RU2194344C2 - Ground terminal - Google Patents

Abstract

FIELD: power engineering. SUBSTANCE: ground terminal used as part of portable grounding electrodes for grounding disconnected conductors of overhead power transmission lines has electrodynamic circuit set up by composite spring-loaded strips arranged one along other. Each strip is made of flexible ferromagnetic material and has longitudinal slit in upper part and transverse taps symmetrically disposed relative to longitudinal axis of strips. Taps terminate in dropping longitudinal sections. Contact assembly is formed by combination of contacts in the form of surfaces of longitudinal edges of lengthwise disposed tap sections. EFFECT: enlarged functional capabilities. 4 cl, 6 dwg

Description

 The invention relates to the electric power industry, in particular, to portable earth terminals used for grounding disconnected wires of overhead power lines.

 Known [1] is a grounding clip containing strips installed one along the other with the possibility of elastic mutual displacement, a contact assembly formed by a terminal plate fixed to one of the longitudinally arranged strips, and a second strip ending in gripping.

 The specified clip has an imperfect socket for accommodating a grounding wire, especially in the area of small wire diameters, which leads to weak contact pressing in the pre-emergency mode and does not provide reliable contact pressing in the short circuit mode, since electrodynamic, electromagnetic and thermal arises in the contact node in this case contact rejection forces that exceed spring compression forces.

 Also known [2] is a grounding clamp containing an electrodynamic circuit formed by spring-loaded strips interconnected along one another, a contact node that is the input of the electrodynamic circuit, consisting of contacts that form a surface for receiving a grounding wire on it, made at the lower end one of the bars of the electrodynamic circuit. The upper ends of the strips are electrically connected by a flexible jumper. At the junction point of the flexible jumper with the second bar, a descent bar is electrically connected, which is located along the second bar of the electrodynamic circuit and is isolated from it below the junction point. The capture for capturing the ground wire is made at the lower end of one of the strips of the electrodynamic circuit. The terminal for connecting the grounding wire is located on the lower end of the trigger strip and acts as an output of the electrodynamic circuit. The design of this clamp is closest to the claimed technical solution (prototype).

 In this grounding clamp in the short circuit mode, the contact pressing is significantly increased by introducing an electrodynamic circuit into its design. However, this clamp is structurally complex due to the relatively large range of elements included in it. It is technologically complicated because of the need for electrical insulation of the descent bars and the connection of the electrodynamic loop and descent bars. The socket for installing the grounding wire in such a clamp is made of a certain configuration and does not provide satisfactory electrical contact on small diameters of the wires. In addition, the implementation of the electrodynamic circuit that determines the mass of the clamp above the contact node makes the clamp unstable from tipping around the axis of the ground wire, and to reduce this effect, it is necessary to increase the mass of the lower part of the clamp, which generally leads to an increase in the metal consumption of the product.

 In the known [1,2] clamps, the circumstance is also poorly taken into account that during a short circuit between the grounding and grounding wires, electrodynamic forces arise, a component of which is directed along the grounding wire and “turns” the clamps, tearing the terminals off at the places of their installation from the wires.

 The disadvantages of the known [1,2] clamps include the inability of the latter to pass emergency currents in the region of "large" values, reaching several tens of kiloamperes, due to the imperfection of the contact assembly, which can provide only a small number of contact clamp-to-ground contact pairs in known clamps wire "through which the emergency current flows to the ground.

 A common drawback of the known [1,2] clamps is the poor predictability of reaching the nominal value of the contact transient in the contact spots after installing these clamps on a grounded wire.

 The basis of the invention is the task of creating a universal grounding clamp by changing the design of the electrodynamic circuit, the contact node, capture, creating a site for attaching the grounding wire to the electrodynamic circuit, as a result of which the newly created grounding clamp would eliminate the aforementioned disadvantages of the prototype.

 The solution to this problem is achieved by the fact that the specified clip containing an electrodynamic circuit formed by spring-loaded strips located one along the other, a contact node that is the input of the electrodynamic circuit, consisting of contacts that form a surface for a grounded wire, a shank for fixing the clamp to the insulating handle, a terminal for connecting the ground wire, electrically connected to the electrodynamic circuit, acting as about the output, the grip for catching the ground wire according to this invention has significant structural changes, namely: each of the strips located between the input and output of the electrodynamic circuit is made up of a number of strips, while the contact node is equipped with limiters for the movement of the ground wire and is located in the upper part of the electrodynamic circuit, acting as its input, the lower ends of the composite strips are electrically and mechanically interconnected by means of a shank, forming the attachment point located below the contact node, the terminal for connecting the ground wire, which acts as the output of the electrodynamic circuit, is placed on the attachment node, with each component strip made of elastic ferromagnetic material, in the upper part has a longitudinal section and transverse branches symmetrically located relative to the longitudinal axis planks and ending with plunged down longitudinally spaced sections, and the role of the contacts of the contact node is performed by surfaces the edges of the longitudinally spaced sections of the transverse branches of the composite planks, while for one composite plank, the role of the contacts is played by the surfaces of the longitudinal outer edges of the longitudinally spaced sections of the transverse branches, and for the other composite plank, the role of the contacts is played by the surfaces of the longitudinal inner edges of the longitudinally spaced sections of the transverse branches the outer and inner edges form their surface nests to accommodate the ground wire, directly when adjacent to the movement limiters of the grounded wire, and in their lower part these edges are beveled relative to each other in opposite directions and form an angle open from below from below, which allows the longitudinally spaced sections of the transverse branches to act as grippers for catching the grounded wire, the mount is equipped with at least at least two holes with intersecting axes perpendicular to each other and to the longitudinal axes of the slats made from the ends of the mount, and one of the holes on one of the ends is made through, and the other hole, respectively, on the other of the ends is made only until it intersects with the first and is threaded, the beveled edges of the grippers are notched, and the longitudinal bars of the electrodynamic circuit are equipped with a locking device made, for example, in the form of a screw, fastening the strips of the electrodynamic circuit between themselves and located on the longitudinal axis of the strips between the contact node and the mount.

 The proposed grounding clamp differs from the prototype in that it can significantly expand the range of its use in the region of "large" values of emergency currents, increasing its operational reliability by reducing the total transient resistance of each contact pair "clamp - grounded wire" and enhancing its thermal and electrodynamic resistance . In addition, the proposed clamp is characterized by simplicity of design and a small range of products included in it.

 The execution of the electrodynamic circuit strips composite, consisting of a number of composite strips equipped with transverse branches, develops the throughput (in kiloamperes) of the contact node to any given value by increasing the number of contact pairs "clamp - grounded wire", which allows the clamp to undergo shock and steady currents of short short circuits without melting and destruction of both its own elements and, which is especially important, without violating the integrity and safety of the grounded wire. The increase in the thermal resistance of the clamp is ensured by the total cross section of the composite slats. A longitudinal section on each composite strip gives reason to consider the contacts of the contact node as self-aligning, providing the most optimal operating mode of the contact node as a whole. The use of the edges of the transverse branches as contact surfaces, the thickness of which is comparable, as a rule, with the diameters of the individual wires of the upper coil of grounded wires, creates the prerequisites for obtaining contact spots in the contact clamp-to-ground wire of the largest diameter with the least pressure on the contact details [3] .

 Spring clamps are characterized by mutual relative movement of the contact surfaces of the clamp and the wire, which serves as a prerequisite for chipping the oxide film on the wires and making contact with satisfactory electrical conductivity. However, in order to enhance this effect, special measures are required to shear the oxide film. In the proposed grounding clamp, a notch on the beveled edges of the grippers is used for this purpose. The importance of solving this problem is emphasized by the fact that, during the usual slip of rubbing contacts, this film sometimes cannot be destroyed [4]. The result of this is that the total contact resistance of the contacts exceeds the nominal tens of thousands of times [5]. Since the oxide film is an almost perfect dielectric, there may be a situation where, when the grounding is installed, it can be considered that it is absent, and this is unsafe for personnel working on the wires of an overhead power transmission line.

 A socket for accommodating a grounding wire is made on each transverse branch of the composite strips, i.e. Compared with the prototype, it is repeatedly strengthened. In this case, both for large and small diameters of the wires, through these sockets, a preload is created by elastic composite strips, which excludes the free placement of a grounded wire in them. The sockets are directly adjacent to the movement limiters and together provide a rigid fixation of the wire in the working position of the clamp, counteracting the effect of “turning” the clamp when a short circuit current passes through it.

 The contact node of the clamp is located in the upper part of the electrodynamic circuit and is equipped with limiters for the movement of the grounded wire. The lower ends of the composite strips are fastened together electrically and mechanically by means of a shank, forming a fastener located below the contact node, a terminal for connecting the ground wire is placed on the fastener. This relative arrangement increases the mechanical stability of the clamp against tipping over (turning around the axis of the ground wire).

 The implementation of composite strips of elastic ferromagnetic material allows us to simplify the design of the clamp by eliminating the spring and its associated parts, and the ferromagnetic properties of the strips additionally increase the compressive forces acting on these strips in the short circuit mode.

 The mount, if necessary, is made with holes, at least one through which the ground wire is passed. By means of other threaded holes, at least one, by means of a bolt, the ground wire is pressed against the part of the mount, thereby providing a terminal for connecting the ground wire to the mount. This design of the attachment node makes it possible to use a single piece of grounding wire without unnecessary contacts with cable lugs, which, especially at high emergency currents, significantly increases the reliability of portable grounding and its manufacturability.

 The use of the locking device, which is provided with the straps of the electrodynamic circuit, allows, if necessary, to differentiate the initial value of the contact pressing in the contact node without changing the traction characteristics of the electrodynamic circuit in the short circuit mode. In the simplest case, the locking device is a screw that fastens the electrodynamic contour strips together and is located on the longitudinal axis between the contact assembly and the attachment assembly.

Below are examples of the implementation of the present invention with reference to the drawings, in which:
FIG. 1 - grounding clamp, the strips of the electrodynamic circuit of which are made in the form of a series of composite strips, the number of which in a row is equal to two, front view;
figure 2 is the same, left view;
figure 3 - the same grounding clamp in the working position;
FIG. 4 - grounding clamp, the strips of the electrodynamic circuit of which are made in the form of a series of composite strips, the number of which in the row is equal to one, front view;
5 is the same, view from the left;
6 is the same, grounding clamp in the working position.

 The grounding clamp consists of an electrodynamic circuit formed by strips 1 and 2, located one along the other, and each of the strips 1 and 2 is made composite, consisting of several strips 3, starting from one or more. Each plank 3 is made of elastic ferromagnetic material, in its upper part has transverse branches 4 symmetrically located relative to the longitudinal axis and ending in longitudinally spaced sections 5, which are lowered downward, and the transverse branches 4 are bent in the same direction towards one of the strips 1 or 2 and form wherein the contact node 6 with travel stops 7. The contact node 6 is formed by contacts 8, which are the contact surfaces of the longitudinal edges 9 longitudinally arranged sections 5. The edges 9 in their upper part and the movement stops 7 form nests 10 of a certain configuration and are beveled in their lower part, due to which the lower parts of the longitudinally located sections 5 act as grippers 11. Each bar 3 in its upper part is equipped with a cut 12 , optimizing pins 8 in the clamp-to-ground wire pair as self-aligning. The edges 9 on the beveled sections of the grippers 11 are provided with notches 13, which provide chipping of the oxide layer on the wires. The contact node 6 is placed in the upper part of the electrodynamic circuit and acts as its input, the lower ends of the strips 3 are electrically and mechanically interconnected by means of a shank 14, forming a fastener 15 with a terminal 16 placed on it for connecting the ground wire, which acts as the output of the electrodynamic circuit. The mount 15 is provided with through holes 17 for screwing the ground wire and holes 18 with thread, where the bolts are screwed to create electrical contact between the mount 15 and the ground wire. The strips 1 and 2 are equipped with a locking device 19, consisting of a screw 20 and its accompanying parts, which allows you to adjust the initial force of the elastic strips 3.

 The ground clamp is mounted on the wire as follows. The grounded wire is caught by the grippers 11 and the clamp moves down with some effort. Under the influence of this force, the grounded wire slides along the contact surfaces of the edges 9, and by means of notches 13, as well as simply during sliding, the contacts of the clamp – grounded wire contact pairs are self-cleaning from oxide films and the grounded wire is placed in sockets 10, being fixed by limiters displacement 7.

 In the short circuit mode, the current from the contact node 6 flows to terminal 16. The resulting electrodynamic forces of interaction between the strips 1 and 2, combined with the mechanical clamping force, resist the forces of spontaneous rejection of the contacts, "turning" the efforts, providing a nominal transition resistance in contact pairs "clamp - ground wire".

 The offered clip is universal. It provides high thermal and electrodynamic resistance in a wide range of emergency currents, is suitable for grounding wires of any cross-sections and configurations, and provides nominal transient resistance in the contacts. The clamp is easy to operate. Prototypes have been successfully tested in laboratory and field conditions.

Sources of information
1. Directory of protective equipment and safety devices. Second edition, revised and enlarged. - M .: Energoatomizdat, 1984, p. 44-54.

 2. Auth. St. USSR 1814121, class H 01 R 4/66. Grounding clamp, authors Mrikhin V.I., Sergeev D.A. Publ. 05/07/93, BI 17.

 3. R. Holm. Electrical contacts. Publisher of foreign literature. - M., 1961, p. 46.

 4. The electrical part of stations and substations. / Edited by A.A. Vasiliev. - M .: Energy, 1980, p. 94.

 5. A.A. Chunikhin. Electrical apparatus. - M .: Energoatomizdat, 1988, p. 92.

Claims (4)

 1. An earthing clamp containing an electrodynamic circuit formed by spring-loaded strips located one along the other, a contact node, which is the input of an electrodynamic circuit, consisting of contacts forming a surface for a grounded wire, a shank for attaching the clamp to the insulating handle , a terminal for connecting the ground wire, electrically connected to the electrodynamic circuit, acting as its output, a grip to capture the ground wires, characterized in that each of the strips located between the input and output of the electrodynamic circuit is made up of a number of strips, while the contact node is equipped with limiters for the movement of the ground wire and is located in the upper part of the electrodynamic circuit, acting as its input, the lower ends of the composite strips are electrically and mechanically interconnected by means of a shank, forming a fastening unit located below the contact node, a terminal for connecting the gap is located on the fastening node the lead wire, which acts as the output of the electrodynamic circuit, with each component plate made of elastic ferromagnetic material, in the upper part has a longitudinal section and transverse branches symmetrically located relative to the longitudinal axis of the plates and ending with the sections arranged longitudinally downward, and the role of the contacts of the contact node is the surface of the longitudinal edges of the longitudinally spaced sections of the transverse branches of the composite slats, while for one composite lath the role of the contacts is played by the surfaces of the longitudinal external edges of the longitudinally located sections of the transverse branches, and for another composite strip, the role of the contacts is played by the surfaces of the longitudinal internal edges of the longitudinally located sections of the transverse branches, in their upper part the external and internal edges form nests for the grounding wire directly adjacent to them to the limiters of movement of the grounded wire, and in their lower part these edges are beveled relative to each other each other in opposite directions and form between themselves an open bottom angle that provides the longitudinally spaced sections of the transverse branches, which serve as grippers for trapping the grounded wire.  2. An earthing clamp according to claim 1, characterized in that the attachment unit is provided with at least two holes with intersecting axes perpendicular to each other and the longitudinal axes of the strips made from the ends of the attachment node, and one of the holes on one of the ends is made through, and the other hole, respectively, on the other of the ends is made only until it intersects with the first and is threaded.  3. An earth clamp according to claim 1, characterized in that the beveled edges of the grippers are provided with a notch.  4. The grounding clamp according to claim 1, characterized in that the composite strips of the electrodynamic circuit are provided with a locking device made, for example, in the form of a screw fastening the strips of the electrodynamic circuit between themselves and located on the longitudinal axis of the strips between the contact node and the mount.

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