WO2004065086A2 - Mobile, compact and flexible on-site casting facility - Google Patents

Abstract

The invention relates to a battery formwork arrangement that comprises at least one formwork chamber and one actuator for an on-site support for the removal of formwork from precast concrete parts. The invention is characterized in that the actuator is configured as an actuator that acts upwards to overcome adhesive forces and the formwork chamber is adapted to be removed from the top. The invention also relates to formwork with wall and bottom areas whereby the bottom area comprises a base and the walls are disposed on the base so as to be displaced and/or slid, thereby providing a mobile, compact and flexible on-site casting facility for construction sites.

Description

Title: Mobile, compact and flexible field factory

description

The present invention relates to what is claimed in the preamble and is therefore concerned with the battery formwork of precast concrete parts.

Battery circuit arrangements are known. They already serve to be able to economically manufacture a large number of precast concrete parts on construction sites in a short time. This affects e.g. elongated precast concrete parts such as Beams, semi-finished beams, purlins and supports of general building construction, which are installed in large numbers for each building without any significant change to each other. However, this also includes ram piles for the foundation formation and / or noise barrier elements.

It has already been proposed to rotate a battery shutter assembly for stripping and to assist stripping by a depressing means. A battery formwork arrangement can be filled with concrete from above and rotated after the precast concrete parts have hardened, so that the concrete parts then fall down after they are released from the chamber. The precast concrete parts are typically removed from the formwork chamber with power, i.e. by means of actuators.

In addition, the aim should be to achieve a production technology that is also suitable for others on a large scale on or on construction sites

- l Number required, in particular both elongated and non-elongated precast concrete parts can be used. A site size of more than 100 m ^{3 of} precast volume is typically relevant here.

The problem now is that the arrangements with rotating formwork are not suitable for all precast concrete parts. It is desirable to enable a wider use of battery-powered precast concrete.

The object of this invention is to provide something new for commercial use.

The solution to this task is claimed in an independent form. Preferred embodiments can be found in the subclaims.

The present invention thus proposes, in a first basic concept, a battery formwork arrangement with at least one formwork chamber and an actuator for supporting precast concrete parts at a location at which it is provided that the actuator acts as an upwardly acting actuator and the formwork chamber or arrangement is designed to remove the formwork.

The present invention is therefore based on the knowledge that the savings from bulky or wide prefabricated parts by stripping several parts at the same time with just one hand movement is not as great as with many small parts, but nevertheless allows considerable savings with suitable series production, unless it is rotated like in State of the art, * but a different approach is realized.

What is essential as a finding is that an actuator can also be used to act against gravity and additionally serves to overcome the adhesive forces, that is to say only to release it from the shape, but not to remove it from it. A typical actuator stroke distances between e.g. Allow 0.5 to 5 cm. The formwork chamber will then be open at the top, i.e. it will not be turned into a position with the side open at the bottom.

In the case of such wide or voluminous parts, preferably over 40 cm wide or over 0.5 m ³ volume and particularly preferably over 0.5 m width or over 1 m ³ volume, an operating mode which consists of this can be preferred not to turn the formwork, but to push the concrete parts out of the formwork by means of particularly strong actuators for stripping so that a hoist can lift the beam without having to pull the static friction and the adhesive forces to the formwork wall. In addition, the dead weight does not have a relieving effect, but rather a strain on the actuator. It is astonishing here that there is at most a slight component deformation even in the case of actuators with a small area, so that there is no risk of destruction of the finished part.

It is possible to press from below with a strong actuator against the adhesive forces of the concrete, particularly against the formwork walls, and also against the weight of the precast element, which is now stressful. In order to limit the cylinder stroke, reduce the concrete pressure to the finished part and the to compensate for different and preferably variable heights without increasing the stroke of the cylinder, a particularly preferred variant can be provided with an element that is height-adjustable and pressure-transmitting, for example, by means of a thread

It should be mentioned that the actuators can be arranged on a base frame that is connected to a battery formwork substructure in a tensile manner. In particular, combinations of threads and sleeves can be used to attach the stamp.

The actuators will typically act hydraulically. This allows the use of a robust technology that is suitable for use on construction sites and in which, in particular, pressure equalization between different actuators is achieved when working with several actuators without having to undertake considerable control efforts. In addition, the work safety required even at high hydraulic pressures can be easily achieved. Special measures for occupational safety are preferred in hydraulics, e.g. to prevent hydraulic oil from spurting out even over longer strokes under a typical water column of 1000 to 7000 m. Encapsulation of lines, counterbalance valves, flow limiters, etc. are representative here. - _.

^• The base frame is particularly torsion-proof to enable it to be set up on an uneven surface without any formwork chamber deformation.

The repetitive structures are, as I said, no longer just filigree, but also more solid than in the prior art of rotary formwork, because the savings made by rotating the formwork only become great if as many parts as possible are accommodated in it, if the parts are therefore more “delicate”.

A multifunction device used in the production of concrete parts is preferably used for the invention supplemented with a lifting device. This lifting device then preferably lifts several reinforcement cages at the same time, for example. from a pre-arranged shelf in which the iron maker can either prefabricate or also deliver prefabricated and store it in a defined manner so that the subsequent reinforcement installation can then be automated or accelerated. It is particularly preferred if the multifunction device is self-propelled, in this case it is also preferred to create an off-road capability so that the surroundings do not have to be specially prepared for use. You get a self-propelled, all-terrain gantry crane with multi-functional quality.

Alternatively and / or additionally, depending on the construction site, positioning of the formwork sufficiently close to a tower crane can be preferred. The particularly economical operation here consists of direct lifting and depositing or also direct lifting and mounting in one. Operation. All kinds of hoists can be used, but a tower crane covers very large construction site areas with effective radii of typically 30 to 55 m. It is also particularly suitable, since the usual approach of the mobile cranes is no longer necessary, for example for smaller assembly files, which typically do not fill up a whole day and therefore require the start-up and shutdown efforts of mobile cranes. This production is particularly preferred when non-returnable individual parts are manufactured, which can therefore be installed directly in the formwork layer, so that direct installation is possible without additional handling, for example by installing attack elements for crane hooks and the like. Alternatively, an intermediate storage on a construction site takes place between the formwork location, which is typically fixed over several cycles, and the respective installation site, whereby such an intermediate storage, in particular together with the installation site and the battery formwork, can lie in the swivel range / swivel ranges of tower cranes. Costly arrivals and departures of additional mobile cranes are often no longer necessary.

However, especially if the tower cranes are not suitable for the high prefabricated loads of over 2.5 t / precast or often over 5 to 10 t / per part, the above. simple intermediate handling can also be carried out particularly preferably with mobile cranes.

The prefabricated concrete parts should therefore preferably be moved with a maximum of two stops from manufacture to the place of installation, regardless of the type of crane used. , ... -

It is particularly preferred if a plurality of shuttering chambers are provided in a battery shuttering arrangement, in particular at least two shuttering chambers parallel in the longitudinal direction, in order to produce a plurality of identical or similar components at the same time. This is preferred because the battery formwork arrangement of the present invention is preferably used for repetitive structures and the formwork chamber mern make it possible to either produce several identical components or components that differ in height and / or length, but not in width. This is preferred because the width variation requires different side wall layers and is therefore more complex to implement.

The formwork chambers can be formed with a variable geometry, which means that it is possible to choose a system battery formwork arrangement that works from the construction site

Construction site or, during a construction on a construction site, always adapted to different needs. For this purpose, displaceable side and / or wall elements can be provided and / or inserts or floor formwork can be provided which are suitable for producing the desired elements.

In this way, small series of 20 to 50 parts can be produced without any problems, especially if the pieces are only of the same width but of different lengths.

In another essential aspect of the invention and viewed as separately protectable, such walls are present. These displaceable side and / or wall elements can be provided in particular on a base frame or base frame, specifically by means of detachable means. In this way, a modular formwork system is obtained which can be removed from the top and reinforced from above. It should be emphasized that the walls can be moved between several cycles, but not for demoulding. The battery formwork arrangement now proposed is particularly preferred when wider components are to be produced, in particular those with a width of more than 40 cm and more preferably more than 50 cm. The arrangement is currently particularly economical if a volume of at least 0.5 m ³ , preferably from Im ^{3 is} reached and is then even more economical than the known battery rotary formwork.

The formwork can be made much easier in any case if the vertical walls of the finished parts have an inclination of about 1:20. If the incline is over 1:40, the formwork is not made much easier; if it is below 1:10, there is no further relief, but an unhelpful change in shape due to walls that are too flat does. The provision of a fall facilitates the stripping, so that movement of the walls for the purpose of stripping is no longer necessary.

It will be preferred with the invention to change the wall position only if one or more other precast concrete parts are to be manufactured, that is to say to leave the wall stationary and / or unchanged during the actual production cycle. This also applies if the actuator, which is preferably provided for overcoming adhesive forces between the walls or floor and the precast concrete part, is omitted and instead the higher forces during stripping, which are to be overcome by means of the lifting arrangement, are permitted. However, it is easily possible, in particular, to remove end walls for stripping, for example when reinforcements extend over the component, in order to facilitate anchoring during installation. Protection is therefore also generally claimed for a method for producing an elongated precast concrete part, it being provided that near the construction site, in particular at a simply equipped production site, where appropriate and preferably also under the open sky, a slack reinforcement is placed in a variable form and with concrete is shed. It was recognized here that the rotary shell production of the invention preferred for railway sleepers can also be used for other, in particular elongated precast concrete parts such as ram piles, purlins and the like.

The elongated prefabricated concrete parts can be manufactured with the same shape and / or in a different shape from each other end to end and / or long side to long side in a battery mold.

It should be noted that even elongated precast concrete parts under 3 m can be formed transversely to the longitudinal direction of the rotating shell. Formwork widths of this type are particularly problem-free in order to create road traffic at the construction site. Typical filling volumes are about 5 to 15m ³ per battery.

In a particularly preferred variant, a formwork form is used which has a stable, preferably also torsionally rigid base module, on which a plurality of formwork chambers are provided in an independent form. These formwork chambers are preferably assembled modularly, which enables the production of smaller series even in conventional building construction with the arrangement described. In this way, purlins, beams or long supporting pieces can be manufactured in order to to preserve filigree repetitive structures. The formwork elements can be combined in various ways, which allows the flexible pre-assembly of a form, for example in a warehouse for component formwork modules, after which it is possible to manufacture exactly the required, different parts from one another at the construction site. It should be pointed out that in the individual formwork modules which are attached to a base module or underframe, floors which can be displaced in height in particular can be used instead of known insert boxes. Preferred elements are all elements particularly known from frame formwork.

The process is now also suitable for massive repetitive structures and / or for small series, whereby no more than 100 identical parts as series of general building construction are no longer required, as was typical for small series, but rather can be coordinated well with the construction site dates in the work preparation Flexible widths and path assignments 20 to 50 series are sufficient, in which only the width is the same, while other dimensions vary, because in particular the heights and especially the lengths of the parts can be adjusted with little effort. The term "web" is understood to mean a row of prefabricated concrete parts made forehead to forehead, the typical web length corresponding to an uncoupled underframe.

A particularly preferred effect of arranging displaceable, stable and load-bearing side walls is that the main surface of the expensive formwork work has been inserted into a simple, flexible and construction site-compatible system. A coupling of several battery formworks in their length is preferably made possible, which reduces the incorrect assignment due to part lengths which are unfavorable compared to the battery length (example: 3 instead of only 2 6.00 m long parts per lane can now fit in 2 coupled 10 long batteries).

These smaller series in particular make the battery process particularly interesting for other parts of structural engineering. Likewise, compared to the battery rotary formwork process, the space requirement is reduced in the generally cramped conditions of a construction site.

In order to avoid undesired bending and normal force in the battery formwork, it is preferred to use only loose reinforcement without prestressing. For the sake of disclosure, it should be mentioned that prestressing with subsequent bonding is possible without any problems.

In the production of precast concrete, the mold can be cleared from the top in a particularly preferred variant, which also ensures that the mold is completely filled. A separate broaching arrangement or a multifunction device with appropriate equipment can be provided for clearing. ... ,

For this purpose, for example, a movable broaching system can be provided, which is used to clear away excess concrete and / or in particular when the clearing blade is folded away, to insert reinforcement and / or to selectively add concrete in the final call for exact form filling from a storage drum or the like, which can be tilted into an open position and / or which serves for the assembly of concrete part sets in the production of concrete parts, and / or contains a lifting unit. The clearing blade can preferably be folded or dismantled for inserting reinforcement and, moreover, is arranged on a sliding yoke to enable tilting, clearing clearing movements. The multifunctionality reduces the reinforcement transport costs on the construction site and / or the total transport costs of the material to be brought to and / or moved to the construction site. With such an arrangement, a transverse transport of reinforcing steel on the construction site and / or a transport of prefabricated parts to be excavated on the construction site can be provided without the scarce and expensive crane resources being burdened. This also helps if the drive motor of the broaching unit can be removed and is designed to drive further units such as lifting traverses etc.

It is particularly preferred, regardless of the presence of a multifunction device, to position the batteries in such a way that they are in the immediate swivel range of a tower crane.

Not only general lifting work can now be done without additional effort, but also the lifting of the parts and their direct assembly "just in time".

The invention is described below and, for example, with reference to the drawing. This is shown by:

1 is a plan view of a suitably designed formwork form for a small building series, 2 shows a basic module as a formwork frame,

Fig. 3 shows a chamber wall cross section for a

Finished part of variable widths and heights, Fig. 4 with an extendable pressure stamp

Ausschalhydraulik. 5 a, b, c a multifunction device which can be used in the method, in particular for inserting reinforcement, clearing excess concrete, for metering concrete in the final call and / or for assembling concrete part equipment or lifting precast concrete parts

According to FIG. 1, a form of form generally designated 1 comprises formwork chambers 2 and walls 3 surrounding it. As can be seen, several formwork chambers are provided in the formwork arrangement, a plurality of formwork chambers of the same width 2a, 2b, 2c, 2d, 2e in a row can be provided.

Details of the formwork chamber wall construction are shown in Fig. 2 and 3. FIG. 2 shows a carrier grate 130. This carrier grate 130 transmits loads, for example from different positions, on a rough surface to the opposite feet 125a. Top and bottom plates 140 provide torsional rigidity when the load and bearing are centered. A lifting tongue 10 and a central bar 130 are only purely optional here, for example for maintenance purposes or if the battery formwork is to be operated as a rotary battery formwork. The formwork chambers attached to it are shown in Fig. 3. At the ends of the box are transverse to it Longitudinal formwork axis welded two raised support beams 130, which due to their greater height (see 125 a, b) absorb the ground pressure.

Also shown in FIG. 3 are side plates 107 with an upper support area 110, which in practical embodiments can have a width of 1 to 2 cm, it being pointed out at the same time that the drawings need not be true to scale or true to height. It can also be seen in FIG. 3 that formwork panels of a floor formwork 105 can be provided in the floor area. As indicated by the sketched screws that run through the frame structure, the side plates are arranged in a position-changing manner on the frame structure. It should be noted that here, as is possible with simple applications, the parts 105 are made of wood.

Alternatively, plastic plates, e.g. that of the company MEFA, type ALCUS, can be used.

Although the spacing of the side plates 107 is variable, the support area 110 for the pull-off level of the clearing blade remains 1-2 cm, which facilitates easy cleaning. Are larger contact area widths of e.g. B. up to 8 cm, this slightly affects the cleaning per se, but makes production much easier. However, a web width that is too large reduces the degree of filling of the battery and thus the efficiency. In a practical variant, good results with a width of 3 to 5 cm can be achieved.

To simplify the form of the formwork, the chamber walls also consist, as preferably as possible, of straight sheets or sheets bent only about a parallel axis. Edged Sheets have the advantage of high stability with the acting fresh concrete loads as well as the adhesive forces when stripping. At the same time, they can be manufactured easily and with a high degree of tolerance, which in particular greatly reduces the conversion times of the formwork floors when the height of the concrete parts changes, since there is no need to adapt and measure individual panels. The formwork base 105 is made of wood here, although a base plate can also be made from a straight plate or plastic.

It can be seen in FIG. 3 that in modular formwork forms 100 to the base module 120 of FIG. 2 with differently sized distances 102a from the lower edge to the frame 103, spacing of formwork base plates 105 to the frame 103 caused by spacer sleeves 106 is possible, as are the different widths 108. This also shows how load-bearing plates 107 can be provided between different precast concrete parts so that they transfer the load onto the frame. The chamber walls (FIGS. 4, 110) are guided in floor rails 103 arranged transversely to the longitudinal axis and are therefore laterally displaceable. Fig. 4 also shows length-adjustable pressure stamps. The pressure stamp 111 consists of a load distribution plate a, a sleeve with an internal thread b and a threaded rod c. The change in length is achieved by the thread. A cylinder 112 is against one another in operation. support floor construction 113 rigidly connected to the base module.

In use, a typical construction site preparation or formwork conversion is carried out, which proceeds as follows:

Before starting a ^' construction site and as necessary during production, the side walls on the rails of the Carrier frame laterally shifted so that small series of repetitive solid structures of over 1 m ^{3 part} volume can be produced according to deadlines and needs. The half screws are tightened and preloaded.

Now the floor formwork can be installed. Since the chamber walls 103 consist of folded sheets, tolerances of +/- 1 mm have been achieved practically, particularly in the bottom area (at 105). The formwork panels of the floor formwork 105 could thus be prefabricated and installed without oversize and are spaced apart on a spacer construction 106. Triangular strips seal these small tolerances without concrete running through later.

The pressure stamps adjusted to length are now from above

(Fig. 4 .; 111) for finished parts of different heights so that later the same hydraulic cylinder is suitable for all parts.

The fully prepared battery formwork is now loaded onto a truck, driven to the construction site and the stable basic module (Fig. 2; 120) of the formwork is placed on a leveled surface. Because this base module consists of the torsionally rigid box with cover and base plates 140, the support is. essentially simple, statically indefinite.

In the midst of loads and uneven floors, only the torsional rigidity is used, which prevents the tolerance-sensitive chamber walls from twisting and enables the finished parts to be made to measure. After installation, production can take place on the same day. A typical production cycle now looks like this:

After cleaning the floor and side walls and applying a release agent, the slack reinforcement cages for semi-finished beams are lifted by the all-terrain, self-propelled multifunction device (Fig. 5, b, c). To do this, the portal runs over the formwork batteries (Fig. 5.a.).

The protruding bars protrude from the end of the beams. Recesses are inserted in the baskets and their height is readjusted.

The concrete vehicle approaches the formwork from the side and unloads most of its load. A fraction, for example a few hundred liters, are poured into the storage container of the multifunction device. The concrete vehicle drives off immediately while fine metering takes place from the storage container of the multifunction device. Because of the out standing connection reinforcement for the later blankets on the semi-finished part beams is to use a dozer blade ^'not provided here for concrete distribution. The concrete is now compacted by external vibrators, while a bottle vibrator supports the work.

The formwork is now cleaned of fresh concrete residues. During the cold winter time, an airtight, heavy tent is placed over the formwork and heated. After 30 hours the concrete has a strength of B25, it is stripped. To do this, a hydraulic cylinder is pushed under the pressure ram and extended by a few centimeters with a hand pump. The precast concrete is relieved of the adhesive and clamping forces, especially on the side walls, and can be lifted without the risk of overloading the lifting gear or the anchor.

A pillar-free, "just in time" assembly of the adjacent component ceiling is made possible. However, some of the parts produced are due to workflow reasons on an intermediate storage facility 15 m next to the production battery. Due to the crane stress, parts are lifted by the lifting unit of the multifunction device (Fig. 5.b.), proceed and filed.

A new work cycle begins with the cleaning of the walls of the steel formwork and the plastic floor formwork that come into contact with the concrete.

In summary, the following was disclosed in particular: Especially with very heavy prefabricated parts (ie especially, over 5 to 10 t), only a few parts fit into a formwork which, due to its transportability, has a width restriction of 2.50m to 3m or transports a height restriction vertically. of less than 3 m. Participation in normal road traffic. The great advantage of being able to trade several parts at the same time is lost, so the effort for the process increases with the weight.

At the same time, it was also disclosed, among other things, about the hydraulics under the floor formwork that a load distribution plate between the high cylinder pressures is preferred (typically 10 t - 20 t on 10- 20 cm ² ) and the comparatively damage-sensitive concrete surface. Also particularly preferred is a length compensation, which can be represented by thread-sleeve combinations, which serves to cover different finished part geometries with the same system modules or parts. The fact that a load distribution plate is particularly preferably provided under the hydraulic ram, which transfers the high forces directly back into the upper structure and prevents the entire formwork including prefabricated parts simply lifting off, was also disclosed.

Claims

claims

1. Formwork form with wall and floor areas, characterized in that the floor area comprises a base frame and the walls are displaceable and / or displaceably arranged on the base frame.

2. Formwork form, in particular for the production of precast concrete parts at a construction site while leaving the shape at one point over several cycles according to the preceding claim, characterized in that the base frame is torsionally rigid.

3. Formwork form according to one of the preceding claims, characterized in that a plurality of formwork chambers can be provided on the base frame simultaneously via displaceable walls.

4. Formwork form according to one of the preceding claims, characterized in that the walls and / or the floor are designed for at least 30, preferably at least 50, particularly preferably at least 100 switching cycles.

5. Formwork form 'according to the preceding claim, characterized in that the walls consist of sheet metal, in particular edged and / or black sheet.

6. Formwork form according to one of the preceding claims, characterized in that the underframe and / or the overall arrangement can be transported by road, in particular can be transported by road without a permit.

7. Formwork form according to one of the preceding claims, characterized in that a plurality of subframes can be coupled, so as to define a continuous battery formwork.

8. Formwork form according to one of the preceding claims, characterized in that several, in particular laterally displaceable chambers are provided, which in particular have narrow webs above and / or in particular with height-adjustable floors and / or insert boxes, are provided releasably on a base module.

9. Formwork form according to one of the preceding claims, characterized in that at least one insert is provided with releasable connecting means between the base or base module and components of the chambers and / or between the components of the chambers themselves.

10. Form of form according to the preceding claim, characterized in that the connecting means is selected from clamps, bolts, screws, wedges, claws.

11. Scarf form according to one of the preceding claims, characterized in that a joint seal is provided between chamber components, which is preferably elastic, in particular formed by rubber, and / or by triangular strips.

12. Battery formwork arrangement in particular according to one of the preceding claims with at least one formwork chamber and an actuator for precast concrete removal Support at one place, characterized in that the actuator is designed as an actuator acting upwards to overcome the adhesive force and the formwork chamber is designed for formwork removal upwards.

13. Battery formwork arrangement according to the preceding claim, characterized in that it is designed for production in the manufacturing cycle non-rotatably installable individual parts.

14. Battery formwork arrangement according to one of the preceding claim, characterized in that a plurality of formwork chambers, preferably over 4, is provided.

15. Battery formwork arrangement according to one of the preceding claim, characterized in that at least two formwork chambers are provided for the same and / or similar components.

16. Battery formwork arrangement according to one of the preceding claim, characterized in that the formwork chambers are formed with a variable geometry.

17. Battery formwork arrangement according to one of the preceding claims, characterized in that the formwork chamber is formed with displaceable side and / or wall elements.

18. Battery formwork arrangement according to one of the preceding claims, characterized in that the formwork chamber has a width of at least 40, preferably of at least 50cm at a widest point.

19. Battery formwork arrangement according to one of the preceding claim, characterized in that a volume of greater than 0.5 m ³ , preferably at least 1 m ^{3 is} provided.

20. Battery circuit arrangement according to one of the preceding claim, characterized in that a hydraulic actuator is provided.

21. Battery circuit arrangement according to one of the preceding claim, characterized in that a pressure distribution plate is provided between the actuator and the prefabricated middle concrete part in order to equalize the pressure of several actuators on a prefabricated concrete part and / or to distribute the pressure from an actuator more uniformly to one or more concrete parts.

22. Battery formwork arrangement according to one of the preceding claims, characterized in that a tensile-resistant substructure is provided, by means of which the actuator is arranged on a battery formwork base in particular in a height-adjustable manner.

23. Battery circuit arrangement according to one of the preceding claims, characterized in that the actuator arrangement. is adjustable in height.