NO333274B1 - Spacer bars for joining a stop railing's opposite side sections. - Google Patents

Abstract

Spacer (1) for joining opposite side sections (23a, 23b) of a casting formwork (21). where the distance strut (1) is provided with a central part (3) and two strut end parts (5a, 5b), and where at least one contact surface (7) is formed in the transition between the central part (3) and each strut end part (5a, 5b) which is designed to rest against an inner side surface (23c) on the side sections (23a, 23b), and where the strut end parts (5a, 5b) comprise facilities (9) for wedge devices (11) for fixing the side sections of the casting formwork (21) ( 23a, 23b), where the spacer (1) comprises a tensile stem (2) and an enclosing mantle (2a), and where the middle part (3) and the stem's (2) mantle (2a) are formed as a continuous structure, the stem (2), the mantle (2a) and the middle part (3) are made of non-corrosive materials.

Description

SPACER BRACKET FOR JOINING OPPOSITE SIDE SECTIONS OF A CAST FORMWORK

The invention relates to a spacer for connecting opposite sections in a cast formwork, in particular a cast formwork for concrete. More specifically, the invention relates to a spacer provided with a central part which is designed to form supporting contact surfaces against the inner surfaces of the formwork in order to maintain a predetermined distance between the formwork sides, and that the central part is designed to be retained in the solidified casting material in order to form attachment points in the concrete on in such a way that good adhesion is ensured between the concrete and the spacer to prevent moisture from penetrating along the strut and causing damage to the concrete, as well as by good thermal technical properties to prevent condensation from forming at the end of the spacer, as the spacer is formed in one piece from a non -corrosive material, preferably a composite material.

In what follows, the casting material is referred to as "concrete", and other casting process-related designations known from concrete casting are also used in this presentation. The invention is nevertheless not limited to only formwork that is to be filled with concrete, but also relates to formwork that is used when casting building structures with other casting materials.

When casting with concrete, spacers must be used to hold the formwork in place, that is to prevent the distance between two opposite formwork sections that are to delimit, for example, a wall, changing when the formwork is loaded by push-back or by the pressure from the plastic concrete being filled in the formwork. Spacer struts are placed at relatively regular intervals and fix the opposite formwork sections with a distance determined by the spacer strut's dimension. At the same time, the spacers are locked with wedges against braces that extend along the outside of the formwork.

Spacer struts according to known techniques are made of steel with spacer pieces, which are arranged to rest against the inner wall surface of the formwork sections, made of plastic, threaded onto the strut during the production process and positioned axially on the strut by abutting each of the extended parts of the strut or equivalent. After the concrete has set and the formwork has been torn, the protruding end parts of the spacers are broken off by bending them at a weakened part located at the spacers. The fracture surface is open in the wall surface, and the spacers, which often have a conical shape with their widest part facing outwards, often fall out. There is a need to sand the wall surface at each spacer, partly to cover the fracture surface, partly to fill the recess left by the spacer. This is labor-intensive and expensive. The biggest disadvantage of the known technique is, however, that the part of the spacer that is inside the concrete structure constitutes an entrance for moisture. The moisture penetrates the concrete structure and comes into contact with the reinforcement, which is partly located in the immediate vicinity of or in direct contact with the spacer. The reinforcement corrodes, the reinforcement strength weakens, the adhesion between concrete and reinforcement weakens and the concrete peels off due to corroded steel (rust coating) swelling compared to non-corroded steel. Corrosion also occurs on the spacer.

Also in conditions where a concrete structure is not in direct contact with water, according to known technology, spacer bars will cause inconvenience, as the thermal properties of the steel cause the spacer to function as a cold bridge, so that with a large temperature gradient across the cross-section of the concrete structure, condensation easily forms on the hot since. This moisture creates various maintenance challenges, caused by the moisture directly or by rust formation on the spacer.

In concrete structures that must hold a liquid, i.e.

prevent the liquid from penetrating in or out, the spacers will often be a source of leakage along the spacers due to, among other things, poor adhesion between steel and concrete.

Another problem with known technology is the distance struts' inability to precisely place reinforcement in the strut's axial direction when the reinforcement is placed directly on the spacer struts. Distance struts according to prior art lack means for this.

From US 3,430,914, a formwork brace made of metal is known, provided with diabolo-shaped distance pieces, where the outer part of the piece can be removed if necessary, and where the diabolo shape ensures that the piece does not accidentally detach from the wall. A plastic plug is also described for sealing the center hole in the spacer after the rod end has been removed in a known manner. Conical filler plugs made of wood and ceramics are also described. The brace exhibits the above-described disadvantages regarding corrosion.

From NO 19980475, a formwork brace is known, where spacers made of plastic have one or more planar partial surfaces in the peripheral surface to effect good adhesion of plaster when the holes after the spacers are to be sealed. The brace exhibits the above-described disadvantages regarding corrosion.

The purpose of the invention is to remedy or to reduce at least one of the disadvantages of known technology.

The purpose is achieved by features that are stated in the description below and in subsequent patent claims.

The invention relates to a distance brace made of non-corrosive materials, preferably composite materials, where a middle part which exhibits opposing contact surfaces is arranged to lie supportingly against the inside of a formwork section, and a brace stem forms a coherent structure. In addition to showing the aforementioned construction surfaces, the middle part can also include support and attachment parts for other building materials as well as elements that increase adhesion to the surrounding concrete and/or reduce the possibility of water penetrating along the spacer. After the formwork has been removed, the protruding strut end parts can be cut off in any direction

position with a suitable cutting tool, such as pliers.

Thereby, the distance strut according to the invention exhibits improved properties in several areas: no corrosion damage occurs on the part of the formwork strut which remains in concrete structures;

the continuous, non-corrosive strut structure with good adhesion to the surrounding concrete prevents water from penetrating into or through the concrete construction in channels formed along the distance strut, whereby the strut according to the invention thereby contributes to a concrete construction with better waterproofing properties as well as a concrete construction that exhibits less risk for rust formation on the rebar; the middle part of the strut can be shaped with minimal cost to form a long

range of positioning and fastening details for reinforcement and internal insulation in plate form; the middle part of the strut can be designed with radial anchoring elements which prevent the spacer strut from loosening from the surrounding solidified concrete under torsional stress, and the continuous plug formed by the remaining part of the spacer strut can thus function as mounting brackets for external building materials by the strut's continuous stem being suitable as, for example, screw fastening; the thermal conductivity of the strut materials is small compared to that of the concrete structure, and the problem of condensation at the spacer struts is eliminated;

protruding end parts of the distance strut can be used for mounting superimposed building materials, for example insulation material in plate form, by feeding the material over the protruding end parts and securing them with suitable locking elements before the excess length of the end parts is cut off; and there are no parts of the spacer that, after the formwork has been removed, can fall out of the cast construction and thereby cause a need for surface repair by plastering pits with mortar, inserting plugs, etc.

Any fasteners for attaching building materials to the spacer are preferably also made of a non-corrosive material.

The invention relates more particularly to a spacer for joining the opposite side sections of a casting formwork, where the spacer is provided with a tensile stem with an enclosing mantle, and where in the transition between a middle part and each of two rod end parts, at least one contact surface is formed which is arranged to rest against an internal side surface of the side sections, and where the strut end parts comprise cantilevered installations for wedge devices for fixing the cast formwork's side sections, characterized in that the stem's mantle with cross-sectional extensions form the middle part and the at least one bearing surface, the middle part and the stem's mantle being formed as a continuous, homogeneous structure formed of non-corrosive materials surrounding a core formed of a tensile fiber material.

The spacer is preferably made of a composite material.

The mantle and the middle part are advantageously made of the same type of material.

The mantle and the middle part are preferably joined by fusion of the material forming the mantle and the material forming the middle part. Alternatively, the mantle and the middle part are joined by gluing.

The central part is preferably provided with means for non-detachable engagement with an enclosing casting material when this has been filled in the casting formwork and has solidified.

The middle part and the trunk part surrounding the middle part are advantageously adapted to form a watertight, non-detachable, continuous plug in a pre-cast construction.

The installation surface is preferably formed by the middle part showing an extended cross-section towards its installation parts.

At least one part of the central part advantageously exhibits a cross-section which, when the cross-section lies perpendicular to the central axis of the spacer, exhibits a non-circular shape.

The central part is advantageously provided with a plurality of concentric cross-sectional extensions.

The middle part is advantageously arranged to be able to receive and hold one or more locking means for a plate-shaped building material, for example an insulating material, the essentially annular grooves being complementary to a part of the locking means.

The locking means are advantageously made of a non-corrosive material.

The middle part of the spacer advantageously comprises one or

several means arranged to be able to receive a reinforcing means, preferably in the form of one or more substantially annular grooves.

The essentially annular grooves advantageously have a trapezoidal cross-section with the smallest width at the bottom of the groove, and where the side edges of the groove exhibit the same angle of inclination in relation to the central axis of the spacer.

The middle part of the spacer is advantageously designed to be able to receive one or more fastening means for fixing the reinforcing means.

The fastening means for fixing the reinforcing means is advantageously made of a non-corrosive material.

The stagger end part is preferably designed to be able to receive one or more fixing pieces for retaining a plate-like building material, for example an insulation material.

The fastening piece advantageously comprises means for releasable connection with the jacket surface of the strut end part.

The fixing piece is advantageously provided with a plurality of springing fingers which extend from a peripheral part and in a radial direction towards a central opening.

The fastening piece is preferably made of a non-corrosive material.

The thermal conductivity of the spacer is advantageously less than the thermal conductivity of the enclosing, pre-cast construction.

In what follows, a non-limiting example of a preferred embodiment is described which is illustrated in the accompanying drawings, where:

Fig. 1 shows a perspective sketch of a spacer according to the invention; Fig. 2 shows a perspective sketch on a larger scale of a locking disc for the distance strut according to the invention; Fig. 3 shows a perspective sketch of a fastening piece for the distance strut according to the invention; Fig. 4 shows a perspective sketch on a smaller scale of a partially assembled formwork where the distance strut connects opposite formwork sections and positions rebar and insulation material; Fig. 5 shows on a smaller scale a ready-cast wall section where a side surface is applied with insulating material which is held in place by means of the spacer according to the invention; and Fig. 6 shows a perspective sketch of a further design example of a central part of the spacer according to the invention.

A distance strut 1 comprises a stem 2 with a jacket 2a, a middle part 3 and two strut end parts 5a, 5b. In each of the transitions between the middle part 3 and the rod end parts 5a, 5b, the middle part exhibits a cross-sectional extension 7a, each of which forms a contact surface 7.

The spacer 1 is made of composite material, the stem 2 being reinforced in a known manner with a tensile fiber material and surrounded by a binding material which forms the stem 2's mantle 2a. The middle part 3 can be made of the same type of material as the mantle 2a.

In a first embodiment shown in fig. 1, the cross-sectional extension 7a forms a truncated cone, where a bottom surface 7b faces the central part 3. The central axis of the cone coincides with the central axis of the spacer 1. A top surface faces the adjacent strut end portion 5a, respectively 5b, and is placed perpendicular to the center axis of the spacer strut 1 and constitutes the contact surface 7. The bottom surface 7b has a non-circular shape, as four segment surfaces 7c lie parallel to the center axis of the spacer strut 1 in the direction of the contact surface 7, as the segment surfaces 7c extends into a side surface 7d. Two opposite segment surfaces 7c are mutually parallel, the bottom surface 7b forming a square with rounded corners.

In another embodiment shown in fig. 6, the contact surface 7 is formed as a first four-armed cross 57b. A second four-armed cross 57a with greater arm length is formed at a distance from the first cross 57b, and four radially and diametrically opposed protruding ribs 58a extend axially between the arms 59a, 59b of the crosses 57a, 57b. In addition, this embodiment exhibits several concentric, circular cross-sectional extensions which form fastening and sealing ribs 58b.

The middle part 3 is joined in a sealing manner to the stem 2, since liquid, for example water, cannot penetrate in the axial direction from the end parts 5a, 5b and towards the middle part 3, because the passage of the stem 2 through the middle part 3 constitutes a tight connection. The tight connection is created by the material in the mantle 2a and the middle part 3 having melted together during manufacture or they are joined with, for example, glue which forms a watertight joint between the stem 2 and the middle part 3.

Each rod end part 5a, 5b is provided at its outer end with a cantilevered device 9 for a wedge device 11 for fixing the side sections 23a, 23b of a casting formwork 21.

The central part 3 is provided with several grooves 3a which extend around the entire periphery of the central part and are designed to receive a locking disc 13 (see fig. 2 and 4) for positioning and retaining a plate-shaped embedding material 15 (see fig. 4), for example an insulating material.

The locking disc 13 is arranged to be able to be inserted onto the central part 3, preferably in a radial direction, by a sector opening 13a leading into an essentially centrically placed, circular center hole 13b. In order to ensure that the locking disc 13 does not fall off after it is mounted on the spacer 1, the thickness of the locking disc 13, at least at the center hole 13b, forms a press fit with the side edges of the groove 3a of the central portion 3, or the periphery of the center hole 13b forms a press fit with the 3a bottom surface of the track.

The middle part 3 is also provided with several grooves 3b which extend around the entire periphery of the middle part and which have a transverse profile which is designed to receive a reinforcing means 25 in the form of rebar or the like, the cross-section of the groove being, for example, trapezoidal.

The distance strut 1 can expediently also comprise an attachment piece 17 (see figs 3 and 5) which is arranged to be fixed on a cut-off strut end part 5a, 5b which protrudes from a solidified casting material 31, for example a cast wall, after the formwork 21 has been removed , the attachment piece 17 being provided with a number of radially oriented, springing fingers 17a (see in particular fig. 3) which extend from a peripheral part 17b and in the radial direction towards a central opening 17c, each finger 17a being separated from an adjacent finger by a slot 17d extends in the radial direction from the center opening 17c and to a circular opening 17e in the peripheral portion 17b of the attachment piece. The center opening 17c has a diameter which is smaller than the diameter of the rod end parts 5a, 5b to ensure that the attachment piece 17 is held in a desired position on the rod end part 5a, 5b by the springing fingers 17a being in tension.

At least the cantilever 9 and stem 2 of the spacer 1, i.e. the strut end parts 5a, 5b and the continuous core in the middle part 3, are made of a composite material with a tensile strength large enough to absorb the relevant tensile stresses as the spacer 1 for a casting formwork 21 exposed to during assembly and when filling in the casting material 31, for example concrete, in the formwork space. The composite material has a fiber reinforcement and a binding material that does not transport water or corrode. The middle part 3 and the stem 2 are made of a material which is designed for fixing a fastening means, for example a nail or a screw. The strut end parts 5a, 5b are designed to be able to be cut off at any point between the cantilever 9 and the contact surface 7 using a suitable tool.

The entire spacer 1 with cantilevers 9 and middle part 3 can be formed in a molding operation.

The locking disc 13 and the fastening piece 17 are advantageously made of a non-corrosive material, for example a plastic material.

The spacer 1 is mounted in a manner known per se during the construction of the formwork 21 (see Fig. 4), with the side sections 23a being assembled before the reinforcing means 25 are then placed and locked off in relation to each other and the formwork 21. Any insulation material 15 for embedding is attached by using the locking washers 13 before the opposite side sections 23b are assembled and the formwork is closed and secured by the wedge devices 11 being mounted on the spacers 1 within the cantilevers 9 and the spacers 1 being tensioned. During tensioning, the contact surface 7 rests against an inner side surface 23c of the side sections 23a, 23b of the formwork 21.

After the casting material 31, for example the concrete, has been filled in the formwork and has solidified, the formwork 21 is removed in a manner known per se and the protruding strut end portions 5a, 5b of the spacer struts 1 are cut off.

If the strut end parts 5a, 5b are to be used for fastening plate-shaped building materials 33, for example insulation boards, on one or both sides of the pre-cast construction 31, these are attached by inserting the fixing pieces 17 (see Fig. 5) onto the strut end parts 5a, 5b to against the plates 33 after the cantilever 9 and a suitable length of the rod end parts 5a, 5b have been cut off.

If building materials are to be fixed by, for example, screwing or nailing, this can be done by fixing the fastening means in the middle part 3 through the center of the construction surface 7, which lies flush with the outer surface of the cast structure 31 and is made up of the cut-off trunk 2. Because of the central part 3's continuous, axial extent and partially non-circular cross-section, they are held in a secure grip in the solidified casting material 31 both under axial load and radial rotational load.

Due to the choice of material, the spacer 1 will not corrode and lead water into the embedded reinforcement or through the cast construction. The auxiliaries 3a, 3b, 13 ensure a better positioning of insulation materials 15 and reinforcement 25 in the cast construction, which results in more efficient utilization of the materials and better quality of the cast construction.

The possibility of using the spacer strut end parts 5a, 5b and the middle part's contact surface 7 when mounting superimposed building materials adds beneficial additional functions to the spacer strut 1.

Claims (22)

1. Spacer (1) for joining the opposite side sections (23a, 23b) of a cast formwork (21), where the spacer (1) is provided with a tensile stem (2) with an enclosing mantle (2a), and where in the transition between a central part (3) and each of two rod end parts (5a, 5b) is formed with at least one contact surface (7) which is designed to rest against an inner side surface (23c) on the side sections (23a, 23b), and where the strut end parts (5a, 5b) comprise cantilevered facilities (9) for wedge devices (11) for fixing the side sections (23a, 23b) of the casting formwork (21), characterized in that the stem (2) mantle (2a) with cross-sectional extensions (7a, 7b) forms the central part (3) and the at least one contact surface (7), the central part (3) and the stem (2) mantle (2a) being formed as a continuous, homogeneous structure formed from non-corrosive materials that encloses a core formed from a tensile fiber material. 2. Spacer strut (1) according to claim 1, characterized in that the spacer strut (1) is made of a composite material. 3. Spacer (1) according to claims 1-2, characterized in that the mantle (2a) and the middle part (3) are made of the same type of material. 4. Spacer (1) according to claims 1-4, characterized in that the shell (2a) and the middle part (3) are joined by fusing the material that forms the shell (2a) and the material that forms the middle part (3). 5. Spacer (1) according to claim 1, characterized in that the mantle (2a) and the middle part (3) are joined by gluing. 6. Spacer (1) according to claim 1, characterized in that the middle part (3) is provided with means (7c, 7d, 57a, 57b, 58a, 58b) for non-detachable engagement with an enclosing casting material (31) when this is filled in the formwork (21) and has solidified. 7. Spacer (1) according to claim 1, characterized in that the central part (3) and the stem part (2) enclosed by the central part (3) are designed to form a watertight, non-detachable, continuous plug in a precast construction (31) . 8. Spacer strut (1) according to claim 1, characterized in that the contact surface (7) is formed by the middle part (3) showing an extended cross-section (7a, 57b) towards its end parts. 9. Spacer strut (1) according to claim 1, characterized in that at least one part of the middle part (3) exhibits a cross-section which, when the cross-section is perpendicular to the center axis of the spacer strut (1), exhibits a non-circular shape. 10. Spacer strut (1) according to claim 1, characterized in that the middle part (3) is provided with a plurality of concentric cross-sectional extensions (58b). 11. Spacer strut (1) according to claim 1, characterized in that the middle part (3) comprises one or more essentially annular grooves (3a) which are designed to be able to receive and retain in the radial and axial direction one or more locking means (13 ) for a plate-shaped building material (15), for example an insulation material, the essentially annular grooves (3a) being complementary to a part (13b) of the locking means (13). 12. Spacer (1) according to claim 12, characterized in that the locking means (13) are made of a non-corrosive material. 13. Spacer strut (1) according to claim 1, characterized in that the middle part (3) of the spacer strut (1) comprises one or more means (3b) arranged to be able to receive a reinforcing means (25). 14. Spacer (1) according to claim 1, characterized in that the middle part (3) is provided with one or more substantially annular grooves (3b). 15. Spacer (1) according to claim 15, characterized in that the essentially annular grooves (3b) have a trapezoidal cross-section with the smallest width at the bottom of the groove (3b), and where the side edges of the groove (3b) show the same angle of inclination in relation to center axis of the spacer (1). 16. Spacer strut (1) according to claim 1, characterized in that the middle part (3) of the spacer strut (1) is designed to be able to receive one or more fastening means for fixing the reinforcing means (25). 17. Spacer (1) according to claim 17, characterized in that the fastening means for fixing the reinforcing means (25) is made of a non-corrosive material. 18. Spacer brace (1) according to claim 1, characterized in that the brace end portion (5a, 5b) is designed to be able to receive one or more fasteners (17) for holding a plate-shaped building material (33), for example an insulation material. 19. Spacer strut (1) according to claim 19, characterized in that the attachment piece (17) comprises means (17a) for releasable connection with the outer surface of the strut end part (5a, 5b). 20. Spacer strut (1) according to claim 19, characterized in that the attachment piece (17) is provided with a plurality of springing fingers (17a) which extend from a peripheral part (17b) and in a radial direction towards a central opening (17c). 21. Spacer (1) according to claim 19, characterized in that the attachment piece (17) is made of a non-corrosive material. 22. Spacer strut (1) according to claim 1, characterized in that the thermal conductivity of the spacer strut (1) is less than the thermal conductivity of the enclosing, precast construction.