Classifications

• • E—FIXED CONSTRUCTIONS
  • E04—BUILDING
  • E04G—SCAFFOLDING; FORMS; SHUTTERING; BUILDING IMPLEMENTS OR AIDS, OR THEIR USE; HANDLING BUILDING MATERIALS ON THE SITE; REPAIRING, BREAKING-UP OR OTHER WORK ON EXISTING BUILDINGS
  • E04G9/00—Forming or shuttering elements for general use
  • E04G9/02—Forming boards or similar elements
  • E04G9/05—Forming boards or similar elements the form surface being of plastics
• • E—FIXED CONSTRUCTIONS
  • E04—BUILDING
  • E04G—SCAFFOLDING; FORMS; SHUTTERING; BUILDING IMPLEMENTS OR AIDS, OR THEIR USE; HANDLING BUILDING MATERIALS ON THE SITE; REPAIRING, BREAKING-UP OR OTHER WORK ON EXISTING BUILDINGS
  • E04G1/00—Scaffolds primarily resting on the ground
  • E04G1/15—Scaffolds primarily resting on the ground essentially comprising special means for supporting or forming platforms; Platforms
  • E04G1/153—Platforms made of plastics, with or without reinforcement

Definitions

• the invention relates to a component according to the preamble of claim 1 and a method for producing a component according to the preamble of claim 62.
• a formwork skin made of a multilayer wood panel and a profile frame which is formed from steel or aluminum.
• the profile frame formed from aluminum is preferably used for a lightweight construction.
• a lightweight construction such as that provided by an aluminum profile frame, ensures that fast work is possible even without a crane.
• areas of application such as residential construction, smaller conversion measures and all areas in which switching without a crane or outside the crane reach are preferred.
• the formwork panels must be nailed and / or screwed to connect them to the profile frame.
• the wood can be mechanically damaged by splintering when nailed. In the event of damage, improper handling can result in splintering of such wooden formwork panels on the construction site.
• the material is affected by weathering and water absorption.
• a silicone seal is also required to accommodate the formwork panels in the formwork frame or profile frame, so that the changes in length due to moisture absorption are compensated for by the elastic joint.
• the film is scraped off by mechanical cleaning with a thickness of up to 440 g per square meter, so that an increased use of release agents is required. The resulting groundwater pollution is considerable.
• components in particular scaffolding coverings, have become known which are used in work scaffolding. These have a work surface that is made of wood. These work surfaces have at least on the narrow sides two hook elements with which the scaffolding coverings are mounted on the scaffolding.
• the wooden worktop also has the disadvantages mentioned above.
• thermoplastic waste which should not be disposed of in landfills, but should be further used in the sense of the recycling economy law.
• the price of new plastic is also getting lower and a supply seems to be secured for several decades, since the recyclability of the thermoplastic is also guaranteed.
• the invention is therefore based on the object of specifying a component which makes it possible at least to conserve wood resources and to use plastics which are themselves recycled or at least recyclable and enable a further reduction in the weight of a component and yet which correspond to the uses Can take loads and largely corresponds to the previous design. Furthermore, the invention is based on the object of providing a method for producing a component which allows the component according to the invention to be produced quickly and inexpensively.
• the configuration of a component as a molded casting according to the invention has the advantage that a shorter working time is required for its production, which means that high wage and ancillary wage costs can be saved.
• this configuration in particular for a component for wall and ceiling formwork and scaffolding coverings, has the advantage that, compared to the previously known aluminum or steel profile frames, galvanic pretreatment can be omitted. Likewise, the complex coating of such profile frames for use on the construction site can be omitted.
• the component also has the advantage that the working surface or formwork plate can be designed to be splinter-free and impact-resistant due to the use of a polymer material. This means that the load-bearing capacity can be maintained.
• the use of polymer materials for the element furthermore means that a long service life can be given.
• the polymer materials are more weather-resistant and easier to clean than wood or a multi-layer wood panel.
• the formwork sheet can be cleaned quickly and easily with a steam jet cleaner. This is relatively thin and has almost no thermal inertia. This leads to the fact that, for example when spraying the formwork panel with a steam jet cleaner, differences in length expansion occur between the concrete layer and the plastic, so that the concrete layer jumps off the formwork panel and the connection is immediately released.
• the use of suitable polymer materials for the component leads to a lower adhesion of cement paste and thus the use of release agents can be dispensed with.
• such a component designed as an injection molded part has the advantage that it has one over the previously known components, consisting of a metal profile frame and a multilayer sheet made of high-quality plywood T further weight reduction by 10 to 20% can be achieved with the same dimensions. This allows even more manageable work and thus quick work.
• This weight reduction advantageously has no loss in a concrete pressure or load to be absorbed, so that, just as in the known construction of the components with a metal profile frame, for example in the case of formwork elements, a concrete pressure of up to 60 kN / m 2 can be absorbed.
• the profile frame is formed by frame legs, which consist of at least partially molded plastic carrier profiles. It can thereby be achieved that several elements for wall formwork can be securely connected to one another. Furthermore, these support profiles can increase the rigidity of the elements, so that the element is designed to be torsionally rigid and robust for use on construction sites.
• the free ends of the profile frames are made less impact-sensitive than an impact-resistant polymer material by the carrier profiles.
• these beam profiles have the advantage that they can be hung on a drop head or column head as well as main and / or secondary beams when used for slab formwork.
• These support profiles which are advantageously formed from an aluminum alloy, have the further advantage that the element is insensitive to creep.
• the polymer materials generally have a very high creep index and can hardly reduce creep stresses.
• Metals and synthetic resins have a very low creep index, so that even after a prolonged and high load due to the preferred reinforcement provided by the carrier profiles, creep can almost be prevented. So are high-performance elements that have almost no distortion - even after a long period of use.
• the design of a profile frame with a support profile has the advantage that such formwork elements can be completely recyclable. Elements can be recycled in which a repair that no longer seems worthwhile due to the use of a thermoplastic polymer material can be recycled.
• the carrier profiles are operated as electrical resistance, which causes them to heat up considerably and the plastic can be detached from the carrier profiles. Through this separation process, approximately 90% of the proportions of the carrier profile can be removed from the plastic. The plastic and also the portions of the carrier profile which are only partially contained therein can then be shredded and ground, so that after processing this waste, it can be reused for an element or further metal-plastic components for use in the construction industry, for example for formwork panels in slab formwork.
• the carrier profiles extend along side surfaces of the profile frame and can be connected to one another with at least one connecting element such as, for example, a corner connecting element to form a carrier professional frame.
• the carrier profiles can be pre-fixed to one another and arranged securely in an injection molding tool, so that a shift in position within the tool can be avoided due to the high injection pressures.
• this corner connection can achieve that the rigidity of the profile frame can be increased, which in turn increases the connection rigidity and also the absorption of the concrete pressure.
• transverse webs are regularly spaced apart over the length, which can also be pre-fixed to the carrier profiles by, for example, a clamp.
• central webs can be provided in addition to the carrier profiles arranged in the longitudinal sides, which can also be pre-fixed, for example, by clipping to the carrier profiles arranged on the end faces.
• the frame leg comprises a partially overmolded carrier profile which, on the inside, has a free contact surface arranged at an angle to the vertical axis of the frame leg in the central section of the frame leg and a further, at the free end of the frame leg not overmolded, inner contact surface and a non-overmolded foot extending along the vertical axis.
• the remaining sections of the support profile are essentially extrusion-coated.
• These non-overmolded contact surfaces serve to arrange a switch lock in order to connect one or more elements to one another.
• a claw of the formwork lock can engage on the contact surface arranged at an angle to the vertical axis of the frame leg.
• the further inward-facing contact surface at the end of the frame leg can serve to apply a projection in the root region of the claws.
• the foot which extends freely along the vertical axis of the frame leg, enables the formwork lock to be braced towards the first contact surface, so that alignment of the two elements is made possible.
• This configuration of the non-encircled contact surfaces advantageously enables a 5-point contact of the formwork lock, as a result of which the concrete pressure can be absorbed up to 60 kN / m 2 . At least one 3-point system is ensured so that the elements can be aligned and aligned.
• a support profile is provided for the formation of a profile frame of an element for wall and ceiling formwork, which stiffens the profile frame and, by means of a lower L-shaped base, enables secure reception on main and secondary supports, drop heads or support heads an insensitive closure by the lower foot.
• the carrier profile has the advantage that an end section is provided on the upper vertical section of the foot, which can be designed such that this end section forms a tight seal in an injection molding tool, so that the 1 adjoining upper part of the carrier profile can be at least partially extrusion-coated.
• a claw is connected to the end section in the upper section of the carrier profile.
• the element has a pretension that largely neutralizes itself under the intended load. This leaves enough reserves for the elements to have the required safety and strength in limit loads.
• the carrier profiles are plastic and / or elastically pre-deformed in the mold during the extrusion coating.
• the carrier profiles are plastically deformed, preferably in the direction of the vertical axis, and then inserted individually or as a frame into the tool.
• the carrier profile or the frame composed thereby can also be positioned undeformed in the tool and are deformed via a tool control before and / or during the spraying process.
• an element can be formed which has a surface center point of the formwork panel which is at least partially raised relative to the edge zones.
• other dome-shaped or curved designs of the formwork panel can also be provided in accordance with the specific applications.
• the advantageous embodiments also apply, for example, to a scaffolding covering, a work platform, to which brackets can be attached, or to other components that build on or link to the component according to the invention.
• the method according to the invention for the production of an element for wall and ceiling formwork has the advantage that an expensive pretreatment and subsequent coating of the profile frame can be saved. Furthermore, the manufacture of the element in one injection molding operation can save a considerable number of work steps, such as, for example, B. the application of a silicone seal in the formwork frame to accommodate a multilayer board. This can result in considerable cost savings. At the same time, the production rate can be increased significantly by manufacturing the element as an injection molded part.
• a prefabricated formwork panel which preferably has a sandwich structure with stiffeners, is inserted into the injection mold.
• the injection molding process can be shortened, and at the same time, by re-spotting the inserted parts, such as, for example, a formwork panel and a support profile frame, a firm connection to a one-piece element is made possible
• FIG. 2 shows a schematic sectional illustration along the line II-II in FIG. 1 with a schematic sectional illustration of a carrier profile
• Fig. 3 is a schematic partial section along the line III-III in Fig. 1 with a schematic partial section of a crossbar and
• FIG. 4 shows a section along the line IV-IV in FIG. 3 of a crossbar
• FIG. 6 shows a side view of a component designed as a scaffold covering
• FIG. 7 is a bottom view of the component of FIG. 6,
• FIG. 9 shows a schematically enlarged detailed view of a fastening element designed as a safety catch.
• the formwork element 12 has a formwork height of 160 cm and a width of 80 cm.
• the formwork elements 13 are designed as a small version with a formwork height of 160 cm and a width of 40 cm.
• the formwork element 12 has a profile frame 14 which runs around the outside and has a vertical central web 16 In the fields between the vertical frame legs of the profile frame 14 and the central web 16, horizontal transverse webs 17 extend at a uniform distance. In the fields enclosed between the central web 16 and the transverse webs 17, a vents 18 are provided, which is formed by two ribs lying in the diagonal of the fields. Further configurations which enable the fields to be stiffened are also conceivable. For example, the height of the ribbing can decrease from the center of the surface of the formwork plate 22 towards the outside.
• the mutually adjacent vertical frame legs of the profile frame 14 of the formwork elements 12, 13 are connected with formlocks 19, four of which are used here, for example.
• the formwork element 13 has a profile frame 14 which runs around the outside. Cross webs 17 are formed between the vertical frame legs of the profile frame 14 and are arranged at regular intervals from one another. A ribbing 18 is also provided between the transverse webs 17, which is designed analogously to the formwork element 12.
• the profile frames 14 of the formwork elements 12, 13 have an analog structure made of the same material with the same cross section.
• the sound element 12 is connected to the formwork element 13 by formwork locks 19. These engage the frame legs of the profile frame 14 and fix the two profile frames 14 adjoining one another. Analogously, the two formwork elements 13 are fixed to one another, so that a shell element wall can be formed by such an arrangement, wherein the formwork elements 12, 13 can be arranged horizontally and / or vertically to one another.
• anchor pockets 21 for the tension rods of formwork anchors are provided between a frame leg of the profile frame 13 and a ribbing 18. These are advantageously arranged in relation to the fields of the formwork element 12 so that they are arranged symmetrically to the longitudinal and transverse axes of the formwork element 12, so that consideration of the orientation of the formwork panel 12 is not necessary. This also applies to the switchboards 13.
• FIG. 2 shows a schematic partial cross section along the line II-II in FIG. 1.
• the formwork panel 12 is shown as an injection molded part and has a frame leg 23 of the profile frame 14, which is formed from a partially extrusion-coated carrier profile 27.
• the frame leg 23 is arranged substantially perpendicular to the formwork panel 22.
• the ribs 18 are arranged on a front side 24 of the formwork plate 22, against which concrete rests during concreting, in order to enable the formwork plate 22 to be made rigid.
• the ribs 18 run diagonally to the left into a corner region 26.
• the frame leg 23 has a system plane 28 along a cross-sectional area of the carrier profile 27.
• the carrier profile 27 has a lower section 29 which is not extrusion-coated with plastic and an upper section 31 which is extrusion-coated with plastic.
• the lower section 29 is formed by an L-shaped foot 32, the horizontal section 33 of which points towards the center of the formwork element 12.
• This L-shaped foot 32 is used for the secure arrangement and support of the formwork element 12 to the main and secondary beams of a scaffold for slab formwork.
• the lower contact surface 34 serves to align the formwork element 12 with a further formwork element 12 or 13 with a formwork lock 19.
• a vertical section 36 of the foot 32 is delimited by an end section 37. The end section 37 separates the lower, non-overmolded section 29 from the upper overmolded section 31.
• This end section 37 also serves to close the injection molding tool from the foot 32 protruding from the injection molding tool.
• the end section has a right arm 38, which is L-shaped. Opposite this, a left projection 39 is provided, the height of which essentially corresponds to the wall thickness with which the carrier profile 27 is essentially extrusion-coated to the outside.
• a wall thickness which is substantially less than that on the outside is provided on the inside of the carrier profile 27, a wall thickness which is substantially less than that on the outside is provided.
• the inner thickness of a plastic layer can be, for example, 1 to 2 mm.
• the end section 37 is followed at a distance by an upper and lower guide groove 41, 42 which are U-shaped and arranged toward one another.
• This guide groove 41, 42 pointing towards the center of the formwork element 12 serves to receive a corner connection element 43 in order to fix two support profiles 27 arranged at right angles to one another.
• the corner connection element 43 can be designed as an isosceles angle, the free ends of which in the guide grooves 41, 42 can be inserted.
• the carrier profiles 27 can be arranged relative to one another to form a carrier profile frame 46 which, after at least partial extrusion molding, forms the profile frame 14.
• connection of the support profiles 27 over a corner should have a certain rigidity, but on the other hand it should also be possible for the support profile frame 46 formed thereby to be designed to be flexible to the extent that when the support profile frame 46 is inserted into an injection molding tool, it is still slightly aligned and Arrangement is possible.
• the corner connection element 43 can be connected to the guide grooves 41, 42 by means of a clamp connection, RasW snap connection or the like.
• the guide grooves 41, 42 are extrusion-coated with plastic and serve as a claw with the plastic. This can give a better connection between the plastic and the carrier profile 27.
• An offset 47 is provided between the guide grooves 41, 42, which is provided to stiffen the support profile 27.
• the carrier profile 27 has an essentially constant cross section from the end section 37 to the end region 49. The wall thickness is approximately 1.5 mm.
• several bores (not shown) are provided in the longitudinal axis of the carrier profile 27. The plastic can reach the inside from the outside of the frame leg 23 via the bore and completely surround the surface between the guide grooves 41, 42.
• the lower web 51 is larger than the upper web 51.
• the webs 51 are preferably arranged at an angle of approximately 100 ° to one another.
• the lower web 51 is provided, for example, at an angle of approximately 25 to 45 ° to the system plane 28.
• the upper and lower web surfaces 51 are functional surfaces and also an outer contact surface 53 of the right arm 38 from the end section 37. These functional surfaces are not covered with plastic.
• the scarf lock 19 engages these surfaces 51, 53 and 34.
• This configuration allows a 5-point support, with a claw of the formwork lock 19 resting at least on the lower web surface 51 and with a projection in the root area of the claw resting on the contact surface 53 and at the same time for aligning the front side 24 of the formlining 22 from enables two formwork panels arranged to each other through the contact surface 34. It also follows that the end sections 52 and contact surface 53, which run in a plane parallel to the system plane 28, are provided. Polymer material is filled between the wall section of the carrier profile 27 running in the system plane 28 and the upper and lower web 51. This serves to support and stiffen the upper and lower webs 51 which are each arranged in a V-shape relative to the wall section. For the lower web 51, the guide groove 52 additionally serves as reinforcement or stiffening.
• a web 54 arranged essentially at right angles to the system level 28, opposite and outwards.
• the web 54 is formed with interruptions when viewed in the longitudinal direction.
• An end face 56 of the web 54 rests in a tool wall.
• a further offset 57 is provided between the webs 51 arranged in a V-shape and an end region 49, which in turn is arranged for stiffening.
• the end region 49 has two opposing profile webs 58, 59 which are arranged essentially perpendicular to the system plane 28.
• the left profile web 58 forms a stiffening of an edge 61, which is formed between the frame leg 23 and the front 24 of the formwork panel 22.
• An end face 62 of the professional web 58 directly adjoins a contact face 63 of the projection 64.
• the height of the projection 64 corresponds to the height of a projection 66 seen from the system plane 28, the latter being arranged opposite the guide groove 41.
• the carrier profile 27 is designed as an extrusion profile and preferably consists of aluminum or an aluminum alloy, such as AlMgiSI 0.5 or titanium or titanium alloy. Furthermore, other light metals as well as metals can be used. High-strength plastics or fiber-reinforced plastics, such as, for example, carbon-kevlar-reinforced plastic, are also possible for forming carrier profiles.
• the wall thickness of the support profile 27 can be increased.
• the carrier profile 27 is formed as a hollow profile body with one or more chambers, which in turn allows a higher stiffness or torsional stiffness of a formwork element 12 to be achieved.
• the carrier profiles 27 can be preformed, preferably plastically preformed.
• FIG. 3 shows a schematic partial section along the line III-III according to FIG. 1.
• the partial section shows the arrangement of the crossbar 17 to the support profile 27 and its configuration.
• the crosspiece 17 has a T-profile 67 which terminates at a lower end with a crosspiece 68.
• the crossbar 17 is completely embedded in the plastic.
• This T-profile 67 is also designed as an extruded profile made of aluminum or an aluminum alloy.
• a projection 71 is formed which is tapered in relation to the width of the T-profile 67 and has two tabs 72 and 73 at its free end which engage in a bore 74 in the support profile 27.
• the bore 74 is provided in the area of the crank 47.
• the tabs 72, 73 are bent in the opposite direction (FIG. 5), as a result of which the crossbar 17 is fixed in its position in relation to the carrier profile 22.
• the crosspiece 17 extends from the formwork plate 22 to below the crosspiece 68 of the T-profile 67.
• a plurality of bores 76 are provided, so that a plastic wall formed between a left and right to the T-profile 67 IT
• the bores 76 are provided in a V-shape offset from one another at regular intervals.
• two fingers 77 are provided at regular intervals on an upper edge region of the T-shaped profile and are deflected in the opposite direction from the longitudinal plane of the T-profile 67. This can create a spacing for the T-profile 67 in the tool. Alternatively, this can be done by placing a plastic clip or the like on a finger 77 of the T-profile 67.
• both the tab-shaped connection between the cross bar 17 and the carrier profile 27 and the cross bar 17 are completely covered.
• further simple and quickly mountable connections can be provided between the crosspiece 17 and the carrier profile 27.
• the transverse webs 17 can furthermore have an opening which is designed as a hand opening. Alternatively, it can also be provided that a handle can be arranged in this opening, so that the formwork elements 12, 13 can be handled easily.
• FIG. 6 shows a side view of a component designed as a frame 80.
• the scaffold 80 has a profile frame 14 which supports the work surface 22 and is arranged perpendicular to the work surface 22.
• the profile frame 14 forms frame legs 23 which surround the work surface 22.
• the function and structure of the scaffolding covering 80, as shown in FIGS. 6 to 9, corresponds to the formwork elements 12, 13.
• fastening elements 83, 84 are attached to narrow end faces 81, 82 in order to fasten the Gerustbeiag 80 to a scaffold, preferably a frame scaffold.
• a scaffold preferably a frame scaffold.
• Such scaffolds are used in particular for plastering, painting or the like.
• the fastening elements 83 are designed as hooks, as shown in the schematically enlarged side view according to FIG. 8.
• the hooking element 83 is fastened to the carrier profile 27, for example by means of a welded connection, clamp connection, adhesive connection or the like can be inserted into a horizontal tube (not shown) at the top
• the carrier profiles 27 are advantageously designed as hollow chamber profiles. This can also be provided for the formwork elements 12, 13. In the case of the configuration as a hollow chamber profile, the extrusion coating can take place analogously to the configuration according to the support profiles 27 of the formwork elements 12, 13.
• the fastening element 84 is preferably designed as an anti-lifting device, as is shown enlarged in FIG. 9. This can enable increased safety during construction.
• the lifting safety device 84 is first placed on horizontal tubes of the scaffolding, in order to then lower the scaffolding covering 80 into the horizontal plane, the fastening elements 83 also engaging on a horizontal tube of the scaffolding.
• the lead-in chamfer 86 can preferably be used.
• 80 hooking elements are also provided as fastening element 83 on both end faces 81, 82 of the scaffold lining.
• horizontal crossbars 17 are provided, which are optionally introduced through a T-profile or other type of profile.
• the carrier profiles 27 have inclined surfaces 51 on their outside. This can make it possible for a connection of the scaffolding coverings 80 to be created by means of scarf locks in the case of a plurality of scaffold coverings 80 arranged parallel to one another, so that a closed work surface 22, which can serve as a running surface or parting surface, is formed.
• the component in which the working surface 22 and the profile frame 14 are integrally formed as an injection molded part is used as a work platform.
• the profile frame 14 can, for example, be modified in such a way that receptacles are attached which make it possible to attach consoles.
• further fastening possibilities can be provided on the profile frame 14 in order to attach a railing, preferably foldable, to it.
• the component according to the invention thus offers a basic concept for a large number of embodiments which can not only be used in construction operations.
• the component according to the invention is produced by the method described below.
• the carrier profiles 27 are cut to the appropriate dimension in terms of length and width.
• the carrier profiles 27 are assembled to form a carrier profile frame 46 via corner connecting elements 43.
• corner connecting elements 43 At the same time, depending on the size, cross and center webs 16, 17 are attached between the carrier profiles 27.
• the carrier profile frame 47 thus represents a relatively rigid frame, which is, however, designed to be slightly flexible in itself.
• This support profile frame 46 is inserted into a multi-part injection molding tool formed with a plurality of slides. The injection molding tool is then closed, the end section 37 being arranged in such a way that it forms a termination to the injection molding tool.
• thermoplastic is introduced into the injection molding tool under high pressure of, for example, 300 to 500 bar via one or more injection points, which are preferably provided at intersections of the ribs 18 or the central and transverse webs 16, 17.
• the spraying time for a formwork element 13 from 160 cm to 40 cm is approximately 6 to 8 seconds. After a slight holding pressure phase and foaming of the plastic and a certain cooling time, the finished formwork element 12 can be removed from the injection mold.
• the carrier profile 27 is or is advantageously coated with an adhesion promoter before the thermoplastic is introduced, so that full-area adhesion of the plastic to the carrier profile 27 is made possible.
• polypropylene is preferably used, which is preferably filled with a glass fiber content of 5 to 40% and is additionally provided with a blowing agent which preferably causes foaming to occur between 5 and 30%.
• additives such as for UV resistance, for lower water absorption, for good concrete repellency or the like can be added or applied as a top layer.
• polyamide or other thermoplastics can be used which have high rigidity and low water absorption. The plastic is advantageously colored light white to eggshell-colored, so that the formwork element 12, 13 does not absorb any heat when exposed to the sun.
• the formwork plate 22 has stiffeners for reinforcement, for example by a continuous or at least partially connected metal or Light metal insert can also be given by a woven, knitted or knitted fabric.
• stiffeners for reinforcement for example by a continuous or at least partially connected metal or Light metal insert can also be given by a woven, knitted or knitted fabric.
• a formwork panel with a sandwich structure which has two metal inserts for stiffening it, is inserted into the injection molding tool and by subsequent overmolding to form a formwork element 12 , 13 is connected to one another.
• a lamination is inserted into the tool, so that the formwork element 12, 13 can be recognized by the lamination provided on the formwork plate 22.
• the formwork panel 22 or the front side 24 can thus simultaneously serve as an advertising space.
• the central web 16 can be designed analogously to the cross section 17. Likewise, an analogous attachment can be provided at the crossing points thereof.
• the structure and design of the elements 12, 13 described above is not only limited to formwork elements, but can also be used for all other support systems in which the creeping of the plastic is a considerable hindrance caused by metallic reinforcements or plastic reinforcements, as in the case of ⁇ can be compensated for example by the carrier profiles.
• Such support systems can be, for example, doors, cassettes, roof covers, molded parts in vehicle construction, roof panels as well as emergency accommodation.

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• Engineering & Computer Science (AREA)
• Architecture (AREA)
• Mechanical Engineering (AREA)
• Civil Engineering (AREA)
• Structural Engineering (AREA)
• Forms Removed On Construction Sites Or Auxiliary Members Thereof (AREA)
• Blow-Moulding Or Thermoforming Of Plastics Or The Like (AREA)
• Forging (AREA)
• Bending Of Plates, Rods, And Pipes (AREA)
• Finishing Walls (AREA)

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• 1997
  • 1997-06-20 AT AT97929237T patent/ATE188006T1/de not_active IP Right Cessation
  • 1997-06-20 WO PCT/EP1997/003240 patent/WO1997049881A1/fr active IP Right Grant
  • 1997-06-20 EP EP97929237A patent/EP0906482B1/fr not_active Expired - Lifetime
  • 1997-06-20 BR BR9710015-3A patent/BR9710015A/pt not_active IP Right Cessation
  • 1997-06-20 US US09/214,129 patent/US6148575A/en not_active Expired - Fee Related
  • 1997-06-20 AU AU33419/97A patent/AU3341997A/en not_active Abandoned

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