DE3543369A1 - Process for reinforcing prefabricated reinforced-concrete compound units and apparatus for carrying out the process - Google Patents

Abstract

The invention relates to a process for reinforcing prefabricated reinforced-concrete compound units by means of reinforcing wires in order to produce mild-steel-reinforced concrete, and an apparatus for carrying out the process. The object of the present invention is to rationalize the entire operation of introducing the reinforcing means into prefabricated mild-steel-reinforced-concrete compound units by using conventional reinforcing steel in rings. The object is achieved according to the invention by the following features: a. the reinforcing wires are unwound from reels; b. the reinforcing wires which have been unwound are straightened out; c. the straightened reinforcing wires are laid out on the concreting mould; d. the laid-out reinforcing wires are stretched by subjecting them to a tensile force which is restricted such that the reinforcing wire is pulled straight but is not deformed by longitudinal extension. t

Description

The invention relates to a method for reinforcing prefabricated Reinforced concrete components using reinforcing wires to create slack reinforced concrete and a device for carrying out the Procedure.

Many reinforced concrete components are prefabricated at the factory, so for Example ceilings, walls, supports, beams and purlins. It poses the reinforcement of these reinforced concrete components with reinforcing steel, in particular cutting, laying the reinforcing steel in the concrete form, securing the position against displacement, as well as placing a distance brackets to secure the concrete cover in relation to the outer edge of the reinforced concrete component a significant proportion of the total effort represents.

Up to now, slack-reinforced reinforced concrete has generally been used for the production Reinforcing steel in lengths of 12 to 14 meters, in exceptional cases too up to approx. 20 meters in straight lengths to processors delivered. Using so-called cutting and measuring trolleys if the rebar is cut, the cut ones are cut Rods brought to the place of use. Before pouring the concrete the reinforcing bars must be fixed using suitable fasteners be fixed in their intended position, be it in the concrete form yourself or beforehand by weaving reinforcement cages. This  The process is very labor-intensive and there is also waste.

For certain areas of application there are welded reinforcing steel mats, by using them the workload can be reduced. There are expensive systems for producing the welded reinforcing steel mesh required, so these mats are usually made by large factories manufactured and delivered to further processors. Doing there so-called storage mats, i.e. standardized sizes and Diameters and list mats are made to order Mats. The storage mats have the disadvantage that they each needed size must be cut, taking considerable work effort and loss of cut occurs that are made to order List mats, on the other hand, are expensive and lacking in series production require longer delivery times, which is usually too for the users Leads to difficulties.

There is also reinforcing steel in rings, depending on the user required length straightened by straightening and cutting systems and cut to length. This technique eliminates the Loss of cut, such as when using rods in factory lengths is inevitable, rationalize the further work by finished installation in the concrete form but hardly.

In addition to the flaccid reinforced shotcrete, there is prestressed concrete, in which tensioning wire is supplied in rings. The tension wire is a high quality and tempered wire with a tensile strength in the range of approximately 150 kg / mm ² , in exceptional cases up to 210 kg / mm ² . When using prestressed concrete and the associated tension wire, it is common to pull the tension wire from the roll and to pull it out directly over a longer shape without the interposition of a straightening roll set. Each tension wire is then individually tensioned in a special tensioning device by applying a high tensile force. Due to the applied tensioning force, the tensioning wire is pre-tensioned up to 80% of its tensile strength. What is important here is the deformation of the tensioning wire, which is fully utilized up to the proportionality limit. Each tension wire is anchored under tension at the ends by special anchoring devices, and after the concrete has hardened, these end anchors are released again. It is the purpose of the prestressing concrete to pre-stress the enveloping concrete by springing back the prestressing steel before applying the working load, in order to completely or partially remove tensile stresses in the concrete as a result of longitudinal force and bending moment.

It is an object of the invention to provide a method for reinforcing prefabricated reinforced concrete components using reinforcement wires Generation of flaccid reinforced concrete with which to create entire insertion of the reinforcement in the reinforced concrete components below Use of normal reinforcing steel in rings decisively rationali is settled. It is also an object of the invention to provide a device to provide for the implementation of the method.

The task is solved by a method for reinforcing pre manufactured reinforced concrete components using rebars to the Er production of flaccid reinforced concrete by the following features is marked:

• a) The reinforcement wires are from an unwinding device unwound,
• b) the reeled out reinforcement wires are straightened,
• c) The directional reinforcement wires are on the concrete form designed,
• d) the laid out reinforcement wires are made by applying a Tension tensile, which is limited so that the reinforcement the wire was drawn straight, but not in the sense of longitudinal expansion is deformed.

The method according to the invention is already economical, if only A ring with a straightening device is available that is economical speed increases by leaps and bounds when a multitude of rings and straightening facilities whose investment costs are relatively low, for Commitment comes. For example, there can be six or twelve reinforcement bars wires are unwound, straightened and pulled out at the same time. Because experience has shown that reinforcing steel in rings after straightening, especially for long lengths that are not yet absolutely straight, the  Reinforcement wire pulled out of the concrete form then similar to in the case of prestressed concrete, tensioned by applying a tensile force, that it becomes absolutely straight. However, it is not the purpose of the invention as with prestressed concrete, the prestressing steel under high internal tension to put. The tensile force is only dimensioned so that it is the steel straightens, but the internal tension of the steel remains clear below the proportionality limit of the steel. To carry out the method therefore suffices simple clamping devices that hold the reinforcement wire.

A special feature of the method provides that the designed Reinforcement wire is tensioned using a straightening roller set, by a roller of the straightening roller set designed as a driving roller driven in the opposite direction of rotation to the unwinding device becomes. The reinforcement wire unwound from the unwinding device is expedient by means of a pulling wagon over the concrete form pulled, the reinforcement wire is straight from the straightening roller set directed, the reinforcement wire facing away from the straightening roller set Fixed the end of the concrete form, a tensile force on the reinforcement wire by driving the driving roller in opposite rotation direction and then the reinforcement wire on the direction end of the concrete form facing the roller set. Due to the slight tensioning of the reinforcement wire at its ends its secure fixation in the intended position is facilitated and the number of the usual spacers can be reduced. If all reinforcement wires are pulled out and slightly tensioned, the Concrete applied, the reinforcement wires remain under tension until the concrete has set or is solid. Only after become the means to apply tension to the reinforcement wires away.

The bond between concrete and steel required in reinforced concrete can be significantly improved by the method according to the invention. If the reinforcement bars are only loose and the shape inserted, you can they easily vibrate when the fresh concrete is shaken be set, with the result that in the range of the vibration range the concrete composite is broken. However, the reinforcement is by light  Tension and anchoring in position outside of the concrete form fixed, their position is unaffected by the shaking of the mold and the Concrete becomes particularly intimate with the surface of the reinforcement wire connect. Therefore the proposed method can also serve to use high-strength reinforcing steel as sagging reinforcement, with strength values that lie approximately in the middle between so far usual beston steel and prestressing steel.

A special embodiment of the method provides that several reinforcement wires, preferably two to three wires tight be laid close to the concrete form. It is through this possible to form so-called rod bundles from reinforcing steel in rings, which are slightly tense so that they act as one. The use of such bundles of rods can offer great advantages, because you can get through from a limited number of thin reinforcement wires the assembly into bundles of two or three, for example Reinforcement strands with a larger cross section can form the more normal way of reinforcing steel in rings are not achievable because reinforcing steel in rings usually to a maximum diameter of 12 to 14 mm is limited. Usually the formation of bundles of rods is off Individual bars are expensive because the bars must lie close together and therefore appropriate connecting means, for example holding brackets or welding spots are required at regular intervals. By slightly tensing the ends, the reinforcement wires become automatically in the proposed embodiment of the method fixed and held together over the entire length.

The process is particularly economical if the Unwinder through the set of reinforcement wire is attached to a clamping device of the drawing carriage, preferably several wires at the same time side by side, the pulling carriage these Reinforcement wires to the opposite end of the concrete form pulls where they are fixed, the pulling carriage then moves back and at the same time all the laid reinforcement wires through the drive roller be tensioned in the straightening roller set and the tensioned reinforcement wires at the end of the concreting mold facing the straightening rollers fixed and cut off there. It is advantageous if  also the unwinding device and the straightening roller set on one Platform trucks are arranged and after cutting off the Reinforcement wires of the platform carriage is moved laterally and the next segment of the concrete form or the next concrete form accordingly covered with reinforcement wires.

To carry out the method described above, a Proposed device that is characterized by at least an unwind arranged on an end face of the concrete form Direction with reinforcing steel in rings, one from the front of the Concrete mold back and forth to the other face of the concrete mold mobile drawing car, with at least one clamping device, one nachge the ring ordered straightening roller set, as well as a device for tensioning the Reinforcement wire and devices for fixing the from the ring reeled off reinforcement wire in the area of the two end faces the concrete form.

The reinforcement wire is removed from the ring by hand or by an auxiliary device through the straightening rollers of the straightening roller set guided until the start of the concrete form. There the wire is in the clamping device on the pulling wagon, for example a motor trailed wagon, and then this wagon pulls the Reinforcement wire from the unwinding device down through the direction roll up to the opposite end of the concreting mold where it sticks is placed.

A plurality of unwinding devices are preferably provided and each Ring is assigned a straightening roller set, so that several reinforcement wires can be clamped to the pulling wagon at the same time and here due to the possibility of multiple reinforcement wires at the same time deduct and judge.

A special embodiment of the invention provides that the Straightening roller set has a driving roller, which has a clutch is connected to a motor, the Direction of rotation of the drive roller opposite to the direction of rotation when pulling out the reinforcement wire. The embodiment  allows the tensile force after laying the reinforcement wire to be applied to the wire directly through the straightening roller set. Overdrawing of the reinforcement wire is automatically avoided, because the driving roller can only exert a limited force due to friction can and immediately after pulling the reinforcement wire straight loses frictional contact and begins to spin. The one from the dir forces that can be transferred to the reinforcement wire are thus too dimensioned that the internal tension of the reinforcement wire below the Deformation limit of the steel remains. The contact pressure of the drive roller regarding the co-operating role of the leveling role rate is adjustable so that it applies to the reinforcement wire apparent force can be varied. At the moment of spinning the straight rebar set and the wire between the severed there clamping device and the straightening roller set.

Another preferred embodiment of the invention provides that the concreting form parallel to its end face with recesses arranged at intervals, in particular U or V has shaped recesses for inserting the reinforcement wires. The Embodiment particularly relates to devices for production fully or partially prefabricated ceiling tiles. With such blankets it is required that the reinforcement on both supports ends protruding freely. Due to the arrangement of the Lateral positions remain at the spacing of the desired element lengths between the transverse positions delimiting the individual elements So much free space in each case that the reinforcement in both elements protrudes freely. The embodiment is particularly suitable for the production of partially prefabricated ceiling tiles of about 4 to 6 cm Thickness. Are these slabs reinforced and as described is concreted, which extends over the entire length of the track Reinforcement between two plates with a suitable one Cutting device, for example a saw cut. Since all For example, bars in concrete can be held firmly in place move the saw across the entire concrete form in a guide be without special holding devices for the concrete bars required are. This is a significant advantage because when cutting Of rebars, the fixtures are usually an important one  Role-play. The reinforcement wires can thus be continuous be cut, the otherwise usual and necessary process of Length measurement of the reinforcement bars is not necessary because the cut length in adaptation to the element length automatically results.

The distances of the straightening roller sets advantageously correspond to the distances between the recesses of the transverse positions.

The ring or rings and the straightening roller sets are intended moderately arranged on a platform trolley that is transverse to the concrete form is movable, especially on rails. Hereby it is possible to use different one and the same basic device Reinforcing elements such as beams, floor slabs, etc.

Further features of the invention are in the description of the Figures and represented in the subclaims, it being noted that all individual characteristics and all combinations of individual characteristics are essential to the invention.

In FIGS. 1 to 8, the invention is shown in one embodiment, for example, without being limited to this embodiment.

It shows:

Fig. 1 is a schematic plan view of the device according to the invention with three Betonierformen,

Fig. 2 is a longitudinal section through one of Betonierformen,

Fig. 3 is a plan view of an alignment roller set,

Fig. 4 is a side view of the alignment roller set,

Fig. 5 is an enlarged plan view of the alignment roller set,

Fig. 6 is a plan view of the Betonierform in the region of a transverse shut off and a terminal strip,

Fig. 7 is a partial perspective view of the transverse parking and the terminal block and

Fig. 8 is a perspective view of a terminal block with several reinforcement wires in each recess of the terminal block.

In Fig. 1, three concreting molds 1 are shown, the broken illustration clarifying that the concreting molds 1 can have any length. Rails 2 run parallel to the long sides of each concrete form 1 . Each concrete form 1 is assigned a drawing carriage 3 , which can be moved back and forth on corresponding rails 2 . The drive of the pulling wagons 3 is not shown in detail, the drive can take place for example by means of a motor arranged on the pulling wagon. In the area of the front end face 4 of the concrete molds 1 , rails 5 run perpendicular to the rails 2 . On the rails 5 are movable platform carriage 6, wherein each Betonierform 1, a platform car is assigned. 6 Each platform carriage 6 carries six unwinding devices 7 with reinforcing steel in rings and six straightening roller sets 8 .

As illustrated in the illustration in FIGS. 1 and 2, the rings rest directly on the platform carriage 6 . The outlet of the reinforcing steel is located in the area of the bearing surface of the ring on the platform carriage 6 , the straightening roller sets 8 are arranged on a cantilevered part facing the relevant concrete form 1 , which is connected to the platform carriage 6 . FIGS. 3 to 5 show the construction and the arrangement of a unit 11 combined six straightening roll sets 8 each Betonierform. 1 The straightening roller sets 8 are constructed in the usual way, they consist of six straightening rollers 12 which receive the reinforcing wire 9 between them. Due to the arrangement of the straightening rollers 12 of a straightening roller set 8 which is in a gap, the reinforcement wire 9 is straightened when it is pulled through the straightening roller set 8 . The straightening rollers 12 are arranged so that their longitudinal axis runs vertically, one of the straightening rollers, namely the straightening roller 12 a is directly adjacent to a straightening roller 12 , so that the connecting line of the longitudinal axes of the straightening roller 12 in question and the straightening roller 12 a perpendicular to the longitudinal extension of the reinforcing bar 9 lies. The straightening rolls 12 and 12 are as far as a proximal to each other that the reinforcing rod 9 is clamped between the two straightening rollers. The straightening roller 12 a acts as a driving roller. It can be driven by means of a motor 13 via a clutch 14 both clockwise and counterclockwise. The TreibroIle 12 a is - relative to the illustration of FIG. 5 - is driven clockwise, when the reinforcement wire is to be inserted into the guide roller assembly 8 and 9 counterclockwise sense driven when the reinforcing wire 9 is to be strained. The latter sequence of movements is illustrated in FIG. 5 by the simple arrows. The double arrow in this figure illustrates that the drive roller 12 a on the corresponding drive roller 12 and can be moved away from it, and thus the contact pressure between the two rollers 12 and 12 a is adjustable, whereby a different amount of tension can be applied to the reinforcing wire 9 is.

Each concreting mold 1 has a clamping strip 15 in the region of its end face 4 and a clamping strip 17 in the vicinity of the other end face 16 . The drawing carriage 3 also has a clamping device 18 . The clamping device 18 consists of six conventional clamping jaws 19 .

At the same time, six reinforcement wires 9 per concreting form 1 can be designed. The six reinforcement wires 9 are slightly unwound from the unwinding devices 7 so that the ends of the reinforcement wires can be inserted into the straightening roller sets. The drive rollers 12 a are moved clockwise so that the reinforcement wires are conveyed through the straightening roller sets. The ends of the reinforcement wires are anchored to the drawing carriage 3 by means of the clamping jaws 19 . The pulling wagons are then moved from the front end 4 to the rear end 16 , the reinforcement wires being further wound by the unwinding devices 7 and the wires being straightened by the straightening roller sets 8 . The motor for driving the drive roller 12 a is out of operation. Fig. 1 illustrates the drawing car in the upper representation at the beginning of the laying process, the middle representation of the drawing carriage shortly before the end of the laying process, the lower representation after the end of the process. If the pulling carriage 3 has reached its end position, the six reinforcement wires 9 are anchored by means of the terminal strip 17 , which is arranged in the region of the pulling carriage 3 between the latter and the front end face 4 . If the wires are clamped, the jaws 19 of the clamping device 18 of the drawing carriage 3 are opened and the reinforcement wires are removed from them. The drawing carriage 3 can then be moved back into its starting position depending on the desired production process. Are the reinforcement wires fixed by the terminal block 17 , the drive rollers 12 a are driven counterclockwise, so that the laid reinforcement wires are subjected to a tensile force. The force is dimensioned due to the distance between the drive roller 12 a and the corresponding straightening roller 12 so that the reinforcing wire in question is pulled straight, but is not deformed in the sense of a longitudinal expansion. The reinforcement wires are fixed in the tensioned state by means of the clamping strip 15 arranged in the area of the front end face 4 . The motor 13 for driving the driving roller 12 a is stopped and the reinforcement wires between the terminal block 15 and the straightening roller sets 8 are separated. Then the platform carriage 6 with the unwinding devices 7 and the straightening roller sets 8 could be moved to another form of concreting.

Fig. 6, the two sides 20 shows a Betonierform 1 in the region of one of the clamping strips 15 or 17 when fully inserted reinforcement. It can be seen that a transverse stop 21 is provided at a slight distance from the terminal strip. Both the clamping bar and the transverse stop 21 have 9 V-shaped recesses corresponding to the number of reinforcement wires, the reinforcement wires being inserted into the base of the recesses. Both the terminal strips and the transverse setting are designed as an angular profile, the clamping strips 15 and 17 are firmly connected to the concrete mold 1 , the transverse setting 21, on the other hand, is arranged to be movable in the concrete form 1 . It can be seen from the illustration in FIG. 1 that the concreting mold 1 has a large number of such transverse stops 21 . Between each 2 spaced at a small distance transverse turnarounds 21 later a free space remains, that is, this space is not filled with concrete so as to form c during the later concreting per Betonierform 1 three concrete elements 1 a, 1 b and the first The transverse stops 21 are designed so that the tensioned reinforcement wires 9 are pressed against the bottom of the recesses 22 . When the concrete is subsequently shaken after concreting, this ensures that the reinforcement wires are held in a defined manner in the transverse positions 21 without additional tools being required.

FIGS. 7 and 8 show clamp means 23 for securing the loading wehrungsdrähte. 9 The clamping means 23 are plate-shaped and have a downward V-shaped recess 24 . A clamping means 23 is placed on each of the reinforcement wires 9 , namely on the end face 16 facing side of the terminal strip 17 in this terminal strip and on the end face 4 facing side of the terminal strip 15 in the latter terminal strip. The clamping means 23 have an upward extension 25 on which they are gripped, by means of a hammer the clamping means 23 are knocked down, as a result of which the respective reinforcement wire between the V-shaped recesses of the relevant clamping means 23 and the recess 22 of the terminal strip is set. Fig. 8 shows a terminal block, in which the recess 22 is trapezoidal. In the bottom of the recess 22 , a wire bundle 26 consisting of three reinforcement wires is arranged, which is held by a corresponding clamping means 23 . This clamping means has a triangular-shaped recess, the opening angle of the triangle being larger than in the clamping means as shown in FIG. 7.

Claims (13)

1. Method for the reinforcement of prefabricated reinforced concrete components by means of reinforcement wires for the production of slack-reinforced reinforced concrete, characterized by the following features:

• a) the reinforcement wires ( 9 ) are unwound from unwinding devices ( 7 ),
• b) the reeled-off reinforcement wires ( 9 ) are straightened,
• c) the directional reinforcement wires ( 9 ) are laid out on the concrete form ( 1 ),
• d) the designed reinforcement wires ( 9 ) are tensioned by applying a tensile force that is limited so that the reinforcement wire ( 9 ) is pulled straight, but is not deformed in the sense of a longitudinal expansion.

2. The method according to claim 1, characterized in that the designed reinforcing wire ( 9 ) is tensioned by means of a straightening roller set ( 8 ) by a roller ( 12 a) designed as a roller of the straightening roller set ( 8 ) is driven in the direction of rotation opposite to the direction of rotation. 3. The method according to claim 2, characterized in that the reinforcement wire ( 9 ) unwound from the unwinding device ( 7 ) is pulled by means of a pulling carriage ( 3 ) over the concrete form ( 1 ), the reinforcement wire ( 9 ) straightened by the straightening roller set ( 8 ) the reinforcing wire ( 9 ) is fixed to the end of the concreting mold ( 1 ) facing away from the straightening roller set ( 8 ), a tensile force is generated on the reinforcing wire ( 9 ) by driving the driving roller ( 12 a) in the opposite direction of rotation and then the reinforcing wire ( 9 ) is fixed at the end of the concreting mold ( 1 ) facing the straightening roller set ( 8 ). 4. The method according to any one of claims 1 to 3, characterized in that a plurality of reinforcement wires ( 9 ), preferably two to three wires are laid out close to each other on the concrete form ( 1 ). 5. The method according to any one of claims 2 to 4, characterized in that from the unwinding device ( 7 ) through the straightening roller set ( 8 ) guided reinforcing wire ( 9 ) is attached to a clamping device ( 18 ) of the drawing carriage ( 3 ), preferably a plurality of wires (9) next to one another, the drawing carriage (3) simultaneously pulls these reinforcing wires (9) to the opposite end (16) of Betonierform (1), where they are fixed, the drawing carriage (3) then moves back and at the same time all the designed reinforcement wires ( 9 ) by the driving rollers ( 12 a) in the straightening roller sets ( 8 ) and the strained reinforcing wires ( 9 ) on the straightening rollers ( 12 ) facing end ( 4 ) of the concrete form ( 1 ) are fixed and cut off there. 6. A method according to claim 5, characterized in that the unwinding device (7) and the guide roller assembly (8) mold carriage on a flat (6) are arranged, and after the cutting of the reinforcing wires (9) of the platform wagon (6) is moved laterally and next segment of the concreting form or the next concreting form accordingly covered with reinforcement wires. 7. Device for performing the method according to one of claims 1 to 6, characterized by at least one on one end face ( 4 ) of the concrete form ( 1 ) arranged unwinding device ( 7 ) with reinforcing steel in rings, one of the end face ( 4 ) of the concrete form ( 1 ) to the other end face ( 16 ) of the concrete mold ( 1 ) reciprocating drawing carriage ( 3 ), with at least one clamping device ( 18 ), a ring roller set ( 8 ) downstream of the ring, and a device ( 12 a) for tensioning the Reinforcement wire ( 9 ) and devices ( 15 , 17 ) for fixing the reinforcement wire ( 9 ) unwound from the ring in the region of the two end faces ( 4 , 16 ) of the concrete form ( 1 ). 8. The device according to claim 7, characterized in that the straightening roller set ( 8 ) has a drive roller ( 12 a) which is connected via a clutch to a motor ( 13 ), the direction of rotation of the drive roller ( 13 ) during operation of the motor ( 13 ). 12 a) sets against the direction of rotation when pulling out the reinforcement wire ( 9 ). 9. Apparatus according to claim 7 or 8, characterized in that a plurality of unwinding devices ( 7 ) and straightening roller sets ( 8 ) are provided. 10. Device according to one of claims 7 to 9, characterized in that each straightening roller set ( 8 ) is assigned a motor ( 13 ). 11. The device according to one of claims 7 to 10, characterized in that the concreting mold ( 1 ) parallel to the end faces ( 4 , 16 ) has transverse stops ( 21 ) with spaced recesses ( 22 ), in particular the U or V -shaped recesses for inserting the reinforcement wires ( 9 ). 12. The apparatus according to claim 11, characterized in that the distances between the straightening roller sets ( 8 ) from each other corresponds to the distances of the recesses ( 22 ) of the transverse stops ( 21 ). 13. Device according to one of claims 7 to 12, characterized in that the unwinding device (s) ( 7 ) and the straightening roller sets ( 8 ) are arranged on a platform carriage, in particular rail-bound platform carriage ( 6 ), which is perpendicular to the direction the extended reinforcement wires ( 9 ) can be moved.