DE102016012948A1 - Prefabricated, multifunctional ceiling - Google Patents

Abstract

The invention relates to a prefabricated, large-area component with multiple uses, preferably made of concrete, which is produced as a false ceiling over at least one spacing, which in turn is made of known materials (eg insulating material, also for thermal separation) as permanent formwork of the above effective, preferably made of in-situ concrete ceiling construction, to its curing serves. In this case, the component for a first use (lost formwork) is constructed and reinforced so that it has sufficient own capacity to the structural members of the above arranged, preferably made of in-situ concrete, ceiling to achieve their own stability and take on any, the to anticipated load adapted to derive temporary sporadic substructure in the subsurface.

Description

Thermally activated concrete ceilings have been known for many decades. Following the fact that energy was cheap, but the system technology was expensive, systems were developed which primarily relieve the system engineering. Accordingly, an attempt was made to activate the largest possible concrete mass. As a result, the pipes were placed in the middle of the concrete core.

In later years, the situation had reversed, trying to increase the performance of the systems. Also at the expense of plant technology, whose production costs had meanwhile dropped significantly. Consequently, from about the 1995s, the pipes were successively relocated from the concrete core to the surface of the ceiling.

Thus, the performance and reaction time in the cooling / heating case could be significantly increased. However, it continues to be at the expense of the indoor climate. However, the previously known ceiling systems were still all sluggish in the decay and switching behavior (heating / cooling).

By the beginning of the 2000s at the latest, another trend is starting. The labor force situation and constraints of the efficiency increase owed the satisfaction of the users became more and more important. Consequently, fast-reacting suspended heating / cooling ceiling systems continued to gain in importance. Also in the knowledge that the situation of the plant engineering, strengthened by the now missing direct exchange of heat radiation between the building mass and the space, further intensifies. In addition, massive Klimadeckensysteme have been developed which are also able to limit the reaction time and to avoid the disadvantage of reduced exchange of heat radiation.

From at least the 2010s, the acoustic requirements, not least pushed by suspended drywall systems, became more important. A change in the usage situation and the increasing need for flexibility also ensured that suspended drywall systems, primarily manufactured as plasterboard ceilings, began to crowd out the massive ceiling systems. Developments which make it possible to provide responsive, acoustically effective solid ceilings to the market remained despite good storage capacity and low investment costs, due to high complexity in the prefabrication and lack of revisability limited regionally The increasing demands on the flexibility and revisionability lead today to the fact that metal Cassette ceilings, despite high costs and high equipment costs, increasingly replace the plasterboard systems in office buildings. So this market in D / A / CH today is divided as follows: system reaction time flexibility plant expenditure 50% metal ceilings nimbly high very high 25% GK blankets nimbly medium very high 25% BTA (Surface) medium to lazy low low (Core) very low low

All suspended systems currently available on the market are to be regarded as solutions that are created in the on-site assembly. The quality is dependent on locally available and increasingly scarce professionals. Especially in the expansion of the landscape is characterized by subcontractors and semi-skilled employees.

Design and use of suspended ceilings, especially gypsum-containing panels are not new in principle. Also, suspended ceilings made of other materials such as cement boards, metal, wood or wood materials, etc. are known. All, however, have in common that they are installed in the course of the expansion of the building. For this purpose, time windows have to be planned for the assembly, which requires more on-site coordination and ultimately extends the construction time. Also, these systems play no role in the technical implementation of the shell, especially when concreting the ceilings.

Also known are filigree suspended ceilings which, statically effective (finitely calculated cross reinforcement) serve as lost formwork. Today, these filigree suspended ceilings, in addition to their original function, combined with other techniques. In the meantime, pipe systems for various installations are being inserted as well as elements for sound absorption. In addition, attempts are made by grooves and again more conduits to achieve a certain reversibility. The success of these measures is, compared to the installation freedom of suspended ceilings and their reversibility at most modest.

To date, the market is not offered a finished part which, over a large area and pre-produced in the factory, provides a consistently high precision. However, the advantages of suspended ceilings and a rational, inexpensive construction site operation agreed.

Task:

The aim of the development presented here is to provide the market with a system that combines today's requirements for prefabrication, rational production, precision planning and production with optimum flexibility.

At the same time meet today's requirements for room comfort (tempering / acoustics, sound insulation) and meet the current and future requirements which are placed on an energy-optimized system in terms of equipment costs. At the same time, the system should be made available to the market in a production-friendly manner and therefore in sufficient quantity.

For this purpose, the system is to be created on the basis of the concrete ceiling known as "filigree corner", as a "filigree suspended concrete ceiling". In contrast to the already known and available in good quantity Filigrandecken systems, the newly found system in its preferred embodiment, however, is not structurally effective in terms of a flat sub-reinforcement of the known "Filigrandecken".

In this case, the component shown according to the invention continues to take on the function of a "lost formwork" for the concrete ceiling to create about it.

The newly found component can, in a preferred embodiment, spaced by cavity and / or insulation material (currently for cost, production, and capacity reasons, preferably in concrete), however, factory-made, attached as a large filigree ceiling, suspended. Thus, it is inventively succeeded for the first time to present a "lost" concrete formwork as a prefabricated Unterhangdecke the market. The overlying concrete pavement is formed essentially and preferably as a classic, steel-saving "Ortbetondecke".

• - Filigranes Betonelement welches gleichermaßen als verlorene Schalung und als Unterdecke dient.
• - Einbau diverser, z.B. gebäudetechnischer Installationen, z.B. Heiz-/Kühlleitungen, ohne Beeinträchtigung der Deckenstatik IN den Spiegel der Unterdecke.
• - Kostenreduktion und (thermische / akustische) Leistungssteigerung in dem von der Statik befreiten Unterdeckenspiegel welcher zudem eine freie Planung und Konstruktion von Rohrmäander und, auch akustisch wirksamer Einbauteile ermöglicht.
• - Durch das Entfallen statischer Aufgaben der Unterdecke kann diese insbesondre bei Verwendung entsprechender Bewehrungssysteme, „schlanker“ gebaut werden.
• - Dadurch niedrigere Betriebskosten im Heiz-/Kühlbetrieb durch kürzer Reaktionszeiten, höherer Leistung und günstigerer dynamischer Werte.
• - Schaffung einer Ebene welche, von der Decke aus gesehen, nach unten einen Hohlraum begrenzt der als Installationsebene, und/oder Lüftungsebene usw. dienen kann.
• - Durch den Einbau etwaiger Rohrsysteme IM Spiegel der Unterdecke, anstatt wie den bekannten abgehängten Trockenbausystemen, AUF dem Spiegel der Unterdecke werden die eingebauten Elemente (Rohre usw.) im Brandfall, geschützt durch den Beton des Spiegels der Unterdecke, keiner direkten Beflammung ausgesetzt. Somit ist der Spiegel der Unterdecke zugleich Schutz vor direkter Beflammung. Eine zusätzliche Dämmauflage für die Funktion „Brandschutz im Hohlraum“ nicht weiter erforderlich.
• - Der Einbau von Schallabsorptionskörpern, führt zu keiner Beeinträchtigung des Brandschutzes
• - Die von Speichermasse und flinker thermischer Ebene kann weiter optimiert und/oder ohne Dämmstoffe ausgeführt werden.
• - Verbesserter Brand-und Schallschutz bei raumübergreifenden Decken-Hohlräumen einer Etage. Insbesondere bei zusätzlichem, erfindungsgemäßem Einbau von Löschsystemen.
• - Verringerter Aufwand für bauseitige Spachtelung bei Verwendung großflächigen Bauelementen.
• - Verkürzung des gesamten Baustellenbetriebes durch präzise, werkseitige Vorfertigung
• - Qualitativ hochwertige Bauweise. Unabhängig von Baustelleneinflüssen hinsichtlich Fachkräftemangel und Wettereinflüssen
• - Entlastung der Baustellenlogistik

The separation of statically effective ceiling level and lower ceiling, here preferably made of concrete, offers the following advantages:

• - Filigree concrete element which serves equally as a lost formwork and as a false ceiling.
• - Installation of various, eg building technical installations, eg heating / cooling pipes, without affecting the ceiling statics IN the mirror of the lower ceiling.
• - Cost reduction and (thermal / acoustic) performance increase in the statics liberated underlayment mirror which also allows a free planning and design of Rohrmäander and, even acoustically effective components.
• - By eliminating static tasks of the sub-ceiling, these can be built in particular with the use of appropriate reinforcement systems, "slimmer".
• - Lower operating costs in heating / cooling operation due to shorter reaction times, higher performance and more favorable dynamic values.
• - Creation of a level which, viewed from the ceiling, down a cavity bounded as the installation level, and / or ventilation level, etc. can serve.
• - By installing any pipe systems IN the mirror of the false ceiling, rather than the known suspended drywall systems, on the mirror ceiling, the built-in elements (pipes, etc.) in the event of fire, protected by the concrete of the mirror ceiling, exposed to no direct flame. Thus, the mirror of the false ceiling is at the same time protection against direct flame. An additional insulation layer for the function "fire protection in the cavity" is no longer required.
• - The installation of sound absorption bodies, does not affect the fire protection
• - The storage mass and nimble thermal level can be further optimized and / or executed without insulation materials.
• - Improved fire and sound insulation for ceiling-to-ceiling cavities of one floor. Especially with additional, inventive installation of extinguishing systems.
• - Reduced effort for on-site filling when using large-scale components.
• - Reduction of the entire construction site operation through precise, factory-made prefabrication
• - High quality construction. Independent of construction site influences regarding shortage of skilled workers and weather influences
• - Relief of construction site logistics

Construction:

According to the invention, the production of a filigree concrete slab is proposed which has a thickness of any thickness in a first embodiment variant. To connect the filigree false ceiling with the Ortbetondecke concreted on the insulating material layer are e.g. individual e.g. preferably made of steel connectors, so-called "pins" or "Wellanker" suggested. The in-situ concrete pavement, which is concreted over the insulating material layer, is always executed in the manner that the weight of the sub-ceiling underneath is introduced via the connections provided for this purpose (for example pins) into the in-situ concrete pavement. The introduction of the forces can be carried out both on the lower reinforcement of the Ortbetondecke or initiated by other known methods in the concrete body of the Ortbetondecke.

According to the invention, it has been found that the alternative or supplementary to the pins can also be used lattice girders. These supports can also be so far beyond the e.g. protrude from insulation existing spacing of the false ceiling to the Ortbetondecke that they serve as Auflagerung and spacers for the lower (n) reinforcement level (s) of the arranged above the spacing Ortbetondecke.

In principle, webs can also be formed on these supports and a corresponding configuration of the spacing which also fill with concrete during concreting of the Ortbetondecke. With appropriate training, these webs can also be performed statically effective. Such statically effective webs can be designed to be supportive, so that, for example, (assembly) support-free systems are created and / or the statics that improve the actual Ortbetondecke. Conceivable here are all known, in particular uniaxial, static possibilities such. Preload systems or steel beams etc.

In a further preferred embodiment variant, a system of "feet / supports" is proposed for spacing the filigree sub-ceiling as an alternative to insulating materials which, e.g. with a plate covered at the construction site is stored on yokes. In a further embodiment, this plate may also be factory-made, e.g. by overcasting the first prefabricated sub-ceiling or in a production variant, by their objection in a second (fresh) concrete board which then takes over the function of the now customary statically effective filigree ceiling made according to proven.

In a further embodiment of the filigree sub-ceiling is proposed in the concrete mirror of the lower ceiling to engage a pipe system which can be used responsively and following the heat radiation principle nevertheless for heating and cooling. It is found that it is advantageous to form the concrete mirror as slim as possible in order to increase the reaction time and the dynamics of the element.

It has been found to be particularly advantageous that the recesses required for the ceilings, e.g. for lighting or absorber body serve as openings for the operation of the underlying installation space.

For the purposes of fire protection, it has been inventively found that these recesses have a thickness required for fire protection according to the requirements of e.g. Concrete deposited layer, can be coated. Preferably, however, with the material from which the factory, prefabricated ceiling is provided.

LIST OF REFERENCE NUMBERS

X: not part of the multifunctional suspended ceiling static load-bearing element to which the climate ceiling attaches, usually designed as a reinforced concrete ceiling 1: 1st level, Prefabricated element, consisting of a 7cm thick reinforced concrete slab as prefabricated part. In a preferred embodiment, the element may contain at least one of the positions a, b, c or d Concrete quality: - Normal concrete: C20 / 25, C25 / 30, C35 / 45 or - Lightweight concrete: LC20 / 22, LC25 / 28, LC30 / 33, LC35 / 38 - other known materials a: reinforcement: As reinforcement all known materials, even for non-structural components, usable. For example, structural steel B500 as round steel or mat, carbon fiber, textile reinforcements, steel, plastic, glass fibers and more. b: Pipe system: Medium-leading pipe system for heating / cooling, extinguishing equipment made of known materials. For example: - Aluminum / plastic composite pipe - Plastic pipe, steel pipe, etc. c: Spachtelnut: Recess along the edge of the plate, arranged on the panel joints for on-site insertion of a crack-bridging fabric and for flush filling. d: Installation element: In a preferred variant as a sound-absorbing built-in part - Preferably made of non-combustible material to ensure a fire protection level. For this purpose and to create a smoke-gas-tight level, the element 1, the mounting parts, on five sides, in particular on the side facing away from the room with the material used for the preparation of the element in a minimum required by fire protection strength; wrap. In sound-absorbing components, expanded glass, also porous, has proved to be particularly advantageous. But other known materials such as mineral or glass wool or various foams turned out to be feasible. 2: 2nd level: (Thermal and / or static) separating layer or and installation level, consisting of known materials. For example, Natural materials, EPS, XPS, PU, phenolic resin, also (reflection) film (s) or, for example, hollow body / space forming, arrangement of built-in parts as Holkörper or "egg carton-shaped" construction realized spacings as a self-airing level or recording of installations of all kinds eg Electric, ventilation, heating, plumbing, therefore variable in height. In another embodiment of the invention, a hollow body / cavity, provided that, filled with sound-absorbing material, acoustically connected to the pos. D with this together creates a resonance and pressure compensation space to the acoustic values of, preferably below the entire ceiling space, such to influence that the reverberation time in the room in question, in particular shortening, can be influenced. 3: Girder: Lattice girder made of structural steel B500 for stiffening the element slab during transport and installation as a mounting lattice girder for receiving the concrete pressure from the site-prepared in-situ concrete floor (Pos.:X) 4: Suspension: Connecting elements formed between air conditioning ceiling and static-bearing element in known constructions. The following constructions are particularly advantageous: - round steel loop or straight rod made of mild steel B500 - Round steel loop and / or straight rod or corrugated anchor made of stainless steel - Hangers made of various art and / or other materials

Claims (12)

Prefabricated, large-area component with multiple benefits. Preferably made of concrete, which serves as a false ceiling over at least one spacing, which in turn is made of known materials (for example insulating material, also for thermal separation), as permanent formwork of the above statically effective, preferably made of in-situ concrete ceiling construction, until its curing. In this case, the component for a first use (lost formwork) is constructed and reinforced so that it has sufficient own capacity to take the structural members of the above arranged, preferably made of in-situ concrete ceiling to reach their own stability and on a possible, to anticipated load adapted to derive temporary sporadic substructure in the subsurface. However, the prefabricated component according to FIG. 1 is designed such that the construction (s) or reinforcement (s) necessary for achieving its own load capacity also serve as spacers and / or supports for the lower reinforcement plane of the preferably cast-in-place ceiling to be constructed above , serves. Component according to one or more of the preceding claims, however, designed such that the structures or reinforcements named in FIG. 2 assume permanent static functions. For example, in association with the overlying e.g. Ortbetondecke as concrete ribs in the sense of a ribbed plate. Component according to one or more of the preceding claims, characterized in that the spacing (s) is formed as at least one cavity or, for example, by a plurality of hollow body-forming constructions. Arranged such that the cavity or cavities acts as a thermal separation in the further use as installation level or for air guidance or by an at least partially filled with air distancing. Component according to one or more of the preceding claims, characterized in that in the component an electrical line system or in a preferred embodiment, a medium-leading pipe system is integrated which is used for room temperature control in particular according to the heat radiation principle. It has also been inventively found to be advantageous that the medium-carrying pipe system can also be used as an automated extinguishing and / or sprinkler system. Component according to one or more of the preceding claims, characterized in that in the component contains fixed or reversible recessed mounting parts. In a further variant, designed such that the mounting parts at the same time represent the openings for access to the installation cavity or serve as ventilation or inspection openings. Component according to one or more of the preceding claims, characterized in that in the component, fixed or reversible to each other by a lying in the lower ceiling mirrors air ducting pipe or pipe system are connected such that a pressure equalization between the individual, in a preferred embodiment, sound-absorbing and acoustically effective installation bodies , to improve the acoustic effect is enabled. It has also been inventively found that this pipe system can also be used as an empty pipe system for installation purposes. It was found that the pipe system can be operated via the permanently or reversibly inserted insert or acoustically active components. Component according to one or more of the preceding claims, characterized in that it is sound-absorbing materials in the built-in parts. Designed such that the sound absorbers on or in the cavity or the spacing which can also be formed by insulation, rich and activate this area acoustically with. Component according to one or more of the preceding claims, characterized in that the suspension of the device according to the invention with lattice girders, rods, loops, pins, Wellanker or the like are statically attached to the overlying, after curing static bearing, eg Ortbetondecke attached. Component according to one or more of the preceding claims, characterized in that the plate joint along the plate edge a recess in the form of a flattening and / or groove / chamfer for on-site insertion of a crack-bridging fabric and for flush filling is provided. Component according to one or more of the preceding claims, characterized in that the spacing in the form is formed as a thermal separation view, forming the Dämmeffekt installation channels. For this purpose, an "egg-carton-type" construction is proposed according to the invention, which has a closed structure on the Ortbetondecke side facing. On the other hand, on the lower, the space-facing side which has webs and cavities. Particularly advantageous is the design of this hollow body / cavity-forming construction of a pressure-resistant and heat-insulating material. For example, PU, EPS phenolic resin. Component according to one or more of the preceding claims, characterized in that the hollow body / cavity-forming construction is internally coated in such a way that it optimally reflects electromagnetic waves (eg thermal radiation) in the respective intended wavelength.

Images