DE2816678C3 - Cable support system - Google Patents

Description

The invention relates to a cable support system in an earthquake-proof design for nuclear power plants and The like, consisting of in particular I-shaped profiled, spaced in the direction of the cable run one behind the other, vertically to be arranged carriers and several on these supported, laterally horizontally cantilevered support arms, the carriers having retaining slats on one or both sides at their ends, which can be fixed on the structure, and also adjacent vertical girders are braced together.

Such cable support systems are from the prospectus »Traversen-System« from Pohl, cables 7 and 8, known.

In the previously known systems of this type, the carrier is attached to the structure on both sides by Dowels of considerable length, for example 200 mm, with corresponding dowel edge distances in dowel groups be inserted into the concrete ceiling or floor and the retaining plates by means of inserted threaded bolts be attached there.

It is also common to hang the beams or use short stands. Furthermore can the girders are also attached to other supporting structures, for example steel girders will.

bo For earthquake-proof design in nuclear power plant construction these constructions are unsuitable. The forces generated by earthquakes are particularly demanding strong and long safety dowels, as the high forces acting, especially tensile forces,

ι, · -, but cannot be intercepted. The distance the dowel of a support plate from each other should according to existing regulations when using M 12 be approx. 190 mm, the distance between adjacent

Support plates with four dowels is 900 mm, according to Expert opinion of the TH. Darmstadt

Furthermore, the support plates are to be designed to be extremely large and strong.

The highest demands are also placed on the quality of the material

All these claims are justified because, provided the load-bearing system is stressed by earthquake vibrations extremely high pull-out forces act on the dowels. This has led to proposals were made to pour large steel plates into the concrete ceilings and to attach the supporting plates to them attach.

The planning effort then required is tremendously large, because already with the shell construction of the The exact location of the support of the system is to be determined and, moreover, the extremely exact arrangement of the steel plates it is necessary so that the carriers are later attached exactly to the above-mentioned points can. The variability of the system is so limited that later changes or additions are practically impossible.

It should also be noted that a laborious search for iron is required to attach dowels of the above length must be made in concrete.

The same effort that must be operated in cable support systems in nuclear power plant construction is also for Ventilation installation and pipelines prescribed.

The different at each attachment point loading conditions must be calculated and taken into account by m corresponding design of the system.

Before laying the individual cables to the cable support arms or lattice or ladder-type cable trays are placed at a uniform edition J ^r> to reach the cables to dissipate the heat generated thereof and to facilitate the replacement of cables.

However, the development described above leads to a no longer manageable dimensioning and a unbearable planning and engineering workload.

The invention is therefore based on the object of providing a cable support system of the type indicated at the beginning to create a suitable earthquake-proof design with little planning and engineering effort leads. The system is composed of the smallest possible number of simple building blocks be.

According to the invention, this object is achieved in that the braced beams have a 5 " Form the rigid unit cell of the structure and the retaining plates with the interposition of all sides effective spring elements and damping elements acting in the same direction are connected to the building are.

In contrast to the prior art, this knowledge is based on the fact that not the fastening elements for Absorption of the required forces should be dimensioned accordingly large, but the forces in the Bearing points as low as possible (.keep and on the t> r> statically necessary dimension must be reduced.

In particular, the transmission of moments must be avoided.

In order to achieve these effects, the spring elements should not be very stiff, but rather larger t> 5 Allow oscillation amplitudes, so that the friction between the cable sheaths placed on the support system is used to destroy the kinetic energy. As essential energy destroyers are the damping elements provided.

In order to also meet the requirements for temperature conditions in nuclear power plant construction it is provided that the spring and damping elements are at least in the range of 268 ° K to 470 ° K are functionally stable.

The formation of spring elements and damping elements and in particular their arrangement between retaining plate and structure is quite complex if steel springs and the like are used find, since these have a relatively large space requirement, are expensive and do not have sufficient damping capacity exhibit.

It is therefore proposed that at least one rubber bearing each be used as the spring and damping element is attached between the retaining plate and the structure

Great progress has already been made with this

But with respect to that required in the Kernkraftbau ⁶ Temperature resistance, it is particularly advantageous in that a bearing of elastomeric material as a spring and damping element is arranged.

A chloroprene rubber or a fluorine-containing rubber can be provided as the elastomer material be able to withstand continuous loads, especially in the temperature range from 268 ° K to 398 ° K, and at 458 ° K a Is resilient for an hour

The temperature requirements usually mean that the bearings are stable in continuous operation between 268 ° K and 398 ° K (-5 ⁰ C and 125 ° C) and can ^{withstand temperatures of 458 ° K (185 0} C) for up to an hour without that their function is switched off.

A chloroprene rubber type, for example, is used as the material successfully used, which consists of 60% chloroprene rubber and up to 20 fillers.

They are assembled in such a way that the bearing can withstand the required temperature loads

In particular, the elastomeric material also has high damping properties, so that the bearing a Has a damping capacity of at least 10%.

An advantageous embodiment is that on the rubber or elastomer bearing at its with the Holding plate or surface corresponding to the structure each have a steel plate facing outwards protruding threaded bolt is vulcanized

The spring constant of this bearing with respect to horizontal movement depends on the sliding module C, on the height of the elastomeric cushion and its cross-sectional area. The constant for the vertical movement is about ten times higher and depends on the relation of the free to the bound surface of the cushion. It is also provided that two bearings are arranged per holding plate.

For this purpose, the holding plate can be rectangular and hold the bearings at its end regions.

It has also proven to be advantageous if the bearings at 473 ° K have a load-bearing capacity of 5 * P / cm ² (approx. 0.5 ^N / mm ² ).

The loads applied can be held well by appropriate dimensioning of the bearings.

A further advantageous embodiment consists in the fact that, in order to stiffen one unit cell, the neighboring cell Beams are connected to one another by flat bars.

Furthermore, it can be provided that in each case a plurality of unit cells are spaced apart from one another are arranged.

Only the respective unit cell is braced,

while the individual unit cells are not braced together.

It can also be provided that the carriers are arranged in a suspended manner.

A further development is seen in the fact that the bearings indirectly with the interposition of profile rails can be fastened on the building side (Figs. 9 and 10).

An advantageous embodiment is characterized in that the profile rail which can be fastened on the ceiling side or the profile rail section is designed as an open C-profile, to which the ceiling-side can be fastened Leg opposite leg the bearing can be fixed on the side facing the profile interior is and the corresponding retaining plate of the carrier on the free, aiming to the profile interior surface of the bearing can be placed and fastened there.

This has the effect that the bearings attached to the ceiling or to the upper retaining plate are only statically are subjected to pressure. This is particularly advantageous in the case of carriers that are arranged in a suspended manner.

A further advantageous embodiment is characterized in that when it is only fastened upright Carrier (F i g. 4 and 6) the holding plate formed over a large area and through between the holding plate and the carrier attached, in particular triangular stiffeners, is reinforced.

It is also advantageous if the carriers in the respective outer unit cells of a carrier field of the last cell are stiffened by angle profiles.

To facilitate assembly, it is useful if the angle or flat profiles at the end and / or the carrier Holes at the corresponding fastening points to accommodate the high-strength fastening screws exhibit.

The training according to the invention has many advantages, some of which will be explained here.

The arrangement of the elastomeric bearings means that the fastening dowels or bolts can only be neglected low bending moments.

In addition to static forces, there are also almost all of the load conditions caused by earthquakes no tensile forces on the dowels. As a result, the dowels can be dimensioned smaller, in particular Smaller dowel and group spacings are possible.

The compressive and tensile forces acting on the dowels are within the scope of the statically applied.

The dowels are dynamically stressed essentially only by shear forces.

As a result, the drill hole depths for setting the dowels as well as the dowel lengths can be reduced, which leads to considerably less work, because in particular the search for iron in concrete is greatly simplified is.

Those previously used in nuclear power plant construction for cable support systems, ventilation and pipelines Retaining plates can be made smaller in area and thickness, which helps when calculating static-dynamic advantages can be achieved in construction planning and engineering.

Because of the now only small space requirement, a simpler coordination of the individual trades is possible. The subsequent shifting of cable routes is no longer difficult.

All these effects result from the interposition of the elastomeric bearings, the high damping characteristics, a spring behavior in every load direction and have a heat resistance of up to 473 ° K, in connection with the stiffening of the Carrier system.

The impact energy to be absorbed is practically converted into kinetic energy and through damping of the bearing material degraded.

The main requirement of the cable support system is that after an earthquake the function of the electrical system is retained in order to enable the reactor to be switched off without risk.

Embodiments of the invention are shown in the drawing and described in more detail below.

It shows

F i g. 1 a unit cell of a cable support system in perspective,

Fig. 2 to 7 different cable carrier shapes ir Opinion,

F i g. 8 a detail in perspective,

Fig. 9 and 10 two variants of the detail in Opinion.

The cable support system in an earthquake-proof design for nuclear power plants and the like consists of I-shaped profiled, vertically arranged one behind the other in the direction of the cable route at a distance of 150 cm Beams 1 and several laterally horizontally cantilevered support arms 2 held on them. The latter can be attached to the carrier 1 on both sides and / or on one side. On the support arms 2 are ladder-like Cable carrier 3 placed. The supports 1 have at one end (Fig. 3, 4, 6, 7) or at both ends (Fig. 1, 2, 5) Retaining plates 4 which can be fastened to the structure.

In each case two directly adjacent carriers 1 are to form a rigid unit cell (Fig. 1) of the Strut structure with each other via flat bars 5 arranged crosswise. The flat bars 5 are at their Crossing points connected to each other and at their ends to the beams 1 by means of high-strength screws.

On the holding plates 4 bearings 6 made of elastomeric materials are attached, which in turn are attached to the building. The bearings 6 have vulcanized steel plates 7, 8 on their upper and lower sides. A threaded bolt 9, which can be inserted into a dowel attached to the building, protrudes from the upper steel plate 8, while a bolt 10 is attached to the lower plate 7 through corresponding holes 11 the holding plate 7 can be guided and can be fixed there by means of its nut 11 '. Instead of the threaded bolts 9, threaded bores for the arrangement of fastening screws can also be provided in the steel plate 8. The elastomer cushion forming the bearing 6 is an all-round spring with high damping properties. The tensile strength of the bearing 6 is at 293 ° K at approx. 170 ^ / cm ² .

It is heat-resistant up to at least 473 ° K and bonds well with metal.

In order to achieve a good spring and damping effect or earthquake damage to the support system avoid, the arrangement of two bearings 6 per retaining plate 7 is sufficient. The distance between the bearings 6 from each other is specified by the dowel edge spacing regulations. In itself, even one would be correct dimensioned bearing 6 are sufficient, but because of the safety regulations, the multiple arrangement imperative.

The coupling of a unit cell as shown in FIG. 1 is shown, to another takes place via flat bars 5 or the like, so that in each case several cells arranged at a grid spacing from one another form a cable support system form.

In the case of the in FIG. 1 shown double-sided fixing

tion of the carrier 1, the lower bearing 6 takes essentially only static compressive forces and the upper one static tensile forces. Dynamic load conditions are absorbed by the bearings 6, with almost only shear forces are transmitted to the fastening bolts 9, 10 or dowels.

If the bearings 6 are only fastened at the bottom (FIGS. 4 and 7), there is a stiffening in the transition between Retaining plate 4 and carrier 1 in the form of angle profiles 12 or profile iron 13 required, and also a larger bearing spacing is favorable, as in FIG. 4 shown.

No stiffeners are necessary for suspended structures (Fig. 3, 6).

In order to statically only apply compressive forces to the upper bearings 6, the training according to Fig. 9 and 10 provided. After that is at the Structural ceiling one or more profile rails 14, 15 or the like attached, which according to FIG. 9 as open C-profile is formed. One of the legs is screwed to the ceiling and the other one stops the side facing the inside of the profile, the bearing 6. On the top of the bearing is another with the Holding plate 4 connected C-shaped rail attached with its free leg, so that the bearing 6 all Can absorb and reduce vibrations and shocks.

In FIG. 10 the holding plate 4 is in a U-profile-like rail 15 with the interposition of the bearings 6 hooked.

ίο The invention is not limited to the exemplary embodiments limited, but varied in many ways.

Examples of this are the variants according to FIG. 5 and

6. The carrier 1 is shown in FIG. 5 by a horizontal profile support 16 attached to the end attached to a side wall. The holding plate 4 is for this purpose attached to the free end of the support 16.

The F i g. 6 shows two suspended supports 1 which are connected to one another via a support part 17. on a cable duct 18 is placed on the support part 17.

In addition 5 sheets of drawings

Claims (17)

, -Patent claims: 1. Cable support system in earthquake-proof design for nuclear power plants and the like, consisting of, in particular, I-shaped profiles, in Cable run direction with spacing one behind the other vertically to be arranged beams and several these supported, laterally horizontally cantilevered support arms, with the carrier on one side or have holding plates on both sides at their ends, which can be fixed to the structure and furthermore adjacent vertical beams are braced together, characterized in that the braced together carrier (1) form a rigid unit cell of the structure and the Retaining slats (4) with the interposition of spring elements (6) that are effective on all sides and rectified acting damping elements (6) are connected to the building. 2. Cable support system according to claim 1, characterized in that the spring and damping elements (6) are functionally stable at least in the range of 268 ° K to 470 ° K. 3. Cable support system according to claim 1 or 2, characterized in that as a spring and Damping element (6) each have at least one rubber bearing between the retaining plate (4) and the structure is attached. 4. Cable support system according to claim 1 or 2, characterized in that a bearing (6) consists of elastomeric material is arranged as a spring and damping element. 5. Cable support system according to claim 4, characterized in that an elastomeric material Chloroprene rubber or a fluorine-containing rubber is provided, in particular in the temperature range can be subjected to permanent loads from 268 ° K to 398 ° K and can be subjected to loads at 458 ° K for one hour. 6. Cable support system according to one of claims 1 to 5, characterized in that the bearings (6) have a Have attenuation of at least 10%. 7. Cable support system according to one of claims 1 to 6, characterized in that the Gummibzw. Elastomer bearing (S) on its corresponding with the retaining plate (4) or the structure Surface is vulcanized onto a steel plate (7, 8) with outwardly projecting threaded bolts (9, 10) is. 8. Cable support system according to one of claims 1 to 7, characterized in that per holding plate (4) two bearings (6) are arranged. 9. Cable support system according to one of claims 1 to 8, characterized in that the bearings (6) at 473 ° K have a load capacity of 5 * p / cm ² (approx. 0.5 ^N / mm ² ). 10. Cable support system according to one of claims 1 to 9, characterized in that for stiffening of a unit cell, the adjacent beams (1) are connected to one another by flat bars (5). 11. Cable support system according to one of the claims 1 to 10, characterized in that in each case a large number of unit cells are spaced apart from one another are arranged to each other. 12. Cable carrier system according to one of claims 1 to 11, characterized in that the carrier (1) are arranged hanging. 13. Cable support system according to one of claims 1 to 12, characterized in that the bearings (6) can be fastened on the building side indirectly with the interposition of profile rails. 14. Cable support system according to one of claims 1 to 13, characterized in that the ceiling side attachable profile rail or the profile rail part is designed as an open C-profile (14), on the side of which can be fastened to the ceiling opposite leg, the bearing (6) can be fixed on the side facing the profile interior and the corresponding retaining plate (4) of the carrier (1) on the free surface facing the inside of the profile of the bearing (6) can be placed and fastened there 15. Cable support system according to one of claims 1 to 14, characterized in that at only upright attached carrier (1) (F i g. 4 and 6) the holding plate (4) formed over a large area and through Particularly triangular stiffeners (12 or 13) attached between the retaining plate (4) and the carrier (1) is reinforced 16. Cable support system according to one of the claims 1 to 15, characterized in that the respective outer unit cells of a carrier field Carrier (1) of the last cell are stiffened by angle profiles. 17. Cable support system according to one of the claims 1 to 16, characterized in that the Winkelbzw. Flat profiles (5) at the end and / or the carrier (1) Holes at the corresponding fastening points to accommodate the high-strength fastening screws exhibit.