can be made by analogy with the design of the additional electrode of FIG. 2 and 3.

When protecting high-voltage installations or power lines, the device is connected by means of a suspension to a high-voltage power transmission element, for example, a wire (directly or through a spark discharge gap).

Lightning surge protection when using the described device is based on the following principle. When lightning strikes the power line, a pulse closure of the nearest insulator or insulation gap occurs. In case of overvoltage after a pulsed isolation overlap has occurred, either a further development of an electric discharge is possible with a transition to a working arc of the operating voltage, which means a short circuit of the line, or restoration of the dielectric strength after a lightning current flows through the discharge channel and support to the ground and normal mode of operation of the line without disconnecting it. The probability of a power arc mainly depends on the rated line voltage U _nom and the length of the overlap path L. For a given nominal voltage U _{nom, the} probability of establishing a power arc P _{d is} approximately inversely proportional to the length of the overlap L: P _d = 1 / L. By increasing L, it is possible to reduce the likelihood of an arc by the same amount and, accordingly, reduce the number of line cuts.

In this regard, the apparatus according to the present utility model provides the possibility of creating a sufficiently long path of spark overlay by using the effect of a surface discharge over the surface of the dielectric. The length of the path of the sparking over the surface of the pulse lightning arrester should be greater than the length of the path of the sparking overcoming of the protected line element.

The resulting overvoltage is applied between the electrode in the form of a rod 1 and an additional electrode 13. The presence of the rod 1 sharply increases the field strength near the electrode 13. The greatest field strength is achieved at the edge of the electrode 13 due to the manifestation of the edge effect. As a result, at relatively low values of the acting overvoltage in the air near the edge of the electrode 13, a sliding discharge channel is formed, which is fed by a capacitive current and slides toward the end electrode. When overvoltages are slightly higher than the operating voltage of the apparatus, the discharge channel is usually formed on one side of the ends of the rod 1. At significant overvoltages, the discharge channel develops in both directions, i.e. to the ends of the rod 1. As you know, the discharge voltage of the sliding discharge is very low, ie with a relatively small magnitude of the acting overvoltage pulse, a very large path along the dielectric surface is blocked. The parameters of the device are selected so that it operates at a lower voltage than the discharge voltage of the protected element, and the length of the overlap path was significantly greater than the length of the overlap path of the protected element. By increasing the length of the overlap, the establishment of a power arc of industrial frequency is excluded and there is no need to turn off the power transmission.

From the circuit diagram of the apparatus of FIG. 1 it is clear that in case of exposure to an overvoltage pulse (corresponding to voltage U), a spark discharge gap first breaks between the high-voltage wire of the protected power transmission and the fastening means 4, and then the discharge develops from the fastening means 4 towards the additional electrode 13, sequentially punching the gaps between additional electrodes 3. Between the electrodes (rod 1) and the additional electrode 3 there is a capacitance C ₁ , and between the electrodes 3 there is a capacitance C ₀ . These capacitances are connected in series, and when exposed to an overvoltage pulse, voltage U is applied to them. Voltage U ₁ on capacitances C ₁ , i.e. the voltage at the spark gap between the rod 1 and the additional electrode 3 nearest to it, in relative units, is determined by the formula: U ₁ / U = 1 / 1- (C ₁ / C ₀ ) / Due to the relatively large surface area of the additional electrodes 3, and due to the fact that the dielectric constant of a solid dielectric ε is much higher than the dielectric constant of air ε ₀ (usually ε / ε ₀ ≈ 2 ÷ 3), the capacity of the intermediate electrode 3 to the additional electrode 13 is significantly larger than its capacity to the rod 1 2, t .e. C ₀ > C ₁ and, accordingly, C ₁ / C ₀ <1. When the values of the ratio C ₁ / C ₀ lying in the range C ₁ / C ₀ = 0.1 ÷ 0.9, the voltage U ₁ is in the range U ₁ = (0.53 ÷ 0.91) U. Therefore, when the voltage U is applied to the apparatus, the main part of the voltage drop falls on the first spark gap between the rod 1 and the electrode 3. Under the action of this voltage U _1, this gap breaks through, and the first additional electrode 3 acquires the potential of the rod 1, and the next, adjacent to the first additional electrode acquires the potential U ₀ . Further, the physical picture of the breakdown of the spark gap is repeated. Thus, cascading, i.e. successive overlapping of the gaps between the additional electrodes 3 with the formation of an arc discharge (arc). Due to the cascade of operation of the discharge gaps, the required low discharge voltage of the operation of the collector is provided.

Under the influence of overvoltage U on the apparatus, breakdown of solid insulation between the additional electrodes 3 and the rod 1 is not permissible it is necessary that the discharge between electrodes 1 and 13 develops, passing only through additional electrodes 3 and through the air spark gaps. Thus, the discharge voltage of the collector (spark gaps located on its surface) should be less than the breakdown voltage of the insulating sheath.

Additional electrodes 3 can be located on the shell 2 sequentially at a distance from each other and in a straight line. But a variant is possible in which additional electrodes 3 are arranged on the shell in a spiral (displacement in the circumferential direction). This arrangement makes it possible to place a larger number of additional electrodes 3 on the collector than in the embodiment of FIG. 1, and thereby further improve the arc suppression ability of the collector by increasing the number of gaps into which the arc is divided. Thus, it is possible to further increase the arc suppression ability of the collector.

Since the extinction of the spark discharge directly depends on the number of punched air gaps, in the claimed apparatus, it is possible to enhance its extinction property due to the formation of additional capacitor systems. An embodiment is possible when the metal rod 1 is made of two successive parts 14 and 15 located in the shell 2 with an air gap 16 between the ends of the rod parts located opposite each other. Thus, the rod 1 becomes a capacitor. The enhancement of the effect can also be achieved by performing an electrode 13 composed of two or more parts 17 - two metal sleeves successively located at a distance from each other, - the area of each of them on the outer surface is larger than the area of any one additional ring-shaped electrode on the part of the insulating shell, which additional electrodes are arranged in series. These parts 17 also form a capacitor system. These improvements are implemented on the previously described apparatus design without changing other nodes.

An example of execution is possible, according to which the metal rod 1 at one end is not connected by a conductive contact node (fastening means 4). That is, one end of the metal rod 1 is located in the socket in the mounting means 4, but is made isolated from this means. Such a device for lightning protection of conductive structures contains a first electrode in the form of a metal rod, covered along the length of the insulating sheath of polymer dielectric material, and a second electrode made in the form of a set of separate electrodes arranged in series on the insulating sheath along this sheath and at a distance from each other. The unit of attachment of the apparatus to the power line is made of metal and with adjacent sockets, in one of which one end of the metal rod is fixed to form a contact conductive node, and in the other, isolated from the contact conductive node, the other end of the arcuate bent metal rod is fixed. The design of the rest of the apparatus may repeat any of the considered examples of execution.

The utility model is industrially applicable in all areas of high-voltage technology related to power transmission. The design of the device provides for the possibility of its manufacture in both small-scale and mass production, since it is a high-tech device.

Claims (5)

1. The apparatus for lightning protection of conductive structures, containing the main electrode in the form of a metal rod, covered along the length of the insulating sheath of a polymer dielectric material, and additional electrodes located in series or offset in the circumferential direction on the insulating sheath along this sheath and at a distance from each other and also means for attaching the main electrode with an insulating sheath carrying additional electrodes to the conductive structure, characterized in that the attachment means is made of metal and has an element of engagement with the conductive element of the conductive structure and with sockets for fastening the ends of the arcuately bent metal rod to each other to form a common contact conductive node, additional electrodes on the insulating shell are located on part of its length from the side of one of the ends of the metal rod, and on the other part of the insulating shell an intermediate electrode is placed in the form of a metallic oh sleeve or fixed to the shell plate, the area of the outer surface greater than the area of any one extra electrode on the insulating sheath portion, in which additional electrodes are located distantly sequentially or offset. 2. An apparatus for lightning protection of conductive structures, containing a main electrode in the form of a metal rod, covered along the length of the insulating sheath of a polymer dielectric material, and additional electrodes located sequentially on the insulating sheath along this sheath and at a distance from each other, as well as means for attaching the main an electrode with an insulating sheath carrying additional electrodes to the conductive structure, characterized in that the attachment means is made of metal and it has an element of engagement with the conductive element of the conductive structure and with sockets for fixing the ends of the arcuate bent metal rod to each other to form a common contact conductive node, additional electrodes on the insulating shell are located on a part of its length from one of the ends of the metal rod and are made each in the form of a metal plate with opposed ears, one of which is inserted into the hole when covering the insulating sheath on the other ear and bent to form a ring shape of the additional electrode, and on the other part of the insulating shell there is an intermediate electrode in the form of one metal sleeve covering the shell, the area of which on the outer surface is larger than the area of any one additional ring-shaped electrode on the part of the insulating shell, on which the electrodes are arranged in series, or in the form of covering at least two sequentially spaced at a distance from each other m -metallic bushings, each having an area on the outer surface greater than the area of any one of the additional electrode to form an annular portion of the insulating sheath, additional electrodes which are arranged in series. 3. The apparatus for lightning protection of conductive structures, containing the first electrode in the form of a metal rod, covered along the length of the insulating sheath of polymer dielectric material, and a second electrode made in the form of a set of separate electrodes arranged in series on the insulating sheath along this sheath and at a distance from each other friend, as well as the site of attachment of the electrodes to the conductive structure, characterized in that the site of attachment is made of metal and with sockets for fixing the ends of the arcuate bent metal rod to form a common contact conductive node, the individual electrodes forming the second electrode on the insulating shell are made ring-shaped to cover the insulating shell and are located on part of the length of this shell on the side of one of the ends of the metal rod, and another part of the insulating shell is placed an additional electrode in the form of a metal tubular element covering the shell, the area of which is on the outer surface greater than the area of any one additional electrode on the part of the insulating shell on which the second electrode is placed, or in the form of at least two metal sleeves sequentially spaced from each other, each of which on the outer surface is larger than the area of any one additional ring electrode forms on the part of the insulating shell on which the additional electrodes are arranged in series. 4. The apparatus for lightning protection of conductive structures, containing the first electrode in the form of a metal rod, covered along the length of the insulating shell of a polymer dielectric material, and a second electrode made in the form of a set of separate electrodes arranged in series on the insulating shell along this shell and at a distance from each other friend, as well as the node attaching the electrodes to the conductive structure, characterized in that the metal rod is made of two sequentially arranged parts d, placed in a shell with an air gap between opposite ends of the rod parts, the attachment unit is made of metal and with sockets for fixing the ends of the arcuately bent metal rod brought out from the shell to form a common contact conducting assembly, separate electrodes forming a second the electrode on the insulating shell, made annular to cover the insulating shell and are located on part of the length of this shell on the side of one of the con metal rod, and on the other part of the insulating sheath an additional electrode is placed in the form of a sheath in the place where there is an air gap of the metal tubular element, the area of which on the outer surface is greater than the area of any one additional electrode on the part of the insulating sheath on which the second electrode is placed, or the form of covering the shell in the place of the presence of an air gap of at least two metal sleeves successively spaced apart from each other, flat the area of each of which on the outer surface is larger than the area of any one additional electrode of a ring shape on the part of the insulating shell on which the additional electrodes are arranged in series. 5. The apparatus for lightning protection of conductive structures, containing the first electrode in the form of a metal rod, covered along the length of the insulating sheath of polymer dielectric material, and a second electrode made in the form of a set of separate electrodes arranged in series on the insulating sheath along this sheath and at a distance from each other friend, as well as the site of attachment of the electrodes to the conductive structure, characterized in that the site of attachment is made of metal and with adjacent sockets, in one of which one end of the metal rod is fixed with the formation of the contact conductive node, and in the other, isolated from the contact conductive node, the other end of the arcuate bent metal rod is fixed, the individual electrodes forming the second electrode on the insulating shell are made ring-shaped to cover the insulating shell and are located on the part of the length of this shell from the side of one of the ends of the metal rod, and on the other part of the insulating shell there is an additional ctrode in the form of a metal tubular element covering the shell, the area of which on the outer surface is greater than the area of any one additional electrode on the part of the insulating shell on which the second electrode is placed, or in the form of at least two metal bushings spanning the shell, the area of each of which on the outer surface is greater than the area of any one additional electrode of a ring shape on the part of the insulating shell on which For further electrodes are arranged in series.

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