DE102005041082A1 - Hollow barrier for use in construction site, has reinforcing bars that provide mechanical connection between shells and determine thickness of barrier, and heat insulating layer provided between shells - Google Patents

Abstract

The barrier has shells (2,3), which are separated from one another. Reinforcing bars (5) are arranged for providing a mechanical connection between the shells and for determining the thickness of the barrier. The ends of the bars extend from the outer side of the barrier. A heat insulating layer (4) is continuously provided between the shells. The heat insulating layer fully encloses the outer contours of the reinforcing bars. The bars take up tractive force, which is developed when freshly mixed concrete is molded in the cavity of the barrier. Independent claims are also included for the following: (1) a reinforcing bar for connecting the shells (2) a method for manufacturing a hollow barrier.

Description

The The present invention relates to systems and methods of manufacture of insulated Hollow walls.

in the It is known in the prior art to use prefabricated hollow walls to produce two wall shells made of reinforced concrete, with the wall shells through Systems for absorbing forces in mechanical operative connection. This ensures that that the cavity wall on the construction site retains its shape when poured into the cavity fresh concrete. In these hollow walls are Separate spacers used in the manufacture of the hollow walls the desired Ensure the distance between the wall shells.

To the introduction of the systems for power and the spacer in the first wall shell according to the prior art, several thermal insulation panels applied to the first wall shell, wherein the thermal insulation panels to the systems for power absorption and the spacers that are already in the wall shell and usually in a rectangular grid are arranged between the wall shells, to be adjusted. The thermal insulation panels So they are pieced together and partially cut out to fit the systems of power and adjust the spacers. As a result, however, there is none full Cover the first wall shell through the thermal insulation panels. It remains so that slots or interruptions between the thermal insulation panels, the pouring of fresh concrete in the cavity are also filled by the fresh concrete and so too unwanted Heat transfers, So lead thermal bridges.

It the object of the present invention is to provide a cavity wall, which are produced in a simpler and higher quality way can. In this case, preferably the production costs are reduced become.

These The object is achieved by a Cavity wall according to claim 1 or by a method according to claim 25 solved. The dependent ones claims relate to advantageous embodiments of the invention. The rebar according to claim 10 and the system according to claim 22 solve as well the task of being able to produce a hollow wall in a simpler way.

The Cavity wall according to the invention has a first wall shell and a second wall shell, the spaced from the first wall shell is arranged. The first Wall shell and the second wall shell are interconnected by reinforcing bars connected. According to the invention the reinforcing bars each a mechanical connection between the first wall shell and the second wall shell, while serving for fixing the wall thickness the cavity wall. As a result, these two functions by the inventive rebars achieved in contrast to the prior art, according to which for this Functions different components were provided.

The rebars should such a mechanical connection between the first Wall shell and the second wall shell create that the reinforcing bars absorb the tensile forces can, which arise when fresh concrete in the free space of the cavity wall in standing condition is poured. The male tensile forces depend on it from the height of the cavity of the wall, since with increasing height of the internal pressure of the filled fresh concrete rises on the wall shells. The mechanical connection should however also pressure forces that when installed from the outside can act on the wall, e.g. in the case of wind, water or earth loads.

To the better understanding The invention relates to the method for producing a hollow wall according to the invention shown. First becomes fresh concrete in a form or steel pallet for the production poured in a first wall shell. It then becomes a thermal barrier coating applied to the first wall shell, preferably in one Condition in which the fresh concrete of the first wall shell is not yet tied or solidified. Subsequently, the reinforcing bars according to the invention by the thermal barrier coating introduced into the fresh concrete of the first wall shell, wherein the reinforcing bars Preferably be introduced so far that in each case the ends of the rebars at the bottom of the mold or the steel pallet for the production of first wall shell rest. This will - as will be explained later - a spacer function Fulfills.

The resulting structure consisting of the first wall shell, thermal barrier coating and reinforcing bars protruding from the thermal barrier coating is then set or cured (the final curing can be done weeks later). Subsequently, in turn, fresh concrete is poured into a mold or steel pallet for producing a second wall shell. The first wall shell is then placed over the second wall shell, wherein the protruding reinforcing bars point in the direction of the fresh concrete of the second wall shell. The first wall shell is lowered, so that the reinforcing bars with ih immerse other ends in the fresh concrete of the second wall shell. The reinforcing rods are also preferably located at the bottom of the mold or steel pallet. This ensures that the length of the reinforcing bars determines the total thickness of the cavity wall. Finally, the second wall shell is set so that it solidifies. It is thus obtained a prefabricated cavity wall, the cavity can be filled at the construction site or at the place of destination with fresh concrete.

One considerable advantage of the method described above is that the thermal barrier coating the inventive cavity wall - with Exception of the penetration holes for the reinforcing bars - continuously formed can be. In other words, the thermal barrier coating covers the adjacent wall shell nearly Completely without interruptions (except for the penetration holes for the reinforcing bars). In order to penetrates during filling of Fresh concrete in the cavity no concrete in interruptions of the thermal barrier coating, the so too undesirable heat pipes to lead can, because the thermal barrier coating immediate and fully enclosing on the outer contours the reinforcing bars is applied. In this way, a higher-quality cavity wall with a significantly better thermal insulation properties receive.

At It should be noted that according to the present invention instead of a thermal barrier coating also a sound insulation layer can be provided if the effect of sound insulation Wall should stand in the foreground.

Around the insertion of the reinforcing bars is preferably provided, in the thermal barrier coating holes for the Passage of reinforcing bars work in before the thermal barrier coating is applied to the first wall shell. These holes can then also as a guide for the rebars serve to make them as rectangular as possible are arranged to the first wall shell. For this purpose, the holes are preferably slightly smaller than the reinforcing bars designed to form a or adhesion between the thermal barrier coating and the rebars to ensure. Furthermore This ensures that fresh concrete is at the construction site is poured into the cavity, not in any gaps between rebars and thermal barrier coating can penetrate. In particular, a penetration of concrete up lead to the wall shell to a significant undesirable thermal bridge.

at The inventive method, it is particularly advantageous if the reinforcing bars from a rod material that is a multiple of the strength of the Cavity wall corresponds to be produced. The rod material can be used for the production the cavity wall are cut into individual reinforcing bars, namely before preferably with a length, the strength of the corresponds to hollow wall to be produced. In this way, the Production costs are further reduced because different wall thicknesses the same starting material can be used.

With the reinforcing rod according to the present invention, it is possible that the reinforcing rod both provides a mechanical connection between the first wall shell and the second wall shell as well as the determination of the wall thickness of the cavity wall, thus fulfilling a spacer function. As already stated, the reinforcing rod must be able to absorb sufficient tensile forces and possibly also compressive forces. For this purpose, the tensile strength should preferably be at least 250 N / mm ² and the modulus of elasticity preferably at least 15,000 N / mm ² , in particular at least 25,000 N / mm ² . In addition, a shear stress between the reinforcing bar and the surrounding concrete (the so-called composite stress) should preferably be at least 1.5 to 2.3 N / mm ² .

Around one possible good thermal insulation of the To achieve hollow wall, the thermal conductivity of the reinforcing rods according to the invention should preferably less than 5, in particular less than 1 watt / (meter × Kelvin) be. Furthermore the reinforcing rods according to the invention are preferably corrosion resistant and are not subject to organic decomposition.

These Properties can Fulfills if, as material for Reinforcing bar fiber reinforced Material is used, in particular glass fiber reinforced plastic, depending on the requirements, also fiber reinforced concrete. Come as fiber material in addition to glass fibers but also carbon fibers, plastic fibers and steel fibers into consideration.

In The end portions of the reinforcing bar are preferably devices provided so that tensile and / or compressive forces from the reinforcing bars in the respective Wall shell can be initiated for making the mechanical connection between the wall shells. These facilities at the ends of the reinforcing bar can as Circumferential grooves, threads, bulges, ribs, claws or holes be educated.

According to the invention, at least one tip is provided at least at one end of the reinforcing bar, which is laterally offset with its end point with respect to the central axis of the reinforcing bar and / or at least one end of the reinforcing bar not rotationally symmetrical is formed.

Thereby is achieved by turning the reinforcing bars when Introducing into the fresh concrete of the first wall shell standing in the way Obstacles, such as pebbles, reinforcements and / or coarse-grained Additives, can be pushed aside. This way you can guaranteed be that the reinforcing bar at the bottom of the mold or the steel pallet rests to fulfill its spacer function. For this purpose, the rebar for example, at one or both ends of the reinforcing bar at least one oblique end face exhibit with an angle opposite the central axis of the reinforcing bar from 25 ° to 85 °, in particular 30 ° to 45 °.

Around also when the reinforcing bars penetrate into the fresh concrete of the second Wall shell despite obstacles in the way to enable can be provided that the second end formed asymmetrically is one being as well a rotatability of the second end by a hinge mechanism can be achieved in the central region of the reinforcing rod. The second end can be twisted so as to sideways obstacles push, although the first end already in the first wall shell is fixed. Preferably leaves the hinge mechanism no further freedom of movement as a rotation about the central axis of the reinforcing bar.

Of the Joint mechanism can be easily formed by a sleeve which are two halves of the reinforcing bar - if necessary connects with frictional engagement. If before touchdown the first wall shell on the second wall shell an adhesive in the respective sleeves is introduced, so is a momentary rotatability of the second Ends of reinforcing bars reached, but after curing the adhesive is no longer given. The adhesive ensures so also the transmission of forces between the two halves the respective reinforcing bars. It can however, alternatively other hinge mechanisms may be provided, the principle are permanently rotatable and allow transmission of tensile and compressive forces, such as B. Verrastungsmechanismen (Christmas tree structure), sleeves with circumferential grooves, male-female connections, plug-in mechanisms and like.

The The present invention also relates to a system consisting of a or multiple reinforcing bars and from an assembly aid, wherein the mounting aid formed in such a way is that they put one side on one end of a reinforcing bar can be, and wherein a second side of the mounting aid is a flat or has rounded surface. With such a mounting aid, it is possible that the worker the respective reinforcing bar in the fresh concrete and / or in the thermal barrier coating by hand - if necessary also with the help of a hammer - bring in can.

Preferably is the mounting aid in the attached state against the Reinforcing bar rotation, to push aside obstacles in the Fresh concrete (with asymmetric end of the reinforcing rod) Turn the mounting aid to allow. This can be achieved by placing the reinforcing bar at the end, on which the mounting aid is placed, with respect to the central axis has asymmetrical shape, and that the mounting aid This asymmetric shape is at least partially adapted.

Instead of a twisting possibility However, it can also be provided that the reinforcing rod in his middle region has a cross-section, which is a bending of the reinforcing bar in a first direction perpendicular to the central axis runs, possible is. This ensures that when introducing the reinforcing rod avoid obstacles laterally in the concrete of the second wall shell can be.

there is the said cross section in the central region preferably also designed such that a bending of the reinforcing bar in a second direction, both to the central axis and to the first Direction is vertical, across from A bending in the first direction is more difficult. Such a bending possibility can be created by the middle area on all sides or only rejuvenated from two sides becomes.

Even though the reinforcing rod is preferably introduced into fresh concrete, It is also possible according to the present invention, in tied or solidified concrete holes to drill and the respective rebar with adhesive in it set. The introduction of the reinforcing bar according to the invention in fresh concrete So is not a mandatory feature of the present invention.

It Now follows a description of a preferred embodiment the invention with reference to the accompanying drawings.

1 shows a cross section through a cavity wall according to an embodiment of the present invention,

2 shows a central region of a reinforcing rod according to an embodiment of the present invention, in which a twist between two halves of the reinforcing bar is possible,

3 shows a central region of a reinforcing bar according to another embodiment of the present invention, in which a Verbie tion possibility between the ends of the reinforcing bar is possible, and

4 shows an assembly aid according to an embodiment of the present invention, to introduce a reinforcing bar in fresh concrete.

1 shows a cross section through a cavity wall 1 according to an embodiment of the present invention. The cavity wall 1 has a first wall shell 2 , a second wall shell 3 and an intermediate thermal barrier coating 4 on. The wall shells 2 . 3 stand by several reinforcing bars 5 in mechanical working connection (in 1 only one rebar is visible). The thermal barrier coating 4 is also determined by the reinforcing bars so that they are preferably attached to the first wall shell 2 is applied.

According to the invention provide the reinforcing rods 5 each a mechanical connection between the first wall shell 2 and the second wall shell 3 forth, and at the same time serve to determine the wall thickness of the cavity wall. As a result, these two functions are achieved by the inventive reinforcing rods in contrast to the prior art, according to which different components were provided for these functions.

The reinforcing bars 5 create such a mechanical connection between the first wall shell 2 and the second wall shell 3 that the reinforcing rods 5 can absorb the tensile forces that occur when fresh concrete enters the free space 6 the cavity wall is poured in the standing state. The male tensile forces depend on the height of the cavity 6 the wall, since with increasing height, the internal pressure of the filled fresh concrete rises on the wall shells. However, the mechanical connection can also compressive forces that can act on the wall from the outside in the installed state, for example in the case of wind, water or earth loads record.

For the production of the hollow wall according to the invention is - as already stated - fresh concrete in a form or steel pallet for the production of the first wall shell 2 cast. It then becomes the thermal barrier coating 4 on the first wall shell 2 applied, and preferably in a state in which the fresh concrete of the first wall shell is not yet tied or solidified. Subsequently, the reinforcing rods according to the invention 5 through the thermal barrier coating 4 through into the fresh concrete of the first wall shell 2 introduced, with the reinforcing bars 5 be introduced so far in the illustrated embodiment, that in each case rest the ends of the reinforcing bars to the bottom of the mold or the steel pallet for producing the first wall shell. It should be noted that the first wall shell 2 in its manufacture initially has such a situation that its outer side facing downward (opposite to the position shown in FIG 1 ). The reinforcing bars 5 are thus pressed in this production phase from top to bottom in the concrete.

The resulting structure consisting of the first wall shell 2 , Thermal barrier coating 4 and reinforcing bars 5 which protrude from the thermal barrier coating is then set or cured. Subsequently, in turn, fresh concrete poured into a mold or steel pallet for the production of the second wall shell 3 , The first wall shell 2 is then over the second wall shell 3 arranged, wherein the protruding reinforcing rods in the direction of the fresh concrete of the second wall shell have (the first wall shell is thus turned over from the first production phase). The first wall shell 2 is lowered, so that the reinforcing bars also with their other ends in the fresh concrete of the second wall shell 3 plunge. Here are the reinforcing rods 5 also at the bottom of the mold or steel pallet. This will ensure that the length of the reinforcing bars 5 determines the overall thickness of the cavity wall so that the reinforcing bars 5 also fulfill a spacer function. Last is also the second wall shell 3 tied, so that it solidifies. It is therefore a prefabricated cavity wall 1 get their cavity 6 can be filled with fresh concrete at the construction site or at the destination.

A significant advantage of the method described above is that the thermal barrier coating 4 the inventive hollow wall 1 - With the exception of the passage holes for the reinforcing bars - continuously formed. In other words, the thermal barrier coating covers 4 the adjoining wall shell 2 completely without interruptions (except for the penetration holes for the reinforcing bars). This penetrates when filling fresh concrete in the cavity 6 no concrete in interruptions of the thermal barrier coating 4 , which can lead to undesirable heat conduction, as the thermal barrier coating 4 immediately and fully enclosing the outer contours of the reinforcing bars 5 is applied. In this way, a higher-quality cavity wall 1 obtained with a significantly better thermal insulation properties.

To introduce the reinforcing bars 5 to facilitate, is provided according to the illustrated embodiment, in the thermal barrier coating 4 Holes for the passage of reinforcing bars 5 work in before the thermal barrier coating 4 on the first wall shell 2 is applied. These holes can then also be used as a guide for the reinforcing bars 5 serve to make them as perpendicular as possible to the first wall shell 2 are arranged. For this purpose, the holes are preferably slightly smaller than the reinforcing bars 5 designed to ensure a positive or positive connection between the thermal barrier coating and the reinforcing bars. It also ensures that fresh concrete at the construction site in the cavity 6 is poured, not in any gaps between reinforcing bars 5 and thermal barrier coating 4 can penetrate.

The rebar 5 exists in the in 1 illustrated embodiment of glass fiber reinforced plastic having a tensile strength of about 250 N / mm ² and a modulus of elasticity of about 25,000 N / mm ² . The shear stress between the rebar 5 and the surrounding concrete (the so-called composite stress) is more than 2.3 N / mm ² . The material of the reinforcing bar 5 has a thermal conductivity below 1 watt / (meter × Kelvin), is resistant to corrosion and is not subject to organic decomposition.

In the end regions of the reinforcing bars, devices are preferably provided which enable the introduction of tensile and / or pressure forces from the reinforcing bars into the respective wall shell. For this purpose, circumferential grooves, threads, bulges, ribs, claws or holes can be formed in the end region of the reinforcing rods. In the embodiment according to 1 is the rebar 5 provided with thread-like extending grooves to allow initiation of tensile and / or compressive forces in the respective wall shell.

The rebar 5 has a tip at both ends 7 on that with its end point in relation to the central axis 8th of the reinforcing bar 5 is arranged offset laterally. According to other embodiments, it is sufficient that the ends of the reinforcing bar are not rotationally symmetrical. This will achieve that by turning the reinforcing bars 5 when introduced into the fresh concrete of the first wall shell 2 obstacles in the way, such as pebbles, reinforcing mesh and / or coarse-grained aggregates, can be pushed aside. In this way it can be guaranteed that the reinforcement bar 5 rests against the bottom of the mold or steel pallet to fulfill its spacer function. For this purpose, the reinforcing bar at one or both ends of the reinforcing bar have at least one inclined end surface whose angle α relative to the central axis 8th of the reinforcing bar in the illustrated embodiment is about 30 ° to 40 °.

In order to allow penetration of the reinforcing bars in the fresh concrete of the second wall shell despite standing in the way obstacles, is in the embodiment according to 2 , which is an alternative to the detail A in 1 shows, provided that a rotatability of the second end by a Ge steering mechanism 9 can be achieved in the central region of the reinforcing rod. The second end may be rotated to push obstacles aside, although the first end is already fixed in the first wall shell.

The joint mechanism can - as in 2 is shown - in a simple manner by a sleeve 10 be formed, which connects two halves of the reinforcing rod - optionally with frictional engagement. If before putting the first wall shell 2 on the second wall shell 3 an adhesive is introduced into the respective sleeves, so a momentary rotatability of the second ends of the reinforcing bars is achieved, which is no longer given after curing of the adhesive. The adhesive thus also ensures the transfer of forces between the two halves of the respective reinforcing bars. However, it may alternatively be provided other hinge mechanisms that are basically permanently rotatable and allow transmission of tensile and compressive forces, such. B. Verrastungsmechanismen (Christmas tree structure), sleeves with circumferential grooves, male-female connections, plug-in mechanisms and the like.

4 shows a mounting aid 11 according to an embodiment of the present invention, to a reinforcing bar 5 in fresh concrete. The mounting aid 5 is formed so that it can be placed with one side on one end of a reinforcing bar, and wherein a second side of the mounting aid 11 a flat or roundish surface 12 having. With such an assembly aid, it is possible that the worker can bring the respective reinforcing rod in the fresh concrete and / or in the thermal barrier coating by hand - possibly with the help of a hammer -.

Preferably, the mounting aid 11 in the attached state opposite the reinforcing bar 5 non-rotating to prevent obstacles from moving in fresh concrete (with asymmetric end of the reinforcing bar) by turning the assembly aid 11 to enable. This can be achieved by the reinforcing rod at the end to which the mounting aid is placed, with respect to the Has center axis asymmetrical shape, and that the assembly aid of this asymmetric shape is at least partially adapted, as that of the surfaces 13 in 4 the case is.

3 shows a middle area of a reinforcing bar 5 according to a further embodiment of the present invention, in which a possibility of bending between the ends of the reinforcing bar is possible. Instead of a twisting possibility is provided that the reinforcing rod 5 has in its central region a cross-section which is a bending of the reinforcing bar 5 in a first direction perpendicular to the central axis 8th runs, is possible. This ensures that when introducing the reinforcing bar in the concrete of the second wall shell 3 Obstacles can be bypassed laterally. Such Veriegungsmöglichkeit can be created by the middle region is tapered on all sides or only from two sides.

Claims (33)

Cavity wall ( 1 ) with a first wall shell ( 2 ) and a second wall shell ( 3 ) spaced from the first wall shell (FIG. 2 ), wherein the first wall shell ( 2 ) and the second wall shell ( 3 ) by reinforcing bars ( 5 ), characterized in that the reinforcing bars ( 5 ) each have both a mechanical connection between the first wall shell ( 2 ) and the second wall shell ( 3 ) as well as for determining the wall thickness of the cavity wall ( 1 ) serve. Cavity wall according to claim 1, characterized in that the reinforcing rods ( 5 ) for determining the wall thickness of the cavity wall ( 1 ) each extend with their ends from the outside of the first wall shell to the outside of the second wall shell. Cavity wall according to claim 1 or 2, characterized in that the reinforcing rods ( 5 ) such a mechanical connection between the first wall shell ( 2 ) and the second wall shell ( 3 ) that the reinforcing bars ( 5 ) can absorb the tensile forces that arise when fresh concrete enters the free space of the cavity wall ( 5 ) is poured in the standing state, and or compressive forces that can act on the wall when installed. Cavity wall according to one of the preceding claims, characterized in that the material of the reinforcing bars ( 5 ) each having a tensile strength preferably at least 250 N / mm ² . Cavity wall according to one of the preceding claims, characterized in that at least in the end regions of the reinforcing rods ( 5 ) Facilities are provided so that tensile forces from the reinforcing bars ( 5 ) can be introduced into the respective wall shell for the production of the mechanical connection between the wall shells. Cavity wall according to claim 5, characterized in that the devices in the end of the rebars as circumferential grooves, threads, bulges, ribs, claws or holes formed are. A cavity wall, in particular according to one of the preceding claims, which is located between the first wall shell (FIG. 2 ) and the second wall shell ( 3 ) a thermal barrier coating ( 4 ), which rests against at least one of the wall shells, characterized in that the thermal barrier coating ( 4 ) except the through holes for the reinforcing bars ( 5 ) is formed continuously. Cavity wall according to claim 7, characterized in that the thermal barrier coating ( 4 ) covers the adjacent wall shell almost completely, without interruptions except the through holes for the reinforcing bars ( 5 ). Cavity wall according to one of the preceding claims, characterized in that the reinforcing rods ( 5 ) a device for fixing the thermal barrier coating ( 4 ) have on the adjacent wall shell. Reinforcing bar ( 5 ) for connecting a first wall shell ( 2 ) and a second wall shell ( 3 ) of a cavity wall ( 1 ), characterized in that the reinforcing rod ( 5 ), both a mechanical connection between the first wall shell ( 2 ) and the second wall shell ( 3 ) as well as to determine the wall thickness of the cavity wall to serve. Reinforcing bar according to claim 10, characterized in that at least at one end of the reinforcing bar ( 5 ) at least one tip ( 7 ) with its end point in relation to the central axis ( 8th ) of the reinforcing bar is arranged offset laterally and / or at least one end of the reinforcing bar is not formed rotationally symmetrical. Reinforcing bar according to claim 10 or 11, characterized characterized in that at least one end of the reinforcing bar at least a weird one end face having. Reinforcing bar according to one of the claims 12, characterized characterized in that the end face across from the central axis of the reinforcing bar has an angle 30 ° to 85 °. Reinforcing bar according to one of claims 10 to 13, characterized in that at least in the end regions the reinforcing bar facilities are provided so that train and / or compressive forces from the rebars can be introduced into the respective wall shell for the production of mechanical Connection between the wall shells. Reinforcing bar according to claim 14, characterized in that that the devices at the ends of the reinforcing bar are in the form of circumferential grooves, Thread, bulges, ribs, claws or holes formed are. Reinforcing bar according to any one of claims 19 to 15, characterized in that in the central region of the reinforcing bar a hinge mechanism ( 9 ) which permits rotation of the first end relative to the second end about the central axis of the reinforcing bar. Reinforcing bar according to claim 16, characterized in that the hinge mechanism ( 9 ) allows no further degree of freedom of movement than a rotation about the center axis of the reinforcing bar. Reinforcing bar according to claim 16 or 17, characterized in that the articulated mechanism ( 9 ) through a sleeve ( 10 ) is formed, which connects two halves of the reinforcing rod together. Reinforcing bar according to one of claims 10 to 15, characterized in that the reinforcing bar has in its central region a cross-section which causes a bending of the reinforcing bar in a first direction perpendicular to the central axis ( 8th ) is possible. Reinforcing bar according to claim 19, characterized in that said cross-section in the central region is designed such that a bending of the reinforcing bar in a second direction, which is both to the central axis ( 8th ) as well as the first direction is perpendicular, with respect to a bend in the first direction is more difficult. Reinforcing bar according to one of claims 10 to 20, wherein the reinforcing rod is made of fiber reinforced material. System consisting of one or more reinforcing bars ( 5 ) according to one of claims 10 to 21 and from an assembly aid ( 11 ), whereby the assembly aid ( 11 ) is formed so that it is provided with one side on one end of a reinforcing rod ( 5 ) and wherein a second side of the mounting aid has a flat or rounded surface ( 12 ) having. System according to claim 22, characterized in that the assembly aid ( 11 ) in the mounted state against the reinforcing rod against rotation. System according to claim 23, characterized in that the torsional strength relative to the rebar ( 5 ) is achieved by the reinforcing bar at the end to which the assembly aid ( 11 ), has an asymmetrical shape with respect to the central axis, and that the assembly aid is at least partially adapted to this asymmetrical shape. Method for producing a cavity wall ( 1 ) comprising the following steps: a) pouring fresh concrete into a mold for producing a first wall shell ( 2 ), b) applying a thermal barrier coating ( 4 ) on the first wall shell ( 2 ) in a state in which the fresh concrete of the first wall shell is not yet set or solidified, c) introduction of reinforcing bars ( 5 ) through the thermal barrier coating ( 4 ) into the fresh concrete of the first wall shell ( 2 ), d) setting and / or solidifying the first wall shell ( 2 ), e) pouring fresh concrete into a mold for producing a second wall shell ( 3 f) applying the hardened or solidified first wall shell ( 2 ) with thermal barrier coating and reinforcing bars as a whole over the second wall shell ( 3 ) in a state in which the fresh concrete of the second wall shell is not yet set or solidified, wherein between the hardened and solidified first wall shell and the not yet hardened or solidified second wall shell remains a gap, and g) bonding and / or Solidification of the second wall shell ( 3 ). Method according to claim 25, characterized in that the introduction of reinforcing bars in step c) takes place such that in each case the ends of the reinforcing bars on the Base of the mold for making the first wall shell rest. A method according to claim 25 or 26, characterized in that in the heat-insulating layer holes for the passage of reinforcing bars are incorporated before the thermal insulation layer is applied to the first wall shell. Method according to one the claims 25 to 27, characterized in that in step f) the set or solidified wall shell applied in such a way over the second wall shell that will be the reinforcing bars penetrate into the fresh concrete of the second wall shell and on the Base of the mold for making the first wall shell rest. Method according to one the claims 25 to 28, characterized in that the reinforcing rods by her length the strenght set the cavity wall. Method according to one the claims 25 to 29, characterized in that the reinforcing bars provided be by adding a rod material that is a multiple of the strength of the Cavity wall corresponds to individual reinforcing bars corresponding to an overall length the strength have to be produced hollow wall, is cut. Method according to one the claims 25 to 30, characterized in that at least the ends of the Reinforcing bars, which are introduced into the first wall shell, each having a tip, the one with its end point in relation to the central axis of the reinforcing bar is laterally offset, so that by turning the reinforcing bars at Introducing into the fresh concrete of the first wall shell standing in the way Obstacles can be pushed aside. Method according to one the claims 25 to 31, characterized in that prior to the pouring of Fresh concrete for the production of the first and second wall shell a Reinforcement is introduced into the mold. Method according to one the claims 25 to 31, characterized in that the fresh concrete for the production the first and / or second wall shell fibers as a reinforcing agent contains.