DE202014105353U1 - Hollow wall anchor - Google Patents

Abstract

Hollow wall anchor (10) consisting of a metal part with two end sections (2) which are each connectable to one of two parallel plates (21, 22) of a cavity wall (20), and a connection section (1) connecting the two end sections (2 ) integrally with each other, characterized in that the transport anchor consists of an angled flat steel, and the end portions (2) and the connecting portion (1) of the hollow wall anchor (10) each have at least one transverse bore (3, 4).

Description

The present invention relates to a hollow wall anchor consisting of a metal part with two end portions, which are each connectable to one of two parallel plates of a hollow wall, and a connecting portion, which integrally connects the two end portions together.

Hollow walls consist of at least two parallel and mutually spaced solid plates, which are partially integrated into the plates, d. H. In general, cast-in spacers, for example in the form of reinforcing elements or reinforcement cages are kept parallel to each other at a distance, so that a cavity is formed between the plates. The cavity means compared to a solid wall, a material and weight savings nd also contributes to the heat and sound insulation. The plates are usually made of concrete, but can in principle also consist of any other pourable and curing material. They are "massive" in the sense that they are cast from a flowable material into which other objects, such as the reinforcements and also the hollow wall anchors in question, poured and thus can be firmly integrated, but what small cavities and pores in the plates does not exclude. The cavity between the plates in any case contains reinforcing and connecting elements for the plates, but is not necessarily filled with additional material. As filling material would still be a pourable or stopable heat and or sound insulation material such as, for example in the form of granules of polystyrene or other material or in the form of rock, glass or pulp wool into consideration

The plates themselves have a thickness which is typically between 3 and 8 cm, while the clear distance between the two parallel plates, which form the cavity wall and which are held by reinforcing elements or a reinforcing cage at this distance, a multiple of the thickness of massive plate sections amounts.

Such hollow wall elements are typical prefabricated components, which form partitions between internal spaces, but if necessary can also form supporting walls and exterior walls in buildings. Hollow wall elements or hollow walls, which are composed of one or more hollow wall elements, can have a total of a relatively large wall thickness between, for example, 12 and 36 cm. They offer improved sound and heat insulation protection and have a significantly lower weight than corresponding solid walls. For aligning and for the transport of such hollow walls, the transport anchors in question are used, which are each integrated in a hollow wall element.

Corresponding hollow wall anchors are known in principle and are integrated with their correspondingly extending legs in the solid plates of hollow walls, while the connecting portion of the hollow wall anchor bridges the distance between the solid plates, so that this connecting portion of the hollow wall anchor as an attachment point for a rope a crane hook or The same can be used in order to be able to transport the corresponding cavity wall with the help of the damaged rope or crane hook easier. Advantageously, hollow wafers are mounted in the vicinity of the plate edges, so that the connecting portion of a hollow wall anchor is easily accessible from the respective edge of a cavity wall.

Corresponding hollow wall anchors are in the prior art generally made of structural steel and bent substantially to a U-shape, so that two parallel legs of the U-shape can be poured into one of the two solid plates of a cavity wall, while the U-shaped end face or protrudes laterally into the space between the massive plates from the plate surfaces and can be used as a transport anchor.

For better anchoring of the parallel U-legs in the solid sections of the cavity wall whose free ends are often bent in the plane of the solid plates.

The cross strut is usually also made of structural steel and is welded to the parallel legs or the ends of the U-bend. The cross strut determines the distance between the two U-legs, which are generally poured approximately in the middle of the massive plates, which consist of concrete as a rule.

The conventional transport anchors have the disadvantage that they have for anchoring in the respective plates relatively long and partially bent parallel legs to be securely anchored in the respective plate can. This makes them unwieldy and requires a corresponding amount of material.

Compared to this prior art, the present invention seeks to provide a hollow wall anchor that is easier to produce, requires less material and yet can be safely anchored in the respective plates. In addition, the transport anchor and in handling and transport should be less bulky.

This object is achieved in that the transport anchor consists of an angled flat steel, and the end portions and the connecting portion of the hollow wall anchor each have at least one eye or transverse bore.

Such a hollow wall anchor is much faster and easier to manufacture and store and also easier to handle than conventional hollow wall anchors and is still suitable for hollow walls up to a maximum total weight of about 5000 kg.

The angled legs of the flat steel are in the same plane and can be made for example by punching from a steel plates.

The eyelets in the end portions of the flat steel material can be conveniently used for the passage of a reinforcing steel, which guarantees when casting the end portions of the hollow wall anchor with the relevant reinforcing steel in the concrete for the production of the plate elements secure anchoring of the hollow wall anchor in the plate elements.

For a sufficient load capacity of the hollow wall anchor, the flat steel should have a thickness of at least 5 mm, preferably at least 8 mm, and a width, measured perpendicular to the connecting line from the transverse bores of the end sections to the transverse bore of the connecting section, of at least 30 mm, preferably at least 40 mm exhibit. In order for a reinforcing steel extending through the eyelet of one end portion to have a sufficient distance from the surface of a plate member, the distance of the eyelets in the end portions from the respective free end of the end portion should be less than 20 mm. The diameter of the transverse holes or eyelets in the end sections should be at least 8 mm, so that correspondingly thick reinforcing bars or wires can be passed through these cross holes, while the cross holes in the connecting section through which a hook or carrying cable for lifting and transporting a Cavity wall must be passed, should have a diameter of at least 10 mm, preferably of at least 12 mm.

It is understood that the hollow wall anchor according to the invention can also significantly exceed the minimum dimensions mentioned above, for example, consist of 10 or 12 mm thick flat steel and may have a width of 60 or 80 mm and also the transverse bores in the end portions and the connecting portion may be correspondingly larger and, for example, 15 mm in the end sections and 20 or 30 mm in the connection section.

Corresponding to the angling of the flat steel, the hollow wall anchor in a side view substantially a V-shape.

It is expedient in view of the concrete use of the hollow wall anchor, if the angle between the corresponding V-legs greater than 60 °, preferably greater than 90 °, but is also less than 160 °, this angle is to be measured between the Connecting lines of the center of the transverse bores in the end portions to the center of the transverse bore in the connecting portion, since the vertical load, which receives the cavity wall anchor when transporting a cavity wall, extends at least to a considerable extent substantially along this connecting line in the longitudinal direction of the legs of the angled flat steel material.

Too large an angle between the V-legs beyond 160 ° would possibly cause a strong bending moment in the flat steel, while a small angle between the V-legs would require increased material usage to bridge the distance between the two solid plate elements of a cavity wall ,

On the other hand, a smaller angle between the V elements results in that the hollow wall anchor is essentially loaded by tensile forces which can better prevent possible deformation.

In this respect, an angle between the V-legs in the range between 90 and 160 ° is a good compromise between on the one hand a lower material usage and on the other hand a favorable load mainly by tensile forces.

Furthermore, it is expedient if the end sections of the hollow wall anchor have an end face which runs parallel to the bisector of the angled flat steel material. This leaves between the eyelet, which makes the connection to a reinforcing steel inside a plate member and the outer surface of the plate member over which the end portion of the hollow wall anchor can not protrude, nor enough flat steel material to avoid tearing of the eyelet or transverse bore.

To improve the tensile load and to increase the resistance to deformation due to bending moments, it may be expedient if the maximum width of the flat steel material in the range of Connecting portion is larger than in the end portions, for example, the width of the flat steel material can increase continuously from the end portions to the center of the connecting portion. The V-angle along the outside of the V-shaped hollow wall anchor would then be slightly smaller than the V-angle along the inner edges of the V-shaped hollow wall anchor.

The present invention furthermore relates to a hollow wall, comprising at least two solid plate elements arranged parallel to one another, which are held at a distance from one another by reinforcing elements partially integrated in the plate elements. In order to produce corresponding hollow walls by lower material usage and easier handling of hollow wall anchors cheaper and easier, the invention proposes that the cavity wall has at least one integrated in the plate elements hollow wall anchor according to one of claims 1 to 8.

To produce the cavity wall, the corresponding reinforcement anchors are arranged inside a formwork or together with a corresponding reinforcement cage so that a reinforcing steel extends through the transverse bore or eye in an end portion of the hollow wall anchor. Appropriately, two or more corresponding hollow wall anchors are arranged along at least one end face of such a hollow wall or the hollow wall formwork, so that the eye or transverse bore of the connecting portion is disposed near the end face of the formwork. The angling of the flat steel material ensures that the corresponding end portions with the eyelets for the passage of a reinforcing steel have a larger distance from the end faces of the formwork and ultimately cast in the formwork plate elements caused by the angulation so that they are securely anchored in the plate elements of the cavity wall are. The hollow wall anchor can either be flush with an end face of the cavity wall or slightly offset from the end face of the cavity wall, for example by 1 to 5 cm, from the plane of the end face in the interior of the cavity wall.

If the reinforcing steel passed through the eyelets in the end sections has little play in the corresponding eyelets or transverse bores, an alignment of the hollow wall anchor or of the flat steel from which the hollow wall anchor consists is effectively effected in a plane perpendicular to the nearest end face and the plane defined by the plate members of the cavity wall.

This alignment of the hollow wall anchor ensures that when transporting the cavity wall by means of hooks or ropes, which are passed through the transverse bores in two arranged at a distance on a front side hollow wall anchors, the hollow wall anchor must absorb only tensile loads substantially.

This makes it possible to move and transport relatively heavy hollow walls with the help of the hollow wall anchors with relatively little use of material for the hollow wall anchor.

An inventive use of a hollow wall anchor is the use of the hollow wall anchor described above and defined in claims 1 to 8 in the manufacture of hollow walls with a maximum total weight of 5000 kg.

Further advantages, features and applications of the present invention will become apparent from the description of a preferred embodiment and the accompanying figures.

Show it:

1 an elevation of a hollow wall anchor according to the invention under three different directions,

2 the arrangement of the hollow wall anchor according to the invention in a reinforcement cage for the production of hollow walls.

It can be seen in the plan view in accordance with 1a a hollow wall anchor 10 in the form of an angled flat steel whose end sections 2 one transverse bore each 4 and the two end portions thereof 2 connecting, angled connecting section 1 also a transverse bore 3 having. The end sections 2 go continuously and without the hollow wall anchor 10 recognizable demarcation in the connecting section 1 over and are characterized only by the fact that they represent the later cast into the plate elements sections of the two flat steel legs. The 1b and 1c are views of the narrow sides of the hollow wall anchor according to a view 1a from the right or from the top.

Overall, the hollow wall anchor has 10 the shape of a plane in plan view V-shaped angled flat steel with a thickness of, for example 8th mm and a width b of, for example, 40 to 50 mm. The total length L of the V-shaped legs 1a . 1b , measured from the bisector W of the V-shape to the end faces of the end portions 2 along one of the cross holes 3 . 4 connecting line typically lies between 8 and 15 cm, giving a horizontal distance between the two front sides 5 the end sections 2 from about 14 to 28 cm corresponds, which in turn would correspond approximately to the total thickness of a hollow wall in which such a hollow wall anchor is installed.

The angle α between the two V-legs 1a . 1b which the connecting section 1 define is about 120 to 140 °. The width b of the legs 1a . 1b can, starting from the end faces 5 the end sections 2 in the direction of the center of the connecting section 1 , which by the position of the bisectors 6 the thigh 1a . 1b is defined, continuously increase, to approximately occurring bending moments when transporting a cavity wall on the hollow wall anchor 10 can act to catch even better.

The diameter of the cross holes 4 is expediently only slightly larger than the outer diameter of a corresponding reinforcing steel 33 , the part of a reinforcement cage 30 is and through the cross holes 4 should be passed. On the one hand, this is intended to allow easy passage of the reinforcing steel 33 through the cross holes 4 allow, on the other hand, but also the hollow wall anchor already give a certain support, so that defined by the plane of the flat steel plane of the hollow wall anchor 10 extends substantially perpendicular to both the front side and the wall surface of a corresponding cavity wall, which are defined in the reinforcement cage by the formwork, which prior to casting of the plate elements 21 . 22 the cavity wall the reinforcement cage 30 take up.

The corresponding arrangement of two hollow wall anchors is an example of a section of a reinforcing basket and the dashed lines indicated plates 21 . 22 a cavity wall 20 in 2 shown. The in a (not shown) formwork generally lying arranged reinforcement cage 30 consists of interconnected, for example braided and braced rebars 31 . 32 Partially located in an area of the formwork, which is filled in the manufacture of the cavity wall of concrete and partially bridge the area between the two concrete slabs remaining cavity. The reinforcing steels 31 . 2 and 33 are preferably all together to a reinforcement cage 30 connected with each other.

The hollow wall anchors 10 are effectively part of this reinforcement by dealing with their end sections 2 also in the areas extending from the concrete material of the plates 21 . 22 and, moreover, the space between the plates 21 . 22 through the connecting section 1 bridged. This involves a reinforcing steel 33 of the reinforcement basket 30 through the eyelets 4 the two hollow wall anchors 10 so that the hollow wall anchors 10 in the reinforcement cage are aligned so that by the flat steel material of the hollow wall anchor 10 defined plane perpendicular to the plane of the plates 21 . 22 and at the same time also perpendicular to the upper end side of the cavity wall 20 extends. After pouring two plates 21 . 22 are the hollow wall anchors 10 or their transverse bore 3 easily accessible from the upper end face of the cavity wall, without causing the hollow wall anchor projecting beyond the plane of the end face, which could interfere with the connection of corresponding hollow walls side by side or one above the other.

To transport a cavity wall, a hook or a ring coupling through each of the transverse bores 3 the hollow wall anchor at one end, generally the upper end, a cavity wall 20 passed so that the cavity wall can be lifted in this way and transported on site and installed at a suitable location.

The hollow wall anchor according to the invention is very simple and material-saving to produce and particularly suitable for lighter cavity wall components with a weight up to 5000 Kg, the scope of this hollow wall anchor but can be easily extended to larger and heavier hollow walls by the flat steel material is dimensioned correspondingly larger.

The installation of the hollow wall anchors in a corresponding reinforcement cage is not a major problem, and can already be done in the production of reinforcement cages or the prefabrication of reinforcement cages, since the reinforcing elements in the hollow walls in any case generally made by a grid of vertically crossing reinforcing steels become. If necessary, two additional reinforcing bars could be used 33 be inserted or introduced into the reinforcement cage, which are aligned by aligned transverse bores 4 in the end sections 2 the respective hollow wall anchor 10 extend.

For purposes of the original disclosure, it is to be understood that all such features as will become apparent to those skilled in the art from the present description, drawings and dependent claims, even though they have been specifically described only in connection with certain further features, both individually and can be combined in any combination with other features or feature groups disclosed herein, unless this has been expressly excluded or technical conditions make such combinations impossible or pointless. On the comprehensive, explicit representation of all conceivable combinations of features and the emphasis on the independence of the individual characteristics of each other is omitted here only for the sake of brevity and readability of the description.

Claims (12)

Cavity wall anchor ( 10 ), consisting of a metal part with two end sections ( 2 ), each with one of two parallel plates ( 21 . 22 ) of a cavity wall ( 20 ) and a connection section ( 1 ), which covers the two end sections ( 2 ) in one piece, characterized in that the transport anchor consists of an angled flat steel, and the end sections ( 2 ) as well as the connecting section ( 1 ) of the hollow wall anchor ( 10 ) at least one transverse bore ( 3 . 4 ) exhibit. Hollow wall anchor according to claim 1, characterized in that the flat steel has a thickness of at least 5 mm, preferably at least 8 mm, and a width perpendicular to the connecting line from the transverse bores of the end portions to the transverse bore of the connecting portion of at least 30 mm, preferably at least 40 mm. Hollow wall anchor according to claim 1 or 2, characterized in that the distance of the eyelets in the end portions of the respective free end of the end portion is less than 20 mm Hollow wall anchor according to one of the preceding claims, characterized in that the transverse bores in the end sections have a diameter of at least 8 mm and the transverse bore in the connecting portion has a diameter of at least 10 mm, preferably of at least 12 mm Cavity wall anchor according to one of the preceding claims, characterized in that the flat steel has a V-shape in a side view, Cavity wall anchor according to claim 5, characterized in that the angle between the V-legs ( 1a . 1b ) is greater than 90 °. Hollow wall anchor according to one of the preceding claims, characterized in that the end sections have an end face ( 5 ) which are parallel to the bisector (W) of the angled flat steel material. Cavity wall anchor according to one of the preceding claims, characterized in that the maximum width (b) of the flat steel material in the region of the connecting portion ( 1 ) is larger than at the end sections ( 2 ). Cavity wall ( 20 ), consisting of at least two parallel plate elements ( 21 . 22 ), partially reinforced elements ( 30 . 31 . 32 . 33 ) are kept at a distance from one another, characterized by at least one hollow wall anchor integrated in the plate elements (US Pat. 10 ) according to any one of claims 1-8. Cavity wall according to claim 9, characterized in that in each case at least one reinforcing element ( 33 ) in the interior of a plate element through the transverse bore ( 4 ) in the end section ( 2 ) of a hollow wall anchor extends. Hollow wall according to claim 9 or 10, characterized in that the hollow wall anchor at the edge or the end face ( 40 ) of the cavity wall ( 20 ) is provided without protruding in a side view over the edge of the cavity wall. Use of a hollow wall anchor according to one of claims 1 to 8 for the production of hollow walls ( 20 ) with a maximum total weight of 5000 kg.

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