EP2066481A1 - Process and reinforcing means for producing reinforced porous or foamed concrete bodies and reinforcement holder frames for use for such a process - Google Patents

Abstract

The metal reinforcement (1,2), for porous or foam concrete, has at least one solid holding rod (5) with a nominal break point (6). The rods are aligned and positioned to be suspended vertically from a reinforcement holding frame and treated with a rust protection material. The frame with the reinforcements is positioned at a concrete mold where the fresh concrete hardens into solid blocks. The individual rods are separated at the fracture points and at least upper rod projections (46) are removed. The solid concrete is cut into the required shapes.

Description

 Process and reinforcing means for the production of reinforced pore or foam concrete bodies and reinforcing frames for use in such a process

The invention relates to a method for the production of pore or foam concrete moldings, in particular of components or plates having a reinforcement of preferably metal, in particular of steel, and a reinforcement frame for use for such a method according to the preamble of the claim 43. Furthermore, the invention relates to a reinforcing agent for pore or foamed concrete molded articles according to the preamble of claim 52.

To be able to absorb not only high compressive forces but also tensile forces, components made of foam or aerated concrete must be known to be reinforced. Usual reinforcement means are rods, welded mats and / or, for example, mats made of steel welded steel baskets. For the preparation of such reinforced Schaumbzw. Autoclaved aerated components is usually first cast a pourable fresh concrete mass of known composition for porous or foam concrete in an eg rectangular mold 100 and inserted into the fresh concrete mass previously welded reinforcing baskets 101 (Fig.10). Importantly, the reinforcing baskets 101 are positioned and fixed so as to be sufficiently spaced from both sidewalls 102 and bottom 103 of the mold 100 and the surface of the concrete mass in the finished component to be completely enclosed by the concrete mass. The reinforcing baskets 101 must be kept in this defined position in the mold 100 until the aerated concrete mass sufficiently raised and possibly distended, so their Green strength has achieved and carries the reinforcement baskets 101 itself.

For holding the reinforcing cages 101 during this stiffening and optionally fermenting process, it is known to provide a rectangular reinforcing frame 104 which is centered on the side walls 102 of the mold 100 placed. A plurality of reinforcement support bars or reinforcement support bars 106, which are displaceable in the longitudinal direction of the reinforcement frame 104, are provided on the reinforcement support frame 104, which span the reinforcement support frame 104 and the mold 100 in the horizontal transverse direction. These reinforcement beams 106 in turn have numerous, vertically extending holes or holes 107 (shown only schematically), wherein in some of the holes 107 each have a substantially stabförmi- ge reinforcing retaining needle 108 is mounted. At the reinforcement needles 108 in turn, the individual reinforcing baskets 101 are fixed in such a way that the reinforcing needles 108 are easily detachable from the reinforcing baskets 101 after the concrete mass has stiffened and can be pulled out of the raised concrete mass. For example, one or more fastening means in the form of an oval hole or an oval eyelet are provided on the reinforcing baskets 101, with which the reinforcing baskets are threaded onto one respective reinforcing holding needle 108. The reinforcing needles 108 have, for example, radially projecting pins or pins (not shown), so that the reinforcing needles 108 are connected to the reinforcing cage 101 after threading through the eyelets by rotating about its longitudinal axis, for example in the manner of a bayonet closure or the like. As a result, the reinforcing baskets 101 are suspended from the reinforcing needles 108 and hang with them into the casting mold 100. In particular, in the case of reinforcing baskets 101 consisting of mutually parallel reinforcing mats 109, it is also known to have spacers or cross connectors between the two reinforcing mats 109 110, for example made of plastic, to provide centrally such oval eyelet and are attached to the two mats 109.

Furthermore, it is known from EP 0 060 232 B1 for holding longitudinal bars connected to individual transverse bars to provide horizontally extending spring arms, which are fastened at one end to a transverse bar and are pressed against a vertical retaining holding needle at the other end with a specific spring force. The reinforcing holding needle also has two horizontally protruding and vertically aligned pins arranged on top of each other. If the reinforcing needle is arranged so that the spring arm is pressed against the reinforcement holding needle between the two pins, the reinforcing needle holds the reinforcement and can not be pulled out vertically. If the reinforcing needle is rotated by approximately 90 °, the pins no longer surround the spring arm above and below and the reinforcement retaining needle can be pulled out.

A disadvantage of the known method, on the one hand, that the reinforcement needles 108 must first be manually hung in the holes 107 in the reinforcement beam 106 and then the reinforcing baskets 101 must also be manually attached to the reinforcement holding needles 108.

In addition, the position of the reinforcing needles 108 and thus the position of the reinforcing baskets 101 suspended from the reinforcing needles 108 in the transverse direction is adjustable only in the grid predetermined by the position of the bores 107 in the reinforcing support bars 106.

Furthermore, the reinforcing baskets 101 suspended from the reinforcing holding needles 108 are usually immersed in a bath with antirust agent prior to insertion into the mold 100 in order to avoid corrosion in the later component. At the same time, the reinforcing needles 108 inevitably also dip at least partially into the bath. To the reinforcement needles 108 but In order to be able to reuse, it is necessary to prevent the rust preventive layer from growing again when the needles 108 are reused, since the size of the eyelets is adapted to the diameter of the reinforcing holding needles 108, so that the holding needles 108 are guided in the eyelets with as little play as possible. Therefore, the reinforcing holding needles 108 are usually dipped in paraffin prior to attaching the reinforcing cages 101 to the reinforcing holding needles 108 in an additional preceding process step. This prevents the rust-preventive agent from permanently adhering to the needles 108. However, the paraffin and the rust inhibitor adhered thereto must be removed again from the reinforcement holding needles 108 in a further method step after each production process. Alternatively, for dipping the reinforcing cages 101, other needles or hooks are used, which must be replaced after dive with the correct reinforcing needles 108. In any case, therefore, at least one additional method step for protecting the reinforcement holding needles 108 is necessary, which entails a time and cost disadvantage.

The object of the present invention is to provide a process for the production of reinforcing materials of preferably steel, reinforced pore or foam concrete molded bodies, which is simple and inexpensive and automatable, and with which an accurate, stable positioning of the reinforcing means with better variability, in particular Transverse direction of the mold by simple means is possible.

In addition, it is an object of the invention to provide a reinforcing agent made of, in particular, steel for pore or foam concrete shaped bodies, which can be produced easily and inexpensively and which is easier to handle and stable and more precisely positionable in the production of the pore or foam concrete molded body. Finally, it is the object of the invention to provide a reinforcement holding frame for holding the reinforcing means in the mold filled with fresh concrete mass, to which the reinforcing means can be fastened easily, quickly and securely.

These objects are achieved by the features of claims 1, 46 and 55. Advantageous developments of the invention are each characterized in the associated subclaims.

In the following the invention will be explained by way of example with reference to a drawing. Show it:

Fig.l: a side view of a reinforcement mat with support rods

2 shows a side view of a holding rod with predetermined breaking point FIG. 3 shows a cross section of the holding rod according to FIG. 2 along the line A-A

4 shows a perspective view of a reinforcing basket made of two reinforcing mats

5 shows a schematic, perspective view from the top front of an alignment and positioning device

6 shows a schematic perspective view from the top front of a part of a reinforcement frame according to the invention

7 shows a schematic, perspective cross-sectional view of a reinforcing bar of the reinforcement frame according to FIG. 6 along the line B-B

8 shows a schematic cross-sectional view of a casting mold with a reinforcing body frame according to the invention and reinforcing baskets hanging in the casting mold 9 shows a perspective cross-sectional view of a demolded concrete cake produced according to the invention with a schematically illustrated screwdriver

10 shows a schematic cross-sectional view of a casting mold with an attached reinforcement frame and hinged reinforcing baskets according to the prior art

For the manufacturing method according to the invention, initially reinforcing mats 1 (FIG. 1) of longitudinal bars 2 and transverse bars 3, which intersect in pairs, can be produced on known mat welding machines (not shown) in a manner known per se. As cross bars 3 while the bars of the reinforcing mats 1 are referred to, which, when the reinforcing mats 1 in a mold 4 (Figure 8) hanging in, are vertically aligned, and thus for a connection and fixed position to each other, the horizontally aligned and vertically aligned one above the other arranged longitudinal bars 2 provide the reinforcement mats 1, which ensure an increase in the tensile strength and bending strength of the finished component.

Preferably, when welding the reinforcing mats 1 for the purposes of the invention holding rods 5 (Fig.1, 4, 5, 8, 9), preferably in the form of elongated transverse bars 3, to the reinforcing mats 1, in particular to the longitudinal bars 2 of the reinforcing mats. 1 , welded, so that the support rods 5 are firmly connected to the reinforcing mats 1. The holding rods 5 thus consist of one common transverse bar 3 of normal length and one holding area additionally provided on the transverse bar. The support rods 5 are so long that they protrude in the vertical direction upwards by a certain amount, in particular by 50 to 400 mm, preferably by 180 to 200 mm over the reinforcing mat 1 arranged later in the mold 4 (FIG ). As an alternative to welding, the holding rods 5 are fastened to the reinforcing mats 1 by means of sleeves and / or clamps and / or mounting brackets.

However, the holding rods 5 can also be applied to externally sourced reinforcement in the pore or foam concrete plant.

In this case, the holding rods 5 preferably have a predetermined breaking point 6, with e.g. at least one, preferably two opposing, notches 7 (Fig.2,3), so that the cross section of the support rods 5 is tapered at the predetermined breaking point 6. The predetermined breaking point 6 is expediently arranged slightly above the uppermost longitudinal bar 2 of the reinforcing mat 1.

Alternatively, the holding rods 5 are merely constricted or compressed or otherwise weakened at the predetermined breaking point 6.

Conveniently, 2 to 8, in particular 5 to 6 support rods 5 are provided per reinforcing mat 1, wherein a reinforcing mat 1 zweckmäßigerweiεe a length of 1 to 8 m, preferably 2 to 6.5 m.

The support rods 5 also preferably have a diameter of 4 to 10 mm, preferably 5 to 8 mm and are preferably made of steel, in particular stretched reinforcing steel, and / or stainless steel, and / or plastic.

Furthermore, in the process according to the invention, reinforcement baskets 8 (FIGS. 4, 5, 8, 9) can be produced from preferably two reinforcing mats 1 each. For this purpose, the reinforcing mats 1 with their longitudinal and transverse bars 2, -3 are respectively positioned parallel to one another and, for example, simple spacing bars 9, which are aligned perpendicular to the longitudinal and transverse bars 2, 3 of the reinforcing mats 1, between two heads to be joined. mation mats 1 positioned and welded with its two Abstandsstab- end faces 10 to the reinforcing mats 1. Alternatively, spacers made of metal or plastic can also be clamped. The support rods 5 of the individual reinforcement mats 1 are thereby positioned so that they each survive on the same side and expediently substantially equally far beyond the finished reinforcing cage 8.

According to the invention, the finished reinforcing baskets 8 provided with support rods 5 are brought into an alignment or positioning device 11 (FIG. 5) in which they are held for receiving through a reinforcement support frame or reinforcement frame 12 (FIGS ) are positioned and aligned, which will be discussed later.

The e.g. Carriage-like alignment or positioning device 11 has a horizontal, preferably substantially cuboid bottom plate 14, at the lower side preferably four wheels 47, e.g. Rail wheels, are attached. As a result, the alignment or positioning device 11 is preferably a movable alignment carriage or a movable alignment shuttle 13. Furthermore, the alignment or positioning device 11 preferably comprises two, aligned parallel to each other and parallel to a horizontal longitudinal direction 23 Outside support walls 15 and at least one, preferably two to thirteen, preferably three to six inner, ie between the outside support walls 15 and parallel to them arranged support walls 17. The support walls 15; 17 serve to position the reinforcement cages 8 in a horizontal transverse direction 20 and are preferably displaceable in the horizontal transverse direction 20, in particular controllable and automatically programmable displaceable.

For the positioning of the reinforcement cages 8 in the horizontal transverse direction 20 is, for example, a from an upper side 18 of the Base plate 14 vertically to the top extending stop Anschlagbzw. Abutment edge or wall or the like (not shown), which extends in the transverse direction 20 and is arranged on one of the two transverse sides 19 of the bottom plate 14.

Furthermore, the alignment or positioning device 11 has at least one, preferably two, vertically aligned centering bars 21, -22 and preferably two positioning bars 48, 49, which are used for horizontal and vertical centering and positioning and fixing of the reinforcement support frame 12 with respect to the alignment carriage 13 serve, which will be discussed below. The centering bars 21, 22 are preferably arranged in the horizontal longitudinal direction 23 in alignment with one another and outside the one outer longitudinal wall 15 of the aligning or positioning device 11 and dimensioned such that they project beyond the supporting walls 15 in the vertical direction. The positioning bars 48, 49 are likewise preferably arranged in the horizontal longitudinal direction 23 in alignment with one another and outside the other outside support longitudinal wall 15 of the alignment or positioning device 11 and are dimensioned such that they project beyond the support walls 15 in the vertical direction. Preferably, the centering and positioning bars 21, 22; 48; 49 the same height. In addition, the centering bars 21, 22 on the front side and on the upper side each have a vertical centering hole 24, 25, of which preferably one centering hole 24 is in the form of a cylindrical hole and the other centering hole 25 is in the longitudinal direction 23 extending slot. In the embodiment with only one centering bar, the centering hole is preferably polygonal in cross-section, in particular rectangular (not shown).

For positioning and aligning the reinforcement cages 8 is now between each two support walls 15; 17 each inserted a reinforcing basket 8 with upwardly directed support rods 5 and placed on the horizontal and flat top 18 of the bottom plate 14. The reinforcement baskets 8 and the support walls 15; 16 are dimensioned so that at least the support rod 5, the support walls 15; 16 slightly higher in the vertical direction.

After insertion, the individual reinforcing baskets 8 by moving the support walls 15; 17 positioned in the transverse direction 20 and fixed in the desired position. The positioning of the reinforcement cages 8 in the longitudinal direction 23 takes place by pushing the loading cages 8 guided between the support walls 15, 17 in the longitudinal direction 23 against the stop edge. The reinforcing baskets 8 are either manually pushed manually or by means of a sliding device, e.g. a crane or manipulator or robotic arm, e.g. on the protruding support rods 5 attacks.

In the vertical direction, the reinforcing cages 8 are automatically positioned by placing them on the upper side 18 of the bottom plate 14.

Alternatively, the alignment or positioning device 11 is pivoted before inserting the reinforcement cages 8 by preferably 30 to 55 °, preferably 45 ° about an axis parallel to the longitudinal direction 23 axis. As a result, the reinforcing baskets 8 automatically slide along one of the support walls 15 due to gravity; 17 and are thus automatically positioned in the vertical direction and also in the transverse direction 20. Positioning in the longitudinal direction takes place in an analogous manner as described above either before or after the alignment or positioning device 11 is pivoted back into its starting position.

The reinforcement cages 8 are now according to their later desired position in the mold 4, which is determined by the desired position in the finished components, horizontal and vertically aligned, positioned, and can be grasped by the reinforcement support frame 12 in the next step.

The reinforcement holder arm 12 (FIGS. 6-8) is preferably of cuboid shape and has an outer frame (44) which has two longitudinally extending longitudinal beams 26; 27 and two perpendicular to the longitudinal beams 26; 27 and also horizontally extending transverse bar 28, only one of which is shown, has. The reinforcement holding ^¬ ranmen 12 also includes at least one, preferably 2 to 8, preferably 5 to 6 Bewehrungstrag- or Bewehrungshaitebalken 29, spanning the outer frame 44 in the horizontal transverse direction 20 like a bridge and linearly displaceable with the outer frame 44, preferably in a horizontal longitudinal direction 23 , are connected. For example, the reinforcing bar beams 29 by means of screws or clamps on the longitudinal beam 26; 27 attached.

According to the invention, at least one respective clamping element or clamping means is provided on the reinforcing bar bar 29 or on one or more of the outer frame elements (26, 27, 28) by means of which one or more holding bars 5 protrude at their upper, over the reinforcement cages 8 and the Ausrichtwagen 13 Haltestabende or Haltestabendbereich 30 {Fig.1, 2, 4, 5, 7-9) can be gripped, clamped and held.

The clamping means are, for example, two vertically aligned clamping beams or ledges 31 extending in the transverse direction 20 of the reinforcement support frame; 32 (Figure 6, 7), for example made of metal or plastic, which are arranged in the longitudinal direction 23 of the reinforcement frame 12 to each other in alignment and slightly spaced from each other and of which at least one with respect to the other in the longitudinal direction 23 of the reinforcement frame 12 is slidable. As a result, between the two clamping strips 31; 32 defines a width-adjustable, downwardly and preferably also upwardly open clamping gap 33. Are the two clamping afford 31, - 32 formed and arranged so that the clerar gap 33 is also open towards the top, length tolerances of the inserted into the nip 33 holding rods 5 are irrelevant.

The length of the terminal strips 31; 32 is preferably dimensioned such that they extend substantially over the entire length of the reinforcement support beam 29.

Preferably, each of the two clamping strips 31; 32 also has two transversely extending, superimposed beads 34 which protrude into the nip 33, wherein the beads 34 of the two clamping strips 31; 32 are arranged in pairs opposite one another and thereby taper the nip 33 in these areas (Fig.7). As a result, the support rods 5 are clamped only between each two opposite beads 34, whereby the clamping force is increased.

The method and fixing the clamping strips 31, -32 to each other is preferably carried out by means of spring force and / or pneumatically and / or hydraulically, wherein the clamping force is adjustable.

As an alternative to the clamping bars 31, 32, the clamping means are individual grippers which have two gripping claws engageable with one another for clamping the holding rod ends 30 and which can preferably be moved in the transverse direction 20 along the respective reinforcing bar bar 29, with several grippers per gripper Reinforcement beams 29 are provided (not shown).

Furthermore, the reinforcement frame 12 preferably has at least one, preferably two, vertically downwardly extending centering pins 35. The centering pins 35 are preferably arranged on the underside of the longitudinal beam 27, wherein preferably both are provided on a longitudinal beam 27. Furthermore, the or the two centering pins 35 are Corresponding to the centering holes 24,25 of the alignment ^e and positioning device 11 is arranged and designed. In particular, the centering pins 35 are cylindrical in the upper area depending on the design of the corresponding centering holes 24,25 or rectangular or polygon in cross-section.

For gripping the reinforcement cages 8 positioned and fixed in the alignment and positioning device 11, the reinforcement frame 12, e.g. lowered by means of a crane over the Ausrich- and positioning device 11 such that the longitudinal beams 26; 27 of the reinforcement frame 12 parallel and the crossbars 28 of the reinforcement frame 12 are perpendicular to the support walls 15, - 17 of the Ausrichtwagens 13 aligned. In the embodiment of the alignment and positioning device 11 as alignment trolley 13, the alignment trolley 13, with the reinforcement cages 8 positioned and fixed, is moved beforehand to the support support frame 12, e.g. on rails, which increases flexibility and considerably simplifies the procedure.

The precise horizontal centering and positioning of the reinforcement support frame 12 in relation to the alignment and positioning device 11 and thus to the reinforcement cages 8 takes place when the reinforcement support frame 12 is lowered by inserting the centering pins 35 into the centering holes 24, 25. In particular, the centering pins 35 and the corresponding centering holes 24; 25 of the reinforcement frame 12, in particular the reinforcing bars 29 with the clamping strips 31; 32, and the reinforcing baskets 8 are positioned relative to one another in such a way that the retaining rod ends 30 are inserted into the clamping gaps 33 when the reinforcement support frame 12 is lowered.

The vertical positioning of the reinforcement frame 12 is effected by the storage of the reinforcement frame 12 on the centering bar 21; 22 and the positioning bar 48; 49th After the reinforcement holder 12 has reached its predetermined position in the vertical direction, the clamping strips 31; 32 driven towards each other and the holding rod ends 30 clamped between them.

As a result, the support rods 5 and thus the individual reinforcing baskets 8 are fixedly connected to the reinforcing bar members 29 of the reinforcing support frame 12 and can not be displaced in relation to this in horizontal or vertical direction or rotated to this. The reinforcing baskets 8 are thus immovable and non-rotatable, but still releasable, with the rebar Heiteranmen 12 in clamped connection.

Subsequently, optionally the alignment trolley 13 can be moved together with the reinforcement frame 12 and the reinforcement cages 8 to a known antirusting dip (not shown) or optionally the reinforcement frame 12 again preferably by means of a crane together with the hanging reinforcement cages 8 of the alignment and positioning 11 are lifted and transported there. It is also possible to use circular chain conveyors. In the anti-rust diving system, the raised reinforcement cages 8 are immersed in a dip with rust inhibitor. Forcibly, the support rods 5 are also at least partially immersed. Alternatively, the reinforcement cages 8 are sprayed with rust inhibitor. In case of using stainless steel, the reinforcement cages 8 are not treated with rust inhibitor. Alternatively, the reinforcement cages may be provided with rust prevention prior to insertion and positioning in the alignment carriage 13.

According to the optionally used anti-corrosion system, the reinforcement frame 12 is transported with the reinforcement cages 8 preferably by means of a crane to the known, preferably cuboid and upwardly open mold 4 (Fig.8) and in a conventional manner such put on that the reinforcement cages 8 hang into the mold 4 inside. In particular, the longitudinal and transverse bars 26, -27; 28 of the reinforcement frame 12 on two vertical Gießformlängswandungen 37, -38 and two vertical Gießformquer- walls (not shown) placed. The positioning of the reinforcement support frame 12 and thus the reinforcement cages 8 in the casting mold 4 takes place in a conventional manner via the centering pins 35 provided on the reinforcement support frame 12, which inserts into corresponding centering recesses (not shown) in the casting mold longitudinal walls 37, 38 become. It is important that the suspended reinforcement cages 8 both from the horizontal mold bottom 36 and from the Gießformlängswandungen 37; 38 and the Gießformquerwandungen are sufficiently spaced. In addition, the reinforcing baskets 8 must be mounted sufficiently deep in the mold 4, that they are far enough below the surface in, possibly distended, concrete cake, so that the reinforcing baskets 8 are completely enclosed in concrete in the later concrete moldings.

In this case, the filling of the casting mold 4 with fresh concrete mass 39 can take place before or after the reinforcing baskets 8 are hooked into the casting mold 4. For the production of autoclaved aerated forirics, a conventional fresh concrete mass 39 is used which comprises at least one propellant pore former, in particular finely divided aluminum, e.g. in the form of aluminum powder or paste. For the production of Schaumbetonformkörpern a conventional fresh concrete composition is used, which already contains admixed air pores.

After filling the fresh concrete mass 39 and inserting the reinforcing cages 8, the fresh concrete mass 39 will stiffen for about 30 to 240 minutes or optionally fermented and allowed to stiffen until the fresh concrete mass 39 has reached a sufficient green strength and a fresh concrete cake 40 (Figure 9) has arisen , After reaching the green strength according to the invention, the support rods 5 and at least one upper HaItestabteil 46 of the support rods 5 are separated from the reinforcement cages 8 and removed. In the case of notched holding bars 5, that is to say with a predetermined breaking point 6, the upper holding-bar portion 46 of the holding bars 5, that is to say the portion 46 above the predetermined breaking point 6, is turned off in a particularly simple manner. For this purpose, for example, first the clamping of the upper holding rod ends 30 is loosened or completely released by moving the clamping bars 31, 32 apart. Optionally, the reinforcement frame 12 is lifted and removed, for example, by means of a crane of the mold 4. Thereafter, the holding rod ends 30 are gripped, eg also clamped, and the upper holding compartment part 46 is rotated about a vertical rod longitudinal axis 42 (FIGS. 2, 7) until it is separated from the rest of the holding rod 5 at the predetermined breaking point 6. The lower part of the support rods 5 is in each case sufficiently firmly connected to the reinforcement cages 8, in particular welded, that it is not rotated with the upper holding compartment part 46 about the rod longitudinal axis 42. The severed upper holding compartment 46 is then pulled out of the concrete cake 40 and removed.

The turning off of the upper half-test compartments 46 preferably takes place by means of an automatable twist-off device. This includes e.g. One or more screwdrivers 41 (Figure 9), in the drill chuck 43, the holding rod ends 30 are clamped and then the screwdriver 41 is activated to turn off.

As an alternative to twisting off the holding rods 5 are bent at the predetermined breaking points 6 and canceled and / or torn and / or pinched and / or sanded.

After a particularly advantageous separation method, the upper holding rack portions 46 are first bent by preferably 90 ° and then the bent holding rack sections 46 are rotated about the rod longitudinal axis 42 until the support rods 5 at the Cancel kink. The kinking and subsequent twisting is expediently carried out simultaneously for all holding rods 5, that is to say automatically. Preferably, the individual support rods 5 of a reinforcing cage 8 are alternately, so each two of the individual support rods 5 a reinforcing basket 8 mirrored to each other and abgeickt in opposite directions and turned off, so that the force acting on the reinforcing cage 8 forces cancel each other. As a result, the anchoring of the reinforcement cage 8 in the concrete cake 40 is not burdened.

Preferably, the predetermined breaking point 6 of the support rods 5 is below or above or equal to a top 45 of the concrete cake 40. In particular, the predetermined breaking point 6 of the support rods 5 as already explained above just above the upper longitudinal bars 2 of the reinforcement cages 8 or just below the surface of the later Component. As a result, the separated lower part of the retaining rod 5 remains as a cross bar 3 in the concrete cake 40 and thus in the later part and forms part of the reinforcement.

However, if desired, the breaking point 6 can also lie very far down, for example in the region of the lower longitudinal bar 2, so that the separated upper holding bar section 46 is still sufficiently long to be used again.

Retaining rods 5 without breaking point 6 are e.g. above the concrete cake 40 or at the height of a top 45 of the concrete cake 40 sawn off or ground or pinched or kinked and broken off or as initially described kinked by 90 ° and then turned off.

If the entire holding bar 5 is removed from the concrete cake 40, the connection, in particular the welded connection, of the holding bar 5 and the reinforcing cage 8 is designed such that it corresponds to the weight of the reinforcing baskets 8 hanging from the holding bars 5 and optionally withstand the pressure, but still, for example, by turning the entire holding rod 5 about the rod longitudinal axis 42 as described above or by tearing out of the support rods 5 or by vibration, is releasable, so that the entire holding rod 5 pulled out of the concrete cake 40 and removed becomes.

In a next production step, if necessary, the new, externally accessible end of the part of the holding rod 5 remaining in the concrete mold cake 40, which has been produced by twisting off or breaking off, is again provided with rust inhibiting means, in particular sprayed.

Thereafter, the concrete cake 40 is expediently demolded in a conventional manner, for example, by the individual side walls 37, -38 of the mold 4 are folded away. Depending on the production process, a side wall 37 is not folded away, this represents the so-called hardness floor 38, on which the cut concrete cake 40 is dropped for hardening. The demoulding can also be done before the removal of the support rods 5 and Haltestabteile 46.

Next, the concrete cake 40 is conveniently placed in a manner known per se, e.g. split with cutting wires into individual green concrete moldings (not shown). Preferably, the concrete cake 40 is thereby cut in the vertical direction between the reinforcement cages 8, wherein expediently cut in such a way that each green concrete moldings having a reinforcing cage 8. When cutting, it is preferable to use e.g. from hardness base 38 as "0" - or reference point assumed.

After cutting, the individual green concrete shaped bodies are preferably fed to an autoclave and hydrothermally hardened in a manner known per se (not shown). In the method according to the invention it is advantageous that the separate dipping of the previously used reinforcing needles in paraffin as an additional production step is eliminated because the support rods 5 according to the invention are clamped from above and not through a hole in the reinforcement bar and the loops must be carried out as accurately as possible.

Another important advantage of the inventive clamping of the support rods 5 from above is that the position of the reinforcement cages 8 in relation to the reinforcement bar bar 12 in the transverse direction 20 is infinitely adjustable. As a result, the later position of the reinforcing cages 8 in the mold 4 is infinitely variable, completely variable and very accurate adjustable and optimally adapted to the particular circumstances and without much effort. In addition, holding rods 5 of any diameter can be clamped without the reinforcement holding bar 12 having to be fitted or exchanged.

Furthermore, it is ensured by the fixed, integrated connection of support rods 5 and reinforcement cages 8 that the reinforcement cages 8 can be positioned and fixed extraordinarily accurately in the casting mold 4 and also remain fixed in position during pouring and optionally fermenting or blowing up the fresh concrete mass 39. The reinforcement baskets 8 withstand very high fermentation pressures. As a result, the tolerances of the reinforcement position in the manufactured components are very low.

By using the automatically controlled and programmable Ausrichtwagens 13 and subsequent automatic gripping and clamping of the positioned support rods 5 by means provided on the reinforcement support bar 12 clamping means from above and optionally automatic, at least partially separating each support rods 5, the entire manufacturing process is fully automated. There is no manual hooking of reinforcement needles in the reinforcing bars 29 and no manual hanging or threading the Reinforcing baskets 8 with the eyelets provided in the reinforcement needles more necessary. This brings with it a considerable time and cost savings. On the other hand, the reinforcement baskets 8 are no longer touched after the coating with rust-preventive, so that the layer of rust inhibitor remains intact. In addition, the automatic alignment of the reinforcement cages 8 by means of the Ausrichtwagens 13 is very accurate.

Of particular advantage is the very short tolerance chain in the method according to the invention, since the support rods 5 when hanging in the mold 4 and until reaching the green strength of the concrete mass 39 both with the reinforcement cages 8 and the reinforcement frame 12 fixed, so immovable and unverdrehbar in Connection and the clamping means introduce no tolerance.

Of course, the method according to the invention is applicable not only to reinforcing baskets 8, but in principle to all reinforcing agents. In the context of this application, reinforcing means are all reinforcing means known to the person skilled in the art, in particular reinforcing bars, reinforcing mats, reinforcing baskets and / or holding lugs and / or assembly anchors, wherein the reinforcing bars, reinforcing mats and reinforcing cages can have any, ie also curved, room forms. When using reinforcing rods, the support rods are attached directly to them.

In addition, of course, the produced concrete moldings may have any cuboid, but also, for example, a cylindrical, semicircular or prismatic Rauitiform that can be produced with an upwardly open mold. Corresponding to the respective resulting spatial shape of the casting mold, in each case only the shape of the reinforcement holding frame is adapted so that it can be placed exactly centered on the casting mold. Reinforcing mats and reinforcing meshes consisting of several reinforcing mats is also particularly advantageous that a part of the normally provided crossbars can be easily replaced by the, eg notched, support rods, since the lower parts remain in the concrete cake and thus form a functional part of the reinforcing means. The support rods are in terms of production technology in this case only elongated cross bars and are particularly easy to incorporate into the production process, without new devices for connecting the support rods are necessary with the reinforcing means. However, the welding of the support rods is also very cost-effective, because no additional and complex fastening means, such as spacers with eyelets are more necessary. In addition, the support rods are simple rods, preferably of the same or the same reinforcement material or reinforcement starting material, which have no additional fastening means, such as stepped heels for mounting in holes in the reinforcement frame, or parts of a bayonet closure.

In summary, the method according to the invention is very cost-effective, among other things because it is fully automated, and ensures extremely accurate positioning of the reinforcement in the pore or Schaumbetonformkörper.

Claims

claims

1. A process for the production of reinforcing materials (1, 2, 8) from preferably metal, in particular steel, reinforced pore or foam concrete shaped bodies with the following process steps:

a) use of at least one, preferably more, reinforcing agent (s) (1; 2; 8) with at least one e.g. firmly integrated holding rod (5), preferably a plurality of holding rods (5), wherein the holding rods (5) are preferably provided with a predetermined breaking point (6), b) aligning and positioning of the reinforcing means

(1; 2; 8) for receiving through a reinforcing bar frame {12), c) clamping the holding bars (5) to the reinforcing bar frame (12) so that the reinforcing means (1; 2; 8) move away from the reinforcing bar frame (12; 12), and the support rods (5) are vertically aligned; d) expediently applying rust protection agent to the reinforcement means (1; 2; 8); e) positioning the reinforcement (1; 1) suspended from the reinforcement frame (12); F) Stiffening of the fresh concrete mass (39) to the concrete cake (40), g) separation of the individual support rods (5) or (2) 8) in a filled with fresh concrete mass (39) or to be filled, upwardly open mold (4) at least one upper holding compartment part (46) of each Holding bars (5), preferably at the respectively predetermined breaking point (6), of the reinforcing means (1; 2; 8), h) optionally cutting the concrete cake (40) into green pore or foam concrete shaped bodies, i) curing the green pores. or foamed concrete molded body or concrete cake (40).

2. The method according to claim 1, characterized in that the upper holding compartment part (46) above or below or at the level of an upper side (45) of the concrete cake (40) is separated.

3. The method according to claim 1 and / or 2, characterized in that provided with a predetermined breaking point (6) holding rods (5) above the predetermined breaking point (6) lying holding part (46) is turned off by a vertical rod longitudinal axis (42) or bent and / or broken off or torn off or pinched off or sanded off.

4. The method according to claim 3, characterized in that for turning off an automatable twisting device is used, which preferably has one or more screwdrivers (41).

5. The method according to claim 4, characterized in that for turning an upper holding rod end (30) of a holding rod (5) in a chuck (43) of a screwdriver (41) is clamped and then the screwdriver (41) is activated for turning.

6. The method according to claim 1 and / or 2, characterized in that

Retaining rods (5) without predetermined breaking point (6) above the concrete cake (40) sawed off or sanded or pinched off.

7. The method according to one or more of the preceding claims, characterized in that the upper holding rack parts (46) are first bent by preferably 90 ° at a kink, preferably the predetermined breaking point Ie (6), and then the bent holding rack sections (46) around the rod longitudinal axis (42) to be rotated until the support rods (5) break off at the kink.

8. The method according to claim 7, characterized in that the kinking and subsequent twisting for all support rods (5) of a reinforcing means (1; 2; 8) is performed simultaneously, preferably each two of the individual support rods (5) of a reinforcing means (1; 2, 8) mirrored to each other and bent in opposite directions and turned off.

9. The method according to one or more of the preceding claims, characterized in that the separated upper Haltestabteil (46) or the entire separated holding rod (5) is pulled out of the concrete cake (40) and removed.

10. The method according to one or more of the preceding claims, characterized in that the holding rods (5) before use of the reinforcing means (1; 2; 8) to the reinforcing means (1; 2; 8) are welded.

11. The method according to claim 10, characterized in that the welded connection of the support rods {5) with the reinforcement means (1; 2; 8) when removing the support rods (5) by rotating the support rods (5) about the rod longitudinal axis (42) or through Tearing out or being released by vibration.

12. The method according to one or more of the preceding claims, characterized in that

Retaining rods (5) are used with a tapered at the predetermined breaking point (6) cross-section.

13. The method according to claim 12, characterized in that

Holding rods (5) are used, which have at the predetermined breaking point (6) at least one, preferably two opposing notches (7).

14. The method according to one or more of the preceding claims, characterized in that

Holding rods (5) are used, which have a diameter of 4 to 10 mm, preferably 5 to 8 mm.

15. The method according to one or more of the preceding claims, characterized in that

Support rods (5) are used, which are made of metal, preferably made of steel, in particular stretched reinforcing steel, and / or stainless steel, and / or plastic and preferably an extended component of the reinforcement means (1, 2, 8), in particular a transverse rod (3 ), are.

16. The method according to one or more of the preceding claims, characterized in that as reinforcing means (1; 2; 8) reinforcing bars (2) and / or reinforcing mats (1) and / or reinforcement cages {8) are used.

17. The method according to claim 16, characterized in that the reinforcing mats (1) before use of longitudinal bars (2) and transverse bars (3) are welded.

18. The method according to claim 17, characterized in that the reinforcing baskets (8) are made prior to use of preferably two reinforcing mats (1), wherein the reinforcing mats (1) with their longitudinal and transverse bars (2, 3) each parallel to each other be positioned and the support rods (5) of the individual reinforcing mats (1) are positioned so that they each survive on the same sixth and expediently substantially equally far beyond the finished reinforcing cage (8), and expediently simple spacer bars (9), the vertical are aligned to the longitudinal and transverse bars (2, 3) of the reinforcing mats (1), positioned between two reinforcing mats (1) to be joined and welded to the reinforcing mats (1).

19. The method according to claim 17 and / or 18, characterized in that the holding rods (5) before the use of the reinforcing means (1; 2; 8) in the form of elongated transverse rods (3), on the reinforcing means (1; ) are attached.

20. The method according to one or more of claims 17 to 19, characterized in that the support rods (5) during welding of the reinforcement mats

(I) to the reinforcing mats (1), in particular to the longitudinal bars (2) of the reinforcing mats (1), are welded.

21. The method according to one or more of claims 17 to 20, characterized in that the upper holding compartment part (46) in the region of the upper or lower longitudinal bar (2) of the reinforcing mat (1) and the reinforcing basket (8) is separated.

22. The method according to one or more of the preceding claims, characterized in that the holding means (5) provided with reinforcing means (1; 2; 8) in an alignment or positioning

(II).

23. The method according to claim 22, characterized in that an alignment or positioning device {11) is used, which has a horizontal, preferably cuboid, bottom plate (14).

A method according to claim 23, characterized in that an alignment device (11) is used, which is a movable alignment trolley (13), wherein on the bottom plate (14), preferably four, wheels (47), e.g. Rail wheels, are arranged on the underside.

25. The method according to one or more of claims 22 to 24, characterized in that an alignment or positioning device (11) is used, preferably two vertically and in parallel to a horizontal longitudinal direction (23) extending parallel to each other aligned outside support walls (15) and at least one, preferably 2 to 20, preferably 3 to 8 inside, ie between the outside Stutzwandungen (15) and arranged parallel to these support walls (17), wherein the support walls (15; 17) are expediently displaceable in the horizontal transverse direction (20) displaceable, in particular controllable and automatically programmable displaced.

26. The method according to one or more of claims 23 to 25, characterized in that an alignment or positioning device (11) is used, which from a top (18) of the bottom plate (14) vertically upwardly extending away Anschlagbzw , An abutment edge or -wandung extending in the transverse direction (20) and at one of two transverse sides (19) of the bottom plate (14) is arranged.

27. The method according to one or more of claims 22 to 26, characterized in that an alignment or positioning device (11) is used, the at least one centering means (24; 25) for centering and positioning of the reinforcement support frame (12) in Reference to the alignment or positioning device (11).

28. The method according to one or more of claims 23 to 27, characterized in that: that for positioning and aligning the reinforcing means

(1; 2; 8) one reinforcing means each (1; 2; 8) between each two

Supporting walls (15; 17) with vertical upward

Holding rods (5) is inserted and preferably on the horizontal and flat top (18) of the bottom plate (14) is placed.

29. The method according to claim 28, characterized in that the individual reinforcement means (1; 2; 8) after insertion by moving the support walls (15, -17) are positioned in the transverse direction (20) and fixed in the desired position.

30. The method according to claim 28, characterized in that the alignment or positioning device (11) before inserting the reinforcing means (1; 2; 8) by preferably 30 to 55 °, preferably 45 ° to a longitudinal direction (23) parallel Axis is pivoted and is pivoted back after inserting into its original position.

31. The method according to one or more of claims 28 to 30, characterized in that for positioning the reinforcing means (1; 2; 8) in the longitudinal direction (23) the reinforcing means (1; 2; 8) in the longitudinal direction (23) against the stop edge be pushed.

32. The method according to one or more of claims 23 to 31, characterized in that the alignment carriage (13) with the positioned and fixed reinforcement means (1; 2; 8) is moved to the reinforcement support frame (12) or the reinforcement support frame (12) to the Aligning and positioning device (11) with the positioned and fixed reinforcing means (1, 2, 8) is promoted.

33. The method according to one or more of the preceding claims, characterized in that a reinforcement support frame (12) is used, which is cuboidal and as outer arms (44) has two longitudinally extending longitudinal beams (26; 27) and two perpendicular to the longitudinal beams (26, -27) and also horizontally extending crossbar (28).

34. The method according to claim 33, characterized in that a reinforcement holding frame (12) is used which has at least one reinforcing bar connected to the outer frame (44), preferably with the longitudinal bars (26; 27), displaceable linearly in the horizontal longitudinal direction (23) (29).

35. The method according to one or more of the preceding claims, characterized in that

Clamping means are used, which in the transverse direction (20) of the reinforcement frame (12) extending clamping bars (31; 32), preferably in a horizontal longitudinal direction (23) of the reinforcing frame terahmens (12) to each other in alignment and low spaced from one another, and at least one of which is displaceable relative to the other in the longitudinal direction (23) of the reinforcement frame (12).

36. A method according to claim 35, characterized in that

Terminal strips (31, 32) are used, between which a width adjustable, downwards and preferably also upwardly open clamping gap (33) is set.

37. Reinforcement frame according to one or more of claims 27 to 36, characterized in that a reinforcement frame (12) is used which has at least one counter centering means (35) corresponding to the centering means (24, -25) of the alignment and positioning device (11).

A method according to one or more of claims 33 to 37, characterized in that for gripping the reinforcement means (1; 2; 8) positioned and fixed in the alignment and positioning device (11), the reinforcement frame (12), e.g. is lowered by means of a crane over the alignment and positioning device (11) such that the longitudinal beams (26; 27) of the reinforcement frame (12) are parallel and the transverse bars (28) of the reinforcement frame (12) perpendicular to the support walls (15; 17) of Ausrxchtwagens (13) are aligned.

39. Method according to claim 38, characterized in that the reinforcement frame (12) during lowering in relation to the alignment and positioning device (11) and thus to the reinforcement means (1; 2; 8) by means of the centering means (24; 25) and Gegenzentriermittel (35) is positioned in the horizontal direction.

40. The method of claim 38 and / or 39, characterized in that the upper retaining rod ends (30) when lowering the reinforcement frame (12) are inserted into the clamping gaps (33).

41. The method according to claim 40, characterized in that the reinforcement frame (12) is stopped and the holding rod ends (30) are clamped by the clamping means.

42. The method according to claim 41, characterized in that for clamping the clamping strips {31; 32) towards each other and the retaining rod ends (30) are clamped between these tight.

43. The method according to claim 41 and / or 42, characterized in that the reinforcement support frame (12) after clamping the retaining rod ends (30) with the reinforcement means {1, -2; 8) is lifted out of the alignment and positioning device (11) and the reinforcing means (1; 2; 8) are optionally immersed in an immersion bath with rust inhibitor.

44. The method according to claim 43, characterized in that the reinforcement holding frame (12) with the reinforcement means (1; 2; 8) after the anti-rust diving system or directly after the clamping and lifting out of the alignment and positioning device (11) to the casting mold (11). 4) is conveyed and placed thereon in such a way that the reinforcing means (1; 2; 8) hang into the casting mold (4).

45. The method according to one or more of the preceding claims, characterized in that the concrete cake (40) before or after the removal and removal of at least one upper Haltestabteils (46) of the individual support rods (5) is removed from the mold.

46. Reinforcing support frame (12) for use in the manufacture of reinforcing means (1; 8) of metal, in particular steel, reinforced pore or foam concrete moldings, in particular for use in the method according to one or more of the preceding claims, for the positioning of reinforcement means (1, -2, 8) in an upwardly open mold (4) and the Holding the reinforcing means (1; 2; 8) therein during the stiffening operation, the reinforcing frame (12) comprising an outer frame (44) and at least one reinforcing bar (29) spanning the outer frame (44) bridging the reinforcing bar (29) with fastening means for fastening retaining bars (5) connected to the reinforcing means <1;2; 8, characterized in that the reinforcing bar (29) or an outer frame element (26; 27; 28) at least one clamping means for clamping the holding rods (5).

47. Reinforcing frame according to claim 46, characterized in that the reinforcement frame (12) is cuboid as outer frame (44) has two horizontally extending longitudinal beams (26; 27) and two perpendicular to the longitudinal beams (26; 27) and also extending horizontally Crossbar (28).

48. reinforcement frame according to claim 46 and / or 47, characterized in that the reinforcing bar (29) with the outer frame (44), preferably with the longitudinal beams (26; 27), in the horizontal longitudinal direction (23) is linearly displaceably connected.

49. reinforcement frame according to claim 48, characterized in that the reinforcing support bar (29) by means of screws or clamps to the longitudinal beam (26, 27) is attached.

50. Reinforcement frame according to one or more of claims 46 to 49, characterized in that the clamping means in the transverse direction (20) of the reinforcing holding frame (12) extending Kleinmbalken or bars

(31; 32), which are preferably in horizontal longitudinal direction (23) of the reinforcing material frame (12) are arranged mutually aligned and slightly spaced from each other, and of which preferably at least one relative to the other in the longitudinal direction (23) of the rebar holder frame (12) is displaceable.

51. A reinforcing material frame according to claim 50, characterized in that between the two clamping strips (31, 32) a width-adjustable, downwardly and preferably also upwardly open clamping gap (33) is determined.

52. Reinforcement maintenance frame according to claim 50 and / or 51, characterized in that the clamping strips (31; 32) extend substantially over the entire length of the reinforcement retaining bar (29).

53. The reinforcing material frame according to claim 51 and / or 52, characterized in that each of the two clamping strips (31; 32) has two beads (34) extending one above the other in the transverse direction (20) and projecting into the clamping gap (33). wherein the beads (34) of the two clamping strips (31; 32) are arranged in pairs opposite one another and thereby taper the clamping gap (33) in these areas.

54. Reinforcement maintenance frame according to one or more of claims 46 to 49, characterized in that the clamping means are individual grippers having two engageable gripping claws for clamping the Halteεtäbe (5), and preferably in the transverse direction (20) along the respective reinforcing holding bar ( 29) are movable, wherein preferably a plurality of grippers per reinforcing support bar (29) are provided.

55. Reinforcing means, in particular reinforcing rod, mat or basket (1; 2; 8), of metal, in particular of steel, for foamed and / or aerated concrete bodies, comprising at least one retaining bar (5), preferably at least two retaining bars (5 ), for fastening the reinforcing means (1; 2; 8) to a reinforcement support frame (12), in particular to a reinforcement frame (12) according to one or more of claims 46 to 54, in the production of the foam and / or aerated concrete moldings, preferably by a method according to one or more of claims 1 to 45, characterized in that the holding bar (5) is fixedly connected to the reinforcing means (1; 2; 8).

56. Reinforcement according to claim 55, characterized in that the holding rod (5) has a predetermined breaking parts (6).

57. Reinforcing means according to claim 55 and / or 56, characterized in that the holding bar (5) is welded to the reinforcing means (1; 2; 8) and / or clamped and / or glued and / or attached by means of a sleeve.

58. Reinforcement according to claim 56 and / or 57, characterized in that the holding rod (5) at the predetermined breaking point (6) has a tapered cross-section.

59. A reinforcing means according to claim 58, characterized in that the holding bar (5) at the predetermined breaking point (6) has at least one, preferably two opposing notches (7).

60. Reinforcement according to one or more of claims 55 to 59, characterized in that the holding rod (5) has a diameter of 4 to 10 mm, preferably 5 to 8 mm.

61. Reinforcement according to one or more of claims 55 to 60, characterized in that the holding rod (5) made of steel, in particular stretched reinforcing steel, and / or stainless steel, and / or consists of plastic.

62. Reinforcement according to one or more of claims 55 to 61, characterized in that the holding rod (5) in the vertical direction upwards by a certain amount, in particular by 50 to 400 mm, preferably by ISO to 200 mm via the reinforcing means (1 ; 2; 8) survives.

63. Reinforcement according to one or more of claims 55 to 62, characterized in that the reinforcing mats (1) consist of horizontal longitudinal bars (2) and vertical transverse bars (3).

64. Reinforcement according to claim 63, characterized in that the reinforcement cages (8) preferably consist of two reinforcing mats (1), wherein the reinforcing mats (1) with their longitudinal and transverse bars (2; 3) are arranged parallel to each other and the Support rods (5) of the individual reinforcing mats (1) in each case on the same side and expediently substantially equally far beyond the reinforcing cage (8), and expediently simple spacer bars (9) perpendicular to the Longitudinal and transverse bars (2, 3) of the reinforcing mats (1) are aligned between two to be joined reinforcing mats (1) are arranged, the reinforcing mats (1) connect together.

65. Reinforcement according to claim 63 and / or 64, characterized in that the holding rods (5) are elongated transverse rods (3), which consist of a transverse bar (3) and a subsequent to the cross bar holding area.

66. Reinforcement according to one or more of claims 63 to 65, characterized in that the support rods (5) on the longitudinal bars (2) of the reinforcing mats (1) are attached.