RU197038U1 - ANTISEISMIC FUSE OF THE STRUCTURAL SUPPORT PART - Google Patents

Abstract

The utility model relates to construction and can be used for extended structures, such as bridges, transport galleries, pipeline crossings, etc., constructed mainly in seismic areas. The antiseismic fuse of the supporting part of the structure contains a friction-movable joint, in which the interaction of its elements with the frictional resistance force is provided with mutual horizontal displacement relative to each other from seismic effects. The anti-seismic fuse is equipped with a structure attached to the support, for example, using anchors located on its one side, with a base on the other side of which at least two power brackets are rigidly fixed at the ends. On the plane are placed, with the possibility of horizontal displacement in an arbitrary direction, two friction-movable plates pressed by pressure shoes, between which a support plate is located with the possibility of interaction and joint displacement with them on this plane. Contact with each other of the surface areas of the base and the base plate was made through an antifriction pair of slip layers, one of which is made of metal with a polished surface, and the other of antifriction material, of polytetrafluoroethylene. On the opposite side of the base plate is placed and fixed on it by a threaded connection supporting part attached to the span of the structure. Holes are made in the power brackets, into which high-strength bolts are screwed fully into the shoes with the normative force, ensuring frictional interaction of the elements of all these movably friction joints. The objective of the utility model is to ensure operational safety during earthquakes of structures with most known types and types of bearing parts by means of protection against strong arbitrary horizontal influences. 3 s.p. f-ly, 3 ill.

Description

The utility model relates to construction and can be used for extended structures, such as bridges, transport galleries, pipeline crossings, etc., constructed mainly in seismic areas.

In earthquakes, horizontal seismic effects are known to be more damaging than vertical ones. Therefore, along with special anti-seismic devices that protect structures from vertical influences (additional connections between spans and supports, spans and soil, supports and soil, special support parts for tear-off load, etc.), wide attention is paid to the protective structures of support parts, allowing to perceive horizontal seismic load of any direction.

Known antiseismic fuse of the rubber support part of the structure, made in the form of a lead rod mounted in this support part / 1 / and the antiseismic fuse of the hinged support part of the structure, made in the form of a support table on flexible vertical steel rods / 2 /. Their disadvantage is that they are based on the principle of compliance and can work in case of weak and partially moderate earthquakes, and in case of strong earthquakes they are irreversibly deformed and do not protect the span from being discharged from the support. In addition, they are intended for supporting parts of only the indicated types and are directly their parts.

The closest to the proposed utility model in terms of technical nature and the achieved result is an anti-seismic fuse of the supporting part of the structure, containing a friction-movable joint, providing with the normative force of friction resistance mutual displacement of its elements relative to each other under horizontal seismic effects of strong earthquakes / 3 /. Due to this, the quenching energy is suppressed and a significant decrease in the horizontal seismic effect on the span is performed.

The main disadvantage of this fuse is due to the fact that it is also an element of the directly supporting part of the same type with negative properties inherent in such a solution. In addition, its disadvantage is that it is made in the form of a friction pack of horizontal sheets, in which each sheet is connected by means of high-strength bolts to another sheet, and the sheets are made with oval holes for the bolts oriented by the larger axis in the most probable direction of the dangerous seismic exposure. As a result, the fuse in question does not always provide full protection of the support part from arbitrary horizontal seismic effects, since their direction may not coincide with the orientation of the oval holes and the designed direction of movement of the sheets in the packet during seismic. These shortcomings significantly reduce the operational reliability of such a design and limit the possibility of its widespread use in buildings.

The proposed utility model is aimed at solving the problem of operational safety during earthquakes of structures with most known types and types of bearing parts by providing them with protection against strong arbitrary horizontal influences.

To solve this problem, the anti-seismic fuse of the supporting part of the structure also contains a friction-movable joint, in which its elements interact with the normative force of friction resistance with mutual horizontal displacement relative to each other from seismic effects. At the same time, it is equipped with a structure attached to the support, for example, using anchors located on its one side, a base on the other side of which is rigidly fixed, in particular, at least two power brackets at the ends, and they are placed with a horizontal displacement in an arbitrary direction, two friction-movable plates pressed by pressure shoes, between which on the same plane there is an interacting and jointly displaced support plate. The contacting planes of the base, friction-movable plates and shoes are normatively processed under the contact surfaces of the friction joint, and the contacting with each other of the surfaces of the surfaces of the base and the support plate is made through an antifriction pair of slip layers, one of which is made of metal with a polished surface, and the other of anti-friction material, in particular polytetrafluoroethylene. On the opposite side of this base plate, it is provided for placement and fastening, for example, by a threaded connection, of a supporting part connected to the span of the structure. Holes are made in the power brackets, into which high-strength bolts are screwed fully into the shoes with the normative force, ensuring frictional interaction of the elements of all the indicated friction-movable joints.

Correspondingly, the surfaces of the elements contacting each other, ensuring frictional interaction, are processed using one of the methods specified in the current regulatory documents, which predetermine the corresponding standard coefficient of friction in the friction-movable joint, depending on which the diameter and number of high-strength bolts are assigned and the calculated horizontal seismic force.

Recesses are made in the pressure shoes, against which high-strength bolts abut, while lubricant channels are placed in the bottom surfaces of these recesses, and high-strength washers and nuts corresponding to these bolts are installed and secured in the holes of the power bracket made for high-strength bolts.

In some cases, when the direction of the horizontal seismic impact is known with a high degree of probability, the friction joints of the fuse can be placed with the mutual displacement of their elements along this probable displacement of the support structure.

The essence of the utility model is illustrated by drawings.

In FIG. 1 shows a view A of a section of an anti-seismic fuse in the supporting part of a structure.

In FIG. 2 shows a top view of the anti-seismic fuse of the supporting part of the structure.

In FIG. Figure 3 shows a section B of the anti-seismic fuse of the supporting part of the structure.

The proposed utility model of the anti-seismic fuse of the supporting part 1 of the structure, installed between its span 2 and the support 3 (these first three positions are indicated by a dotted line) contains a base 4, on which one anchor is fastened to one side facing the support 3, in particular anchor bolts 5 , embedded in this support 3, and on the other side of the base 4, power brackets 6 are rigidly fixed at the ends, between which there is a support plate 7 and two friction-movable plates 8. Power brackets can be of any design: frame locks mentioned, with stiffening ribs, brackets, etc., and may be attached to the substrate by any means, threaded connections, welding, molded together with the base a single piece, etc.

The support plate 7 and the friction-movable plates 8 interact with each other with the possibility of joint frictional displacement relative to the base 4 at the estimated horizontal seismic loads. For this, the base 4 and the support plate 7 are in contact with each other through the counter surfaces of the antifriction pair 9 of slip layers, one of which is made of polished metal, for example, hard-chrome-plated or stainless, and the other is made of antifriction material (the contact point of these slip layers is shown by a thickened colorless line 9) . Polymers known from the state of the art can be such anti-friction material: pure, filled or radiation-modified tetrapolyfluoroethylene (the so-called fluoroplast-4), ultra-high molecular weight polyethylene, etc. This allows for a minimum friction coefficient of no more than 0.06 in the antifriction pair of slip layers. At the same time, plates 8 are made with two opposite lying surfaces, subjected to special processing, which allows to obtain large friction coefficients in the range 0.35 - 0.58 (SP 35.13330.2011 PIPE BRIDGES. Updated version of SNiP 2.05.03-84 * tab. . 8.12). These surfaces are in contact (the place of this contact is shown by a thickened dark line 10) and interact with frictional mobility during the calculated seismic loads with the correspondingly processed corresponding sections of the base plane 4 and with the mating surfaces of the pressure shoes 11.

In accordance with the values of the normalized coefficient of friction due to surface treatment, based on the calculated horizontal seismic force, the diameter and number of high-strength bolts are assigned. To ensure displacements from the horizontal seismic forces of the elements of the anti-seismic fuse during their placement, the sizes Δprod and Δpop must be provided, which allow the support plate 7 to move together with the friction-movable plates 8 in arbitrary directions under the action of a horizontal seismic action exceeding the resistance to normalized friction.

The required normative force required for the frictional interaction is created by providing pressure on the pressure shoes 11, screwed with the specified torque of the high-strength bolts 12 widely used in bridge construction into the holes of the power staples 6. In this case, it is possible to use nuts and washers specially designed for the high-strength bolts installed in holes of power staples 6. But bolts and holes with special threads, including persistent, known from the state of the art, can be used. In addition, the use of another set of nuts is possible for locking high-strength bolts from loosening and loosening their tension. An additional set of nuts can be used. In order to avoid slipping of the pressure shoes 11 when tightening the high-strength bolts 12 in these shoes, it is advisable to prepare a recess in which these bolts will abut. To facilitate the twisting of the latter to the standard axial force in the bottom surfaces, lubrication channels can be made, for example, along the thickness of the shoes 11.

Under normal (non-seismic) operating load, the support part is firmly held on the support 3 by securing it, for example, with bolts in the threaded holes 13 on the support plate 7, which in turn is fixed by friction-movable plates 8. Mounting the support part 1 on the support plate 7 possibly in other ways known from the state of the art. The dimensions of the plate 7 and the location of the holes 13 are determined by the dimensions of the support part installed in the fuse of any of the known types and types used in construction. Actually, along with other factors, the size of the proposed fuse depends on this.

As already mentioned, with seismic effects, the most dangerous are horizontal displacements relative to the statically inertial span 2 shifting bearings 3 caused by seismic movement of the soil. Under normal operating conditions, the operation of the proposed utility model is to keep the supporting part 1 with the span 2 on the support 3. Moreover, all friction joints reliably absorb operational loads and keep the supporting part in the design position.

At the same time, the work of the proposed utility model with horizontal seismic influences of an unacceptable calculated scale lies in the shift of the base 4 due to the movement of the support 3 with the power bracket 6 and the shoes 11 relative to the span 2 with the supporting part 1 attached to it and to the base plate 7. this seismic horizontal force in excess of the calculated resistance to friction, predetermined by the selected method of surface treatment and the corresponding coefficient of friction of the friction joints edohranitelya causes a shift of the horizontal displacement and the friction element compounds. Displacements can occur within Δprod and Δpop values in arbitrary directions. If the most probable direction of seismic horizontal displacement of the support along this direction is known, only one of the sizes Δprod or Δpop in which frictional displacement can occur can be provided in the fuse structure.

Due to the shown displacements with the existing frictional contact of the parts of the antiseismic fuse of the supporting part, the seismic energy of the shock is suppressed and the horizontal seismic effect on the span is significantly reduced.

The presence under the base plate 7 of an antifriction pair of 9 slip layers makes it possible, when calculating the vertical frictional contact force created by high-strength bolts, not to take into account the influence of other vertical factors acting on the support part, since the horizontal force they create will be quite small due to the low coefficient of friction indicated slip pairs.

Naturally, choosing the appropriate dimensions of the anti-seismic fuse in it on the anti-friction plate, you can place almost any known support part and thereby expand its functionality for use in structures under construction in seismic areas.

Thus, the proposed utility model of the anti-seismic fuse of the supporting part of the structure allows its operational safety in earthquakes with significant horizontal seismic effects acting in arbitrary directions.

Sources of information taken into account:

1. Kelly J.M. Earthquake resistant design with rubber. Springer 1997.243 p.

2. A.C. USSR, No. 1162886, M. cl. E 01D 19/04, 23. 12, 1982.

3. A.S. USSR, No. 1106868, M.cl. E01D 19/04, 07/12/1982.

Claims (4)

1. Antiseismic fuse of the supporting part of the structure, containing a friction-movable joint, in which the interaction of its elements with the frictional drag force at mutual horizontal displacement from each other from seismic effects, characterized in that it is provided attached to the support of the structure, for example, using anchors located on its one side, the base, on the other side of which is rigidly fixed, in particular, at the ends, at least two power staples, and on the plane With a possibility of horizontal displacement in an arbitrary direction, two friction-movable plates pressed by pressure shoes, between which on this plane a support plate is also located with the possibility of interaction and joint displacement with them, and contact with each other of the surfaces of the base surfaces and the support plate is made through an antifriction pair slip layers, one of which is made of metal with a polished surface, and the other is made of antifriction material, in particular polytetraflu ethylene, and on the opposite side of the base plate is placed and fixed on it, for example, by a threaded connection, the supporting part attached to the span of the structure, while the holes in the power brackets are made into which high-strength bolts are screwed into the shoes with normative force, providing frictional interaction of elements of all these movably frictional compounds. 2. The antiseismic fuse of the supporting part of the structure according to claim 1, characterized in that recesses are made in the pressure shoes, against which high-strength bolts abut, while lubricant channels are placed in the bottom surfaces of these recesses. 3. The anti-seismic fuse of the supporting part of the structure according to claim 2, characterized in that corresponding to them high-strength washers and nuts are installed and fixed in the holes of the power clamps made for high-strength bolts. 4. The antiseismic fuse of the supporting part of the structure according to claim 3, characterized in that the elements of its frictional joints are arranged to ensure their mutual horizontal displacement along the probable direction of the seismic horizontal displacement of the support.

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