RU2099613C1 - Shock absorbing device - Google Patents

Abstract

FIELD: securing multi-wire conductors of aerial power lines suspended from cross-members of power line towers forming spans. SUBSTANCE: at least one multi-wire conductor runs rectilinearly; it is secured by means of bracing strut articulated to corner points of equilateral triangular frame, with top of clamp directed downward. Triangular frame is connected with insulator by means of holding bracing strut articulated to lower corner point. Holding bracing strut is connected with upper corner points of triangular frame by means of vibration damper. EFFECT: enhanced reliability. 6 cl, 4 dwg

Description

 The invention relates to a shock-absorbing device for fastening to connecting fittings using clamps of multiwire wires of overhead power lines, which are suspended on the yokes of the bearing masts and form spans.

 It is known that overhead lines, along with forces from the dead weight of the multi-wire wires, are mechanically loaded with additional loads, such as ice cover or wind, which loads the multi-wire wires. Other additional loads may result from fluctuations, the causes of which are different. Along with short-term large-amplitude oscillations that are caused by a pulse, and small-amplitude vibrations across the axis of the conductor with a small wavelength and high frequency, which are also called vibrations, longitudinal vibrations with large amplitude and small frequency, which are also called jitter, are significant a problem that adversely affects the service life of stranded wires. In this case, the multi-wire wires are fixed using multi-wire wires made in the form of load-bearing or tension clamps on the cross-arms of the bearing masts.

 From the laid-out application of Germany N 4041889, a shock-absorbing device for a high-voltage overhead power transmission line is known, which is carried out by means of the spans between the yokes of the anchor masts and is held on them, in which the longitudinal vibrations folded from individual spans are absorbed using damping elements that are connected to the insulators, moreover the stranded wire is pulled and looped around the tension point. In this case, the multiwire wire is fixed in the so-called anchor clamps, which are either directly or indirectly connected to the shock-absorbing device.

 According to a known shock-absorbing device, an electric current characteristic due to the formation of a loop is provided separately from the mechanical diagram of the forces. In practice, this means a significant consumption of material for additional loops of a multiwire wire, as well as a large investment of time for installation work, not counting the special difficulties associated with the installation of such shock absorbing devices at a considerable height.

 Therefore, based on the prior art, the object of the invention is to provide a shock-absorbing device of the type mentioned at the beginning, which eliminates these costs and, if necessary, also additionally allows installation in high-voltage overhead power lines.

 In accordance with the distinguishing features of paragraph 1 of the claims, this problem is solved due to the fact that each multi-wire wire runs approximately rectilinearly and is fastened accordingly by an equilateral triangular frame directed at the top corner points pivotally connected with the tip pointing downward that the triangular frame is pivotally connected attached to the lower corner point of the retaining strut is connected to the insulator and that the holding strut, at least one The first vibration damper is connected to both upper corner points of the triangular frame.

 In the construction in accordance with the invention, it was possible to avoid the usual hinge formation during double-sided stretching, instead, the corresponding multi-wire wire is pulled tight. However, the arising long-wave oscillations in the span cannot be transmitted to the adjacent span, since in the short section of the multi-wire wire between the two supporting terminals, which are located at the upper corner points of the triangular frame, axial elongations are absorbed by means of vibration dampers attached here.

 In order to avoid possible damages to vibration dampers due to exceeding their travel in the case of especially longitudinal strong vibrations of stranded wires, it is advisable to provide for the arrangement of stops on the base of the strut provided for connecting the upper corner points of the triangular frame, which limit the deviation of the holding strut along the base strut in the direction of its longitudinal axis .

 In principle, a shock-absorbing device in accordance with the invention is also provided for fastening a lightning protection cable intended for lightning protection.

 According to another preferred embodiment of the invention, it can be provided that, in order to articulate the load-bearing terminals from the triangular frame, respectively, two parallel fixing strips are provided, between which the load-bearing terminal is placed, on which at least one is pivotally connected to the triangular frame (this the system is especially favorable when more than one stranded wire is provided for each phase). In this kind of case, it is advisable to conduct multi-wire wires in parallel in pairs with the help of the multi-wire wires acting on the terminals of the strips, they are articulated to a triangular frame.

 A particular embodiment of the invention is that there are two triangular frames that are parallel to each other and secured by pivot pins at a lateral distance from each other. This system, in particular, is suitable when a total of four stranded wires are provided for each potential, which are respectively articulated in pairs by means of fixing strips respectively on the sides of the triangular frame facing away from each other. At the same time, vibration dampers are located on the hinge pins in triangular frames in accordance with the invention, and it must be pointed out that the holding struts are also provided with such a hinge pin.

 In principle, the solution in accordance with the invention does not depend on the number of conductors in each phase, i.e. there may be either individual conductors or bundles of conductors with 2, 3, 4 or a large number of individual conductors.

 In all embodiments of the shock-absorbing device in accordance with the invention, only single-acting damping elements are used, and these elements, when viewed in the longitudinal direction of the line, are respectively directed against each other. And they have a damping effect only when pulling the piston rod of the damping device.

 In an advantageous embodiment of the invention, it is provided that the upper ends of the holding struts have, or can be installed on them, fixing elements that enable fastening on mating insulators suspended on the yoke of the carrier mast.

 These and other preferred embodiments are the subject of additional claims.

 Using the exemplary embodiment shown in the drawing, it is necessary to explain and describe the invention, specific embodiments and advantages of the invention in more detail.

 The drawing shows: FIG. 1 shock absorbing device for four stranded wires per phase; FIG. 2 shock absorbing device for one stranded wire per one phase; FIG. 3 shock absorbing device for two stranded wires per phase; FIG. 4 shock absorber for three stranded wires per phase.

 In FIG. 1 shows a shock-absorbing device 10, which has two structurally identical, directed downward pointed equilateral triangular frames 12, the corner points of which are fixed at a certain distance with the help of pivot pins.

 In the upper corner points of the triangular frame 12 in the center, in pairs, are fixed parallel to each other fixing strips 16, which are respectively pivotally connected at the ends to the supporting terminals 18, so that the shock-absorbing device 10 as a whole has 8 terminals 18 of multi-wire wires.

 Using the supporting terminals 18, a total of four multi-wire wires 20 were drawn, and the longitudinal tensile forces folding from the own weight of the multi-wire wires are perceived by the multi-wire wire section 21 located between the terminals 18 and not by the triangular frame 12. To the downwardly directed corner point of the triangular frame 12 are pivotally connected respectively support strut directed vertically upwards 22, which is designed to be connected to insulators not shown in more detail in the drawing, located GOVERNMENTAL above the cushioning device 10, and this has provided for the fixing device 23.

 Approximately in the area connecting the two upper corner points of the triangular frame 12 of the base strut 24, both parallel holding braces 22 are connected to each other using the other hinge pin 15, just like with the downward pointing edge of the triangular frame. This hinge pin 15 is also intended as the hinge pin 14, which holds the corner points of the triangular frame 12 at a certain distance, at the same time for installing vibration dampers 26, which, in order to damp two vibrations, act between the upper corner points of the triangular frame 12 and the holding struts 22.

 In the same way as the corner points of the triangular frame 12 located on the sides of the triangular frame 12, the fixing bars 16 are also held at a certain distance by the pins 17.

 The principle of operation of the shock-absorbing device described above 10 is based on the fact that the multi-wire wires 20, which are drawn straight from span to span using shock absorbing devices forming the corresponding attachment points, in the case of longitudinal oscillations on one side, i.e., in one of the two upper corner the points of the triangular frame 12, make a tensile movement, which leads to the displacement of the triangular frame 12 relative to the vertically directed holding brace 22, so that the latter, which is normal position of the strut forms a base 24 at right angles, the angular deviation undergoes temporary. This displacement is compensated by the vibration damper located between the free end of the retaining strut 22 and the upper corner points of the triangular frame 12 so that the transmission of this displacement to an adjacent span and thereby the transmission of longitudinal oscillation is excluded.

 In this case, it does not play any role whether it is necessary to fix a multi-wire wire or a bundle of wires consisting of several, for example, three, four or six separate multi-wire wires. In the latter case, individual wires in accordance with their geometrical arrangement relative to each other are also fixed in the shock-absorbing device in accordance with the invention in the bearing terminals.

 In FIG. 2 shows a shock-absorbing device for one stranded wire, which is almost identical in design to that shown in FIG. 1 to a shock-absorbing device, so that the same symbols apply to the same individual parts.

 Only the mounting of the supporting terminals for the multiwire wire on the shock absorber is different from the mounting shown in FIG. one.

 As in FIG. 1 shown in FIG. 2, the shock-absorbing device is formed of two triangular frames 12 located parallel to each other at a certain distance and with vertices pointing downward, the corner points of which are held by pivot pins at a certain distance from each other.

 By analogy with FIG. 1 in a cushioning device in accordance with FIG. 2 fixing strips 16 are also located at the upper corner points of the triangular frame. Moreover, they are in a triangular frame 12 in accordance with FIG. 2 are connected to the base strut 24 as a whole and, accordingly, made rigid by bending. In the form of a downwardly directed end of the base strut 24, retaining trunnions 29 are connected, which are directed to the opposite triangular frame and hold the bearing terminals 18 for straight-drawn multi-wire wire 20 at approximately half the distance. A further embodiment corresponds to the shock-absorbing device in accordance with FIG. one.

 In FIG. 3 and 4 show modified shock absorbing devices, for example, for two or three stranded wires, which, relative to the fastening of the stranded wires in the carrier terminals 18, correspond to those previously shown in FIG. 1 or 2 designs, so reference is made to their explanation.

 While in the shock-absorbing device for two stranded wires, which is shown in FIG. 3, only one plane is occupied, in this case the upper plane, of the fixing strips 16, and the lower plane has only a hinge pin 17 that connects both triangular frames 12, and the shock absorbing device provided for three multi-wire wires in accordance with FIG. 4, in the upper plane, fastening of the multiwire wires is provided, as shown in FIG. 3 and in the lower plane corresponding to that shown in FIG. 2, a structure in which a multi-wire wire is secured between the triangular frames 12 in the bearing terminals 18.

 In a similar design, bundles with six stranded wires can also be conducted, with another pair of stranded wires parallel to and below and above shown in FIG. 1 attachment points for four separate stranded wires 20.

Claims (6)

 1. A shock-absorbing device for stranded wires of overhead power lines, containing a frame, at one end of which a corner is formed, the apex of which is directed downward, and bearing terminals, characterized in that it is equipped with vibration dampers and a vertically mounted strut, one end of which is articulated at the apex of the corner links, the free ends of which are pivotally connected to the bearing terminals, mounted on a rectilinear wire, forming an equilateral triangle with the links of the frame, and the end of the strut through vibration dampers is connected to the corresponding articulated ends of the links and is intended for connection with insulators of power lines.  2. The device according to claim 1, characterized in that it is equipped with an additional strut connecting the articulated ends of the links of the frame, and placed on it stops, restricting the movement of the main strut along the wire.  3. The device according to claim 1 or 2, characterized in that it is provided with pairs of parallel strips mounted at the ends of the pivotally mounted frame links, at least one of which is pivotally mounted on the corresponding link, and the corresponding carrier terminal is placed between the strips.  4. The device according to claims 1 to 3, characterized in that the vibration dampers are made in the form of single-acting dampers.  5. A shock-absorbing device for multiwire wires of overhead power lines, containing two frames parallel to each other, with one end of each link forming an angle, the top of which is directed downward, and the bearing terminals, characterized in that it is equipped with two vertical struts each installed in the corresponding frame, one end of which is pivotally mounted at the apex of the corner of the corresponding frame, which is an equilateral triangle, by pivot pins, connected connecting the corresponding free ends of the links of the frames and the free ends of the struts located between the frames by at least two vibration dampers connecting each trunnion connecting the ends of the struts with the corresponding trunnion connecting the ends of the links of the frames, and located on the ends of the last parallel bars connected at the ends by holding trunnions with bearing terminals fixed to them, at least one of which is intended for fixing a multiwire wire.  6. A shock-absorbing device for stranded wires of overhead power lines, containing two frames parallel to each other, with one end of each link forming an angle, the top of which is directed downwards, and the bearing terminals, characterized in that it is equipped with two vertical struts each installed in the corresponding frame, one end of which is pivotally mounted at the apex of the corner of the corresponding frame, which is an equilateral triangle, by pivot pins, connected connecting the corresponding free ends of the frame links and the free ends of the struts located between the frames by at least two vibration dampers connecting each trunnion connecting the ends of the struts with the corresponding trunnion connecting the ends of the frame links, and pairs of parallel strips, the inside of which are pivotally connected to the corresponding ends of the links frames, and the bearing terminals are fixed between the ends of the corresponding pairs of parallel strips, are located at the corners of the square and are designed to fix four multi-wire x wire single phase.

Images