EP2119838A1 - Insulating wood/wood material construction element and pressure-resistant insulating material for use in roofs, walls, ceilings and floors - Google Patents

Abstract

The universally used constructional insulation element comprises a vapor barrier, a web of pressure-resistant insulating material (2) and two disks made of a solid wood or a wood material (1). The dimension is adjusted for the disk and the insulating material. The insulating material is provided with a water-repellent or water proof layer for a roof structure.

Description

Technical area

The invention relates to a structural element for use in and as a wall, ceiling, roof and floor as well as various derived variations.

State of the art

Prefabricated elements for surface applications in the construction industry which at the same time combine the structure and the insulation are well known. You will be i.d.R. artisanal, object-related made of rod-shaped materials, with board materials (OSB, chipboard, sheet metal or similar) planked or boards / slats and insulated with flexible insulating materials.

That's how it describes it DE 197 28 980 A1 an element designed for use as a roof element in box form for laying over an existing foot and ridge purlin. Essential is the two-sided planking to obtain a rigid element that can be manipulated by crane and forklift without deforming. A one-sided planking would endanger the shape of the element in the manipulation and the accurate fit of the insulation material.

The insulating materials used in previously known elements are usually less pressure-resistant mineral fiber insulation with gross densities between 20 and 30 kg / m ³ . They are characterized by good properties in terms of heat transfer. A disadvantage is their poor heat storage properties and thus to buffer (low density, low specific heat storage capacity) and their poor length-related flow resistance and thus low Sound absorption. Good building physics results can only be achieved by combining different component layers.

In contrast, pressure-resistant wood soft fiber insulation materials combine good physical properties: heat protection, sound insulation, moisture absorption, insulation. So far, this could not be used in an intermediate rafter insulation or between wall stems, because due to the high rigidity of the material, a joint-free installation could not be implemented in the building practice.

Thus, the invention also opens up new applications for pressure-resistant soft wood fiber boards.

• * Flexible Holzweichfaserplatten benötigen für ihre Flexibilität und Klemmwirkung Stützfasern i.d.R. aus Kunststoff.
• * Die Euroklasse E nach EN 13501-1 für den Brandschutz wird durch Beimengung mineralischer Salze erreicht.
• * Diese Platten weisen gegenüber den druckfesten Holzweichfaserplatten deutlich geringere Rohdichten auf.
  Problematisch ist weiterhin die Vermischung vieler verschiedener Materialien (Holz, Holzwerkstoffe, verschiedene Kunstharze, Stützfasern aus Kunststoff, verschiedene Mineralische Fasern und Zement) in einem Element. Die baubiologische Beurteilung und die Entsorgung am Ende der Verwendung sind schwer zu überschauen bzw. aufwändig und teuer.
  Eine Fertigung der beschriebenen Elemente ist nur handwerklich möglich, eine industrielle Fertigung wäre wegen der vielen verschiedenen Arbeitsschritte und Objekte unwirtschaftlich. Zudem treten bei den üblicherweise eingesetzten Elementen hohe Kosten und Umweltbelastungen durch Transport auf.
  Zunächst wird das Material vom Werk zum Händler geliefert, dort vereinzelt und zum ausführenden Handwerker geliefert, dort in der Montagehalle zu Elementen zusammen geführt um dann i.d.R. mit Spezialfahrzeugen als Elemente auf die Baustelle geliefert zu werden.
  Die Verwendung der bisher verwendeten Elemente ist eingeschränkt. Durch die Ausbildung als Kastenelement werden diese unnötig schwer. Eine Manipulation bauüblicher Abmessungen ist nur mit mechanischen Hebegeräten möglich. Dies schließt eine Verwendung aus, sobald auf Grund räumlicher Gegebenheiten mechanische Hebegeräte nicht zum Einsatz kommen können, bzw. ihr Einsatz unwirtschaftlich wäre. Ein wesentlicher Teil der heute am Bau ausgeführten Arbeiten sind jedoch Sanierungen bzw. Bauen im Bestand mit kleinen Volumen bzw. schwieriger Zubringung.
  Bisher verwendete Elemente weisen auf der Oberseite i.d.R. Folien oder dünne paraffinierte MDF-Platten als wasserabweisendes Unterdach auf. Beide sind in der baulichen Praxis durch mechanische Einwirkungen der Gefahr der Beschädigung ausgesetzt.
  Ausgehend vom vorgenannten Stand der Technik liegt der Erfindung somit die Aufgabe zugrunde ein Element zu schaffen, dass
• * gleichzeitig die Funktion des Tragwerks und der Dämmung übernehmen kann
• * aus möglichst wenig Ausgangsrohstoffen besteht,
• * eine ausreichende Steifigkeit aufweist um mittels mechanischen Hebegeräten manipuliert werden zu können,
• * ausreichend leicht ist um beim Bauen im Bestand auch von Hand manipuliert werden zu können
• * gute dämmende Eigenschaften hinsichtlich Kälte, Hitze, Schall und Feuchtigkeit aufweist
• * leicht zu recyceln bzw. zu verwerten ist
• * industriell erzeugt werden kann
• * wirtschaftlich, umweltfreundlich und baubiologisch einwandfrei zu erzeugen und einzubauen ist
• * einen schnellen Baufortschritt gewährleistet um im Sanierungsfall bestehende Gebäude schnell schließen zu können
• * weitestgehend unempfindlich gegen mechanische Beanspruchung in der baulichen Praxis ist

It should also be noted that flexible wood fiber insulation panels have been developed for installation between rafters and stems. These plates differ in different points from the ideal to be used pressure-resistant soft wood fiber boards:

• Flexible flexible wood fiber boards require support fibers, usually made of plastic, for their flexibility and clamping effect.
• * The Euroclass E according to EN 13501-1 for fire protection is achieved by admixing mineral salts.
• * These panels have significantly lower densities compared to the flameproof wood fiber boards.
  Another problem is the mixing of many different materials (wood, wood materials, various synthetic resins, plastic backing fibers, various mineral fibers and cement) in one element. The building biology assessment and the disposal at the end of the use are difficult to overlook or complex and expensive.
  A production of the elements described is only artisanal possible, an industrial manufacturing would be because of the many different steps and Objects uneconomical. In addition, occur in the commonly used elements high costs and environmental impact of transport.
  First, the material is delivered from the factory to the dealer, there isolated and delivered to the executing craftsman, there in the assembly hall to elements together and then usually with special vehicles as elements to be delivered to the construction site.
  The use of the previously used elements is limited. By training as a box element they are unnecessarily difficult. A manipulation of customary dimensions is only possible with mechanical lifting devices. This precludes use as soon as mechanical lifting devices can not be used due to spatial conditions, or their use would be uneconomical. However, an essential part of the work that is currently being carried out on the construction site is renovation or construction in the existing building with small volumes or difficult access.
  Previously used elements usually have films or thin paraffinized MDF boards on the top as a water-repellent sub-roof. Both are exposed in structural practice by mechanical effects of the risk of damage.
  Based on the aforementioned prior art, the invention is therefore based on the object to provide an element that
• * can simultaneously assume the function of the structure and the insulation
• * consists of as few starting raw materials as possible,
• * has sufficient rigidity to be manipulated by mechanical lifting equipment,
• * is sufficiently light to be able to be manipulated while building in the inventory also by hand
• * has good insulating properties in terms of cold, heat, sound and moisture
• * easy to recycle or recycle
• * can be produced industrially
• * economically sound, environmentally friendly and biologically ideal to produce and install
• * ensures rapid construction progress in order to be able to quickly close existing buildings in case of renovation
• * is largely insensitive to mechanical stress in construction practice

Presentation of the invention

The solution of this invention underlying object (s) is set forth in claim 1. The concept of the invention advantageously further features are the subject of the dependent claims and the description in particular with reference to the exemplary embodiments.

The solution according to construction of the structural Dämmelements gem. Claim 1 consists of two slats of a nail-resistant material (1), usually solid wood slats, but it can also wood materials such as OSB, kerto, plywood or MDF are used, which, one each, alongside the element on the narrow sides of a wood softboard or other stiff insulation (2) be glued ( Fig. 1 ). Their dimensioning depends on the requirements of the application, usually statics.

Depending on the application, the wooden lamellas on the long sides of the element assume the function of load-bearing rafters, wall posts, ceiling beams, purlins, latches or similar.

The type and thickness of the insulation depends on the application.

According to the task, reduction of the materials used, good Insulating properties, easy to recycle or dispose of and good building biology properties, should be pressure-resistant soft wood fiber boards used as insulation material. They usually consist of wood, a small glue addition (ideally, the glue used for bonding lamella and insulating material should be identical to the glue used in the production of the insulating material) and optionally a water repellent, usually paraffin. Soft wood fiber boards are in many ways the ideal insulation material for this invention.

Finds e.g. a wood soft fiberboard made of wood fibers with the binder PUR resin use and is the gluing of the elements made with PUR resin, thus creating an element of only two raw materials. A building biology assessment is thus facilitated. Known wooden materials made of wood and PUR resins have been shown to produce emissions such as grown wood. Thus, an improved technical application of the material wood would be given, without negative effects on the positive biological properties.

Soft wood fiber boards have a high length-related flow resistance, which already brings in a single-layer structure very good sound insulation values, as well as a very high buffer effect in terms of summer heat.

An element of wood and e.g. PUR resins are decentralized at any time to be used thermally in suitable plants, there are no disposal problems.

Soft wood fiber boards are also produced in consistently water-repellent quality. If these insulation materials are used, there would be continuous moisture protection, which is virtually indestructible in structural practice.

However, the use of other rigid insulation materials (polystyrene foam, polyurethane foam, flameproof mineral fiber insulation, etc.) is conceivable and part of the inventive concept, since depending on the application, the use of alternatives may be desired or necessary.

A combination of different insulating materials is conceivable and part of the inventive concept.

The insulating material takes over in the invention, in addition to the functions of heat-heat and sound insulation, the functions of planking / element stiffening, mounting aid, undercoverage, temporary weather protection, plaster base u.a.

Due to the rigidity of the insulating material and the full-surface narrow-sided bonding with the wooden lamellae, an element is created that, unlike previously customary, can do without the construction as a box or frame element. The essential advantages resulting from the invention are the weight and cost savings without compromising the function. The invention enables a weight reduction, which allows manipulation of the elements by hand.

The production in known glulam wood presses enables an industrial economic production. The presses usually have lengths between 13 and 24 m. These dimensions enable elements that enable a rapid construction progress and were difficult to implement in the previous manual practice. stand profile.

Annex 4 to the patent application Sequence protocol part of the invention Designs / variations of the invention, industrial applicability Laying as a roof element

When laying as a roof element, the invention ( Fig.1 ) parallel to the location or parallel to the eaves.

In the case of parallel laying via a foot - if necessary a middle and a ridge purlin - the element replaces the rafters and insulation ( Figure 13 ).

For this application, the invention gem. Claim 2 or claim 3 are varied.

By a continuous or partially water-repellent finish of the insulation according to claim 2 eliminates the u.U. necessary application of an emergency roof as well as the subsequent application of a sub-roof made of foil or bottom cover plate. Mechanical damage, which make the roof waterproof, i.d.R. Walking in roofing work, are almost impossible by the continuous water-repellent treatment.

A variation of the invention according to claim 3 provides to make rafters and counter battens in one piece ( Fig. 4 ). This results in a 2- to 4 cm higher rafter cross section, which protrudes beyond the glued insulation. This additionally increases the carrying capacity of the element or the construction height is reduced by 2 - 4 cm. The material wood is better utilized.

Traverse-parallel laying is of particular importance in hall and commercial buildings. For this purpose, the invention gem. Claim 1 laid over, for example, glulam beams or steel beams ( Fig. 14 ). The elements can thus replace the coupling purlins and at the same time insulate them.

This is of particular importance insofar as wood soft fiber insulating materials have very good soundproofing properties. Business buildings noise-intensive operations can thus be closed and insulated easily and effectively. Furthermore, wood soft fiber insulating materials can very well buffer heat and thus make a significant contribution to the summer heat protection of buildings.
Since commercial properties tend to have lower insulation thicknesses than residential buildings, the use of the invention with the insulating material soft wood fiber in commercial buildings where heat-sensitive goods store or reduced in shopping the cost of air conditioning.

A modification of the eaves-parallel laying is the use as insulating element.

In the renovation of old roofs, the following problems often occur. The rafters of old buildings are too weak by today's standards. If a new load is added by a newly introduced thermal insulation, the existing roof truss is often called into question or costly measures to reinforce the existing rafters are inevitable.

If the invention gem. Tray laid parallel to the trajectory, the lamellae may, if sufficient dimensioning, possibly distribute the load or remove it via gable walls and / or partitions ( Figure 15 )

The interior design can be maintained and due to the high diffusion-open nature of the wood soft fiber insulation material, the space between the rafters can be additionally insulated after installation of a roof renovation membrane in sub-and-top laying ( Fig. 16 ). This reduces the height compared to a pure on-rafter insulation.

Use as a wall element

• * Parzellierung der vorhandenen Gefache
• * Dämmen des Bauwerkes
• * ggf. Schaffung einer 2. wasserführenden Schicht und/oder Unterkonstruktion um eine vorgehängte Fassade aufzunehmen.

The invention acc. Claim 1 - 7 is particularly suitable as an attached outer wall in skeleton construction ( Fig. 17 ) as in hall construction ( Fig. 18 + 19). Wherever larger spans have to be bridged between supporting columns or ceilings, a framework is usually first erected that parcels the large existing fields. By applying the invention gem. Claims 1 -7 in vertical or horizontal installation, various steps are done in one operation:

• * Parceling of existing compartments
• * Dams of the building
• * If necessary, create a second water-bearing layer and / or substructure to accommodate a curtain wall.

Furthermore, the invention is gem. of claims 1 - 7 with vertical installation as a supporting structure and insulation in timber frame construction ( Fig. 20 ).

There are two types of production to be distinguished in timber frame construction. Construction site construction and building with prefabricated elements as a precursor to wood panel construction.

During construction site work, after aligning the threshold, stalk for stalk is aligned and fixed on the construction site, after the introduction of the stiffening, the wall is usually planked with wood-based or plasterboard panels from the inside of the building. The disadvantage here is the great amount of time to align and fix the stems. The installation of the insulation must now take place via the framework, depending on the weather and impaired by the poor installation conditions on a scaffold.

If insulation and wall stems gem. of claims 1 - 7 replaced and these are factory gem. Cut plan at the desired angle eliminates the need for time-consuming alignment of the stems and weather-dependent insulation over the scaffolding. The elements are simply "turned off" on the threshold, the stiffening of the wall then takes place as usual in timber frame construction on the planking ( Fig. 20 ).

• * durch den Einsatz nach Plan winklig gekappter Elemente entfällt die Notwendigkeit eines Montagetisches zum Ausrichtung der Wandstiele
• * eine Dämmung muss nicht mehr eingebracht und/oder separat transportiert und bauseitig eingebracht werden
• * bei dickeren Wänden kann die außenliegende Beplankung zur Elementaussteifung für den Montagefall entfallen, da durch die Steifigkeit des Dämmstoffs ein Verformen des Elements verhindert wird
• * beidseitig geschlossene Wandelemente dürfen nur güteüberwachte und zertifizierte Handwerksbetriebe fertigen. Da eine außenliegende Beplankung für den Transport und die Manipulation nicht notwendig ist, eröffnet sich die Möglichkeit der Vorfertigung dickerer Elemente auch nicht zertifizierten Betrieben.

The transition from timber frame construction with prefabricated walls to wood panel construction is fluid. In order to prefabricate walls in timber frame design with sufficient accuracy, a mounting table is usually necessary. It serves to fix the wall stems at right angles to threshold and Rähm until a planking in the form of a wood-based or gypsum board takes over the stiffening. If the wall stems used become slimmer and deeper (the wall becomes thicker), further stiffening on the opposite side becomes necessary to prevent deformation when manipulated with lifting equipment.
By the use of the invention gem. of claims 1 - 7, the following is achieved:

• * The use of a plan of angularly capped elements eliminates the need for a mounting table to align the wall posts
• * an insulation no longer has to be introduced and / or transported separately and brought in on-site
• * For thicker walls, the external planking can be omitted for element reinforcement for the installation case, since the rigidity of the insulating material prevents deformation of the element
• * Wall elements closed on both sides may only be manufactured by quality-controlled and certified craftsmen. Since an external planking for transport and manipulation is not necessary, opens up the possibility of prefabrication thicker elements even non-certified companies.

In a similar form, the invention gem. of claims 1 and 3 - 7 as a quick to install partition. ( Fig. 21 ). These are elements of said claims fixed on a threshold and strung together. As Rähm here is a metal angle rail. The remaining joint after assembly is closed with cotton wool from natural or mineral fiber.

Use as a ceiling element

In the ceiling, the situation is similar to that in the wall and roof. Usually prefabricated ceiling elements are designed as a box or frame element, made of construction timbers, insulation and planking with all the associated disadvantages.

• * durch die geringere Tragwerkshöhe gegenüber konventionellen Decken aus Holzbalken nimmt das Schwingen der Decke zu.
• * durch die kraftschlüssige steife Verbindung der Hölzer untereinander breiten sich Schallwellen im Tragwerk leichter und weiter aus.
• * durch die fehlende Absperrung der Brettschichtholzelemente gegen Quellen und Schwinden des Holzes muss ein Arbeiten jedes Elements in der Konstruktion berücksichtigt werden, bzw. führt bei mangelhafter Ausführung oder extremen klimatischen Beanspruchungen (hohe Dauerfeuchten, extreme Trockenheit) zu Bauschäden.

As special components for ceilings, the increasingly popular glued laminated timber or cross laminated timber elements can be considered. Here, boards / planks are glued to flat elements. This results in two or three problems:

• * Due to the lower structural height compared to conventional wooden beam ceilings, the swinging of the ceiling increases.
• * Due to the frictional rigid connection of the woods with each other, sound waves propagate more easily and further in the structure.
• * due to the lack of shut-off of laminated timber elements against swelling and shrinkage of the wood, it is important to consider the work of each element in the construction or, in the case of poor performance or extreme climatic stress (high permanent moisture, extreme dryness), structural damage.

The invention of claim 1 and 3 and claims 5-7 improves the known glulam elements by replacing individual slats by wood soft fiberboard ( Fig. 22 ). The well-known advantages of the glued laminated timber elements (fast assembly, high safety at work) are maintained and are complemented by less vibration of the elements and a muted spread of Sound waves.

Use as a wall stalk

Reducing the dimensions of the elements to cross sections which are common as wall posts in timber frame construction so obtained according to claim 9 insulated wall stems ( Fig. 11 ). While the inner solid lamella is dimensioned according to statics, the exterior serves to accommodate the fasteners of an attached facade. The insulating material now fulfills two tasks: It determines the depth of the framework and thus the Gefachdämmung and at the same time insulates the wood content of the Wandstiels, the U-value of the component improves.

Non-load-bearing drywall walls are made of squared lumber, KVH or laminated veneer lumber, if not of metal profiles. That's how it describes DE 10 2005 015 404 A1 a building wall made of laminated veneer lumber. While the metal profiles require expensive auxiliary constructions to fix loads in the wall (cisterns, pipelines, etc.), squared timbers or KVH cause problems due to distortion under humidity fluctuations. Veneer plywood and squared timbers / KVH, however, have a detrimental effect on the passage of sound through partitions due to their massive structure.
The structural advantages of solid wood or laminated veneer lumber and improved sound insulation properties are combined in the invention according to claim 10. While the wooden lamellae absorb the fasteners of the planking, the insulating material (ideally soft wood fiber) dampens the sound passage. The dimensions of the slats and the insulating material are further reduced compared to the use as a insulated wall post for timber frame construction. Ideally, the dimensioning is based on the known dimensions of the standard in drywall metal stud profiles.

Claims (10)

1 and / or 2 consisting of at least one web pressure-resistant insulating material (2) and at least two slats of solid wood or wood materials (1), starting with a lamella, are alternately glued together. The dimensioning of the fins and the insulating material depends on the requirements of the application, i.d.R. statics and building physics. Structural insulating element according to claim 1, characterized in that the insulating material (3) is provided with a water-repellent or waterproof layer (4), or consists entirely of water-repellent / waterproof materials to fulfill a roof or emergency roof function. Elements can optionally be equipped with a vapor barrier (5). (Fig. 3). Structural insulating element according to claim 1 or 2, in which the lamellae (1) are wider, so that an element with counter-lath (6) (roof) or ventilation or installation level (wall) is formed (Fig. 4). The counter-battens can thus be omitted, or the part of the blade which replaces the counter-battens can now be statically included in the calculation. Structural insulating element according to claim 1 to 3, characterized in that within the element a plate made of solid wood (7) or wood materials is glued in order to obtain a disk effect of the element and an air-tight plane, protected from mechanical damage to form. (Fig. 5) The insulating material (2) can hereby be recessed on one side to allow, for example, installations. The location of the plate in the element can be selected as needed (Figure 6). Structural insulating element according to claim 1 to 4, characterized in that it comprises at an outer lamella (1) of a first constructive Dämmelements at least one spring-like projection (9) or a spring in one or more corresponding groove-like depression (s) or Groove (s) (8) in the adjacent element engages / engage (Fig. 7). Structural insulating element according to claim 1 to 4, characterized in that it has on each outer lamella (1) and / or on the front side at least one groove (11) in the assembly for mounting one or more corresponding loose spring (s) made of wood / Wood material (10) is introduced / which is then engaged in the groove (s) of the adjacent element / engage (Figure 8). Structural insulating element according to claim 1 to 4, characterized in that it has on the respective outer slats (1) and / or on the end faces an alternating fold (12). While the narrow-side fold ensures the necessary handle width, especially when used in timber frame construction to the required edge distances of the fastening means (14) of the stiffening planking (13) to comply with the frontal fold serves as mounting and fixing aid to threshold and Rähm. (Fig.9). Structural insulating element according to claim 1 to 4, characterized in that it has on the respective outer slats (1) (narrow sides) an undercut changing fold (15) whereby the element when used as a roof or ceiling element by gravity automatically "refers "(Figure 10). Structural insulating element according to claim 1 chosen in its dimensions so that it is used as a thermally separated wall stem in timber frame construction. For this, the slats are dimensioned differently. The inner slat (1) replaces the usual solid wood handle, is dimensioned according to statics and takes the fastening means (17) of the stiffening planking (18). The outer lamella (16) serves to receive the fastening means (19) of the facade (20). Of the Insulation (2) reduces the heat transfer and fixes the wall depth. The insulating material (21) lying between the wall stems is introduced on the finished component. (Figure 11). Structural insulating element according to claim 1 chosen in its dimensions so that it is used as a sound-decoupled frame in partition wall construction in dry construction. While the slats (1) absorb the fastening means (22) of the skins (21) of the partition, the insulating material (2) breaks the sound. The three-layer construction prevents the usual distortion of solid wood products. The insulating material (21) lying between the wall stems is introduced on the finished component. (Fig. 12)

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