DE1609722B1 - Potting compound for the anchoring of tension members and methods of insertion - Google Patents

Description

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The invention relates to a potting compound made from grains that may seem obvious in solnern and hardening binder for anchoring cases in place of casting metal cold verrung to use plastic casting compounds that can be worked by tension members within the cavity, a support body, e.g. B. an anchor sleeve, so that the problem can only be unspecific Spread like a broom for the anchoring; - Loosen 5 satisfactorily, because such masses always ter bundle of wires. Anchors of this type are z. B. a - albeit often only slight - shrinkage from the German Auslegeschrift 1193 226 known. In addition, the wires run through the Zugnach which consists of grains and hardening stress a · - albeit, in turn, binding agent existing casting compound a concrete casting rings - experience a reduction in cross-section. Both is the mass that is used as grout. io causes the wires to stretch under high tensile stress

The invention also relates to a method for. . pulling the sealing out of the potting compound more easily

Introducing the potting compound and finally leaving it as this due to the strength properties

Special training that would be expected with the casting compound to be th of such casting compounds,

anchoring tension members. In addition, all plastics are at high

Concrete as a casting compound is not free from permanent wind exposure, considerable plastic deformation.

appearances; that a shrinkage takes place, conditions show (flow slowly), so that if

indicates that between the aggregate grains they are continuously stressed for long periods of time

made of cement stone, which are unsuitable in the course of hydration power transmission,

the cement will shrink. It is also known per se, the invention is based on the object of this

In gravel concrete, the binder can be added to avoid difficulties, but the advantages

pressing, namely with so-called »Prepact- a metal potting for the power transmission with-

Concrete"; such concrete is retained as a casting compound,

not previously used for anchoring. The invention consists in that within a

It is also known to create a tightly sealed wire bundle in potting compound of the type mentioned above.

Anchor sleeves with a low-melting metal 25 deposited pile of metal grains, the

to shed. Filling in this way through adhesion and anchorage cavity, in itself known

Clamping effect on the wire bundle in a tensile manner, supporting arches between the inner surface of the

closed sleeve is in turn formed again in the well-known support body and the tension members,

ter way, e.g. B. by screwing or clamping the binder holds the metal grains in their

or stable storage only by supporting it with the structure and unites it into a load-bearing

bound. Such anchors are z. B. in the steel-capable support structure. Since the metal grains are in the

Bau-Handbuch, Volume 2, published by Deut-Masse touch, shows the one made from the metal grains and

see Stahlbauverband, Cologne, 1947, p. 547 because the binding agent does not contain any mass

and shown there in Fig. 39. . ._. - shrinkage. Again, the binder is only the

In this known anchoring of wires 35 gaps between the densely mounted body As a result of which the molten potting agent fills, the plastic deformations remain metal caused the wire ends to heat up slightly,

Wire strength not insignificant back. The metal, of which the metal grains are made, is slightly larger when it is cast with metal, for example steel. Since the grains blow through the bubbles (voids), which are tightly enclosed by filling the fine binding agent, cavities need to be impaired with casting metal and expensive rust- or corrosion-proof alloys and thus "the even connection of all wires is achieved. Depending on the particular one." Requirements of the heavy-duty. Experience has shown that even in the case of a turn, however, softer metals are also more often used, individual wires than steel and even lead the later occurring pressure to undesired force redistribution achieved within the a particularly tight storage.
Wire bundle leads and the security of anchoring Different embodiments result, depending on the reduction. It has also been shown that whether the metal grains have a spherical shape or a mediated transition of the wires into the casting - have rounded, elongated shape or are angular, metal the load-bearing capacity at this point compared to 50. With angular metal grains can often be advantageous repeated loads (fatigue strength) mutual interlocking can be achieved,
considerably diminishes. The grain size is expediently between 0.1

Just the fatigue strength of the anchoring and 5 mm; In special cases it is also possible to use larger metal grains economically. In general, wire bundles are of particular importance. Wire 55 is used grains from below are essentially bundles z. B. as suspension cables of suspension bridges borrowed the same size. But it is also possible, or with the stay cable mixtures often built today, to use graded grain sizes that use bridges. Because they are getting smaller and smaller, they are particularly void-free. When introducing the dead weight of modern bridge construction casting compound, care must be taken to ensure that the grain gradation with little voids and the steadily increasing traffic load is not disturbed,
The suspension cables are subject to constant repetition. One embodiment is characterized by the use of large changes in tension that are greater than that of a binding agent made of reaction-hardening synthetic fatigue strength and can thus lead to permanent materials, preferably from the group of breaks in the anchoring area. _y of epoxy resins, polyester resins or polyurethane

Diqser.v appearances, -.require a larger 6g resin. In another embodiment, a

Dimensioning of the wire frame as the actual binding agent from the group of elastomeric materials

Wire strength corresponds to what additional costs and uses. Another embodiment is

brings additional construction problems. a binder from the group of thermoplastic

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To use fabrics, yet another in that one length pressed across. The wires give with growing inorganic binder, namely a cement tensile force and thus increasing transverse pressure Suspension is used. To the thermoplastic forces more and more along their outer surface on the In addition to synthetic resins, masses also include bitumen and surrounding support structures. This is a relative bad luck and the like. A cement suspension is particularly suitable especially as a binding agent, if later none is very beneficial for the continuous vibration load Vibration loads occur. Load capacity of the wires affects.

The invention also resides in a method for shaping the wire ends as explained

Introducing a potting compound of the type described and suitable design of the inner surfaces of the in the anchoring cavity, which thereby gekenn- io support body, z. B. a surrounding sleeve, the one is drawn is that first the metal grains in the hollow results in the corresponding core shape, the from When poured into the room and preferably shaken, the amount of force to be taken over is so small that what keeps the binder in a liquid state, that the influence of the plastic deformable below is introduced forth into the cavity. The unity of the hardened or set binder shaking is used to achieve the highest storage density. 15 remains meaningless.

Instead of shaking, especially in the case of elongated order, the formation of the metal pressing

Metal grains a dense or orderly storage of the grains of the casting compound also secured pressure can be achieved magnetically. The strive to encourage the later move from The stress of the anchored links introduced in the liquid state below as load-bearing Binder fills the cavities between 20 ascending, it may be appropriate to use the z. B. in a the metal grains until it conically auserst on the surface of the steel sleeve formed anchoring space filled and then compacted metal zubilden in such a way that it is in the direction of the granules appear. the tensile forces acting on the links to be anchored

Another inventive method for rejuvenating. About a strong compression of the grain pack To achieve the introduction of a potting compound of the 25 described, however, it can also be expedient to use the Type in the anchoring cavity is thereby- wall surfaces of a conical anchoring space, indicates that the metal grains in the liquid z. B. an anchoring sleeve, with a non-stick gem to treat binders in a thixotropic state. It is thereby achieved that are mixed in and the so produced by acting on the anchored links Mixture (suspension) in the anchoring cavity 30 pull the anchoring wedge deeper into the conical is introduced. This prevents the anchoring space from being drawn in and the transverse die Metal grains too fast, d. H. before the pressure is increased in the anchoring area, mix the metal grains with the binding agent. As mentioned briefly above, the displaced person needs Potting compound in the anchoring cavity is not made from a uniform mixture of potting compound is introduced, discontinue. After the introduction of the 35 metal, in particular steel, grains and binding the metal grains and the liquid or medium, but there can be additional In the thixotropic state, the binder has advantageous effects through the use of protruding Achieve casting compound in the anchoring hollow * of stepped compounds. To the graduation in one room will produce the settling of the metal grains again fan way, you can z. B. Advantageously supported by shaking. In this way 40 anchor sleeves for wire bundles according to preliminary this results in a tight storage and a mutual fixing of the spread wire ends with the he support the metal grains. Hang the wider cone down and through

One can see the power transmission from the one above opening initially steel balls Wires one with the potting according to the invention of z. B. 2.5 mm in diameter to the filling of the Let the mass of anchored wire bundle trickle in two fifths of the way around the cavity. then giving support body, which, when it is not made of concrete, becomes smaller balls of, for example, 1.5 mm of the structure itself is formed, for. B. from a diameter up to the filling of four fifths of the Steel sleeve may exist, roughly as follows, introduced into the cavity and shaken into it place. brought tightest storage. Then will

Under the load, a displacement of the 50 then begins through an opening at the bottom Wires opposite the support body, liquid reaction-hardening binder is introduced, and immediately a blocking effect. In the densely stored, so much, until all the cavities of the anchoring metaUkorn heap struts are formed between space-filled.

It is achieved in this way that the extremely soft metal grains transversely to the pressure direction 55 through sensitive wires in the area of the exit the binder is prevented. The locking opening only in the soft compared to steel Effect is increased if, as it is, sit in more plastic binders and in this Kriti-training of the invention is provided that with the see area no pressure whatsoever by the steel balls Potting compound after the occurrence according to the invention. The gradual transition from drive tension members to be anchored, namely wires, 60 flexible plastic mass to tightly packed steel rods, Bolt or the like in their ball compound in the potting compound is a 'a longer way lying area, preferably at its end, an extending, particularly favorable introduction of force and Changes in cross-section that prevent sliding, e.g. B. thus achieved such a high oscillation range, as in Thickenings or other profiles or white metal casting have not yet been achieved have lungs. 65 could.

As a result of the generally oblique to the pulling direction The drawing shows various design

the struts running through the wires are the shapes of the potting compound according to the invention Wires on a large part of their anchoring produced by the method according to the invention

Anchoring of members designed according to the invention to be anchored.

Fig. 1, 3 and 5 represent longitudinal sections through anchors and

Fig. 2 and 4 associated cross-sections through the represent the lower areas of the anchorage bodies.

In the example of FIGS. 1 and 2, there is a bundle of wires 1 in a cylindrical recess 13 of a component? anchored from concrete. The wires 1 of the wire bundle are spread in the anchoring area delimited by the walls 6 of the recess 13 and with thickenings at their ends 2 provided. The cavity formed by the cylindrical recess 13 is initially of up with metal grains up to one by calculation or try certain height filled. Then this metal grain filling is treated in such a way that to ensure that the grains are stored tightly, the filling is preferably shaken. then is from below through a provided in an end plate 14 filler opening S into the Cavity 13 pressed in. The binder fills all voids between the metal core and the in these embedded spread wires 1 out.

In the upper region of the wire bundle in Fig. 1, in which the wires 1 are not or only slightly spread, the wire bundle goes through a cylindrical one Recess 15 of the component 7 therethrough, which has a smaller diameter than the recess 13. The anchoring compound made of metal grains and binding agent extends into this area of the recess 15 not in. Rather, the recess 15 is provided with a filling 4 consisting only of binding agent filled in, which embeds the wires 1.

In the example according to FIGS. 3 and 4, a special steel sleeve 9 to be inserted into a structure is provided in which the wires 1 of a wire bundle are in turn anchored. The wires 1 are provided with corrugations 8 in the region of their spread ends, which lie in the cavity 16 formed by the sleeve 9 and delimited by walls 6 '. The anchoring cavity 16 is filled with metal grains from above up to approximately the point where the wires 1 of the wire bundle begin to spread. The binding agent is then pressed in through the filling opening 5 ' provided above the bottom of the sleeve 9. The binder rises to the top of the sleeve9. The cross-hatched area 3 in FIGS. 1 to 4 is filled with the casting compound formed from metal grains and binding agent, whereas the single hatched area is filled with a filling consisting only of binding agent. Against the force occurring in the direction of the arrow when the wires 1 are subjected to tensile stress, the anchoring sleeve 9 is supported on its upper side in the structure, which exerts the reaction forces also indicated by arrows on the sleeve. In its upper area, in which the wires 1 pass through the sleeve to the outside, the sleeve opening is narrower than in the area of the cavity 16.

In a third exemplary embodiment according to FIG. 5, an anchor sleeve 12 is provided which is conical on the inside and, in its upper part in FIG. 5, on the outside as well. The wires 1 of the wire bundle to be anchored, the. are spread within the korüschen cavity enclosed by the sleeve 12, have at their ends multiply arranged thickenings 2 'or thickenings U _{3 in} front of which washers 17 are placed. The area 3 with cross-hatching in FIG. 5 is filled with anchoring compound, the single-hatched area 4 is only filled with binding agent. The binding agent is pressed in through the opening 5 ". Against tensile stress on the wires 1 in the direction of the arrow shown, the anchoring sleeve 12 is held from its lower side in FIG. 5 by a pull rod 10 screwed into it that the embedment length of the individual wires 1 in the potting compound can be selected to be of different sizes.

Claims (11)

Patent claims: 1. Potting compound made from grains and hardening binder for anchoring tension members within the cavity of a support body, e.g. B. an anchor sleeve, especially for anchoring Wire bundle spread out in the manner of a broom, characterized in that within the casting compound there is a tightly mounted pile --_-_ of metal grains, the anchoring cavity filling, in a manner known per se, supporting arches between the inner surface of the supporting body and forms the tension members. 2. Potting compound according to claim 1, characterized in that the metal grains are spherical .to have. 3. casting compound according to claim 1, characterized in that that the metal grains have a rounded, elongated shape. 4. casting compound according to claim 1, characterized in that that the metal grains are angular. 5. Potting compound according to one of claims 1 to 4, characterized in that a binder from reaction-hardening plastics is used, preferably from the group of Epoxy resins, polyester resins or polyurethane resins, 6. Potting compound according to one of claims 1 to 4, characterized in that a binder from the group of elastomeric substances is used. 7. Potting compound according to one of claims 1 to 4, characterized in that a binder from the group of thermoplastic materials is used. 8. potting compound according to one of claims 1 -... to-4, - characterized in that an inorganic Binder, namely cement suspension, is used. 9. The method for introducing the potting compound according to one of the preceding claims in the Anchoring hollow, characterized in that the metal grains are first poured into the cavity and preferably vibrated, after which the binder in the liquid state of is introduced below into the cavity. 10. A method for introducing the potting compound according to one of the preceding claims in the anchoring cavity, characterized in that the metal grains in the in liquid or thixotropic state located binders are mixed in and the so produced Mixture (suspension) is introduced into the anchoring cavity. 11. With the potting compound according to claim 1 or one of claims 2 to 8 according to the method according to claim 9 or 10 to anchoring tension members, characterized in that the tension members, namely wires, rods, bolts or the like in its area lying in the potting compound, preferably at its end Changes in cross-section that prevent sliding, e.g. B. thickenings have. 1 sheet of drawings COP *