DE102004017325A1 - Component, in particular plate-like component and method for producing a component, in particular a plate-like component - Google Patents

Abstract

Construction element, especially a plate-shaped construction element, comprises at least two layers (A, B) containing cellulose elements or cellulose-containing elements such as wood chips, cement as a binding agent, and optionally aggregates. Each layer consists over the entire layer thickness of a mixture of cellulose elements or cellulose-containing elements of all fractions of the same sieve line. The cement is uniformly distributed through the layer thickness (S). Adjacent layers are joined together by their boundary surfaces (FA, FB) and have different crude densities depending on the cement content or the degree of packing. An independent claim is also included for the production of a construction element, especially a plate-shaped construction element.

Description

The invention first relates to a component according to the preamble of claim 1. Such a component is in the DE 25 48 210 B2 described.

For the preparation of the known device is used a fiber or Spangemisches. This is after cutting into at least two fractions, namely fine material with a chip size of 2-8 mm and normal with a chip size of 8-20 mm - of which at least 80% greater than 12 mm - divided and each of the fractions for themselves with binder cement mixed. In this case, the fine material fraction is added much more cement than the normal fraction. The two fractions mixed with the binder cement are sprinkled by air classification onto a substrate, whereby during spreading at least three layers gradually merging with one another are produced which are different in terms of fiber or chip-to-cement ratio. According to a preferred embodiment of DE 25 48 210 B2 The main fraction (64%) consists mainly of a chip mixture of 5-12 mm in length, which is intended to ensure reinforcement of the plate-like component and, associated therewith, also the corresponding strengths. The fines (0-5 mm) of about 14% of the total weight of the chips are placed in the outer layers. In this case, the structure of the known plate-like component is made such that a gradual transition from the outer uniform fine layers to the inner coarse layer takes place.

Construction and production of the plate-like component according to the DE 25 48 210 B2 are perceived as very complicated and costly.

Of the DE 34 06 895 A1 is a method for producing cement-bonded wood fiber molded body is known in which a mixture containing Portland cement, water and wood chips or wood wool, and optionally with conventional additives deformed and cured under pressure and optionally with heating to dimensional stability. From this known document it is also known to use amorphous silicon dioxide for the mineralization of wood components (beech chips).

Of the DE 198 26 190 C1 For example, a composite panel is known which consists of at least two layers, one layer of concrete and another of an insulating material formed from a mixture of pulp mixed with water and cement. Thus, the known composite panel on an entirely made of concrete outer wall, which is a supporting element. Inside, the plate is provided with the insulation board made of pulp and cement. The composite plate according to the DE 198 26 190 C1 is perceived as disadvantageous because of the supporting function of the composite panel securing concrete area makes virtually no contribution to the thermal insulation of the composite panel.

Finally are In general, plate-like components made of monostructured Aerated concrete known. Such an aerated concrete plate meets both a thermal insulation function as well as a support function. However, both the thermal insulation function on the one hand, as well as the support function, on the other hand not considered optimal.

Starting from the initially described component according to the DE 25 48 210 B2 , The invention has for its object to provide a universally applicable device which is relatively easy to manufacture and which as an integrated component different functions, especially the support function on the one hand and the thermal insulation function on the other hand, optimally fulfilled.

Corresponding the invention, this object is achieved together with the features of The preamble of claim 1 with its characterizing features solved by that each layer substantially over the entire layer thickness from a mixture of cellulosic or cellulosic Elements of all fractions of the same Sieblinie insists that the Cement evenly over the Layer thickness is distributed that the facing adjacent Layers with their interfaces are firmly connected to each other and that adjacent layers dependent on of cement content and / or depending on Degree of compaction have different densities.

In contrast to the device according to the DE 25 48 210 B2 an essential advantage of the device according to the invention is first that the grain size distribution of the cellulosic elements or the cellulosic elements across the thickness of a layer not individually in a complicated manner along a gradient, but that each layer substantially over the entire layer thickness away from cellulosic elements or cellulosic elements of all fractions of the same grading curve. This feature of the invention is essential for easy manufacturing handling and for a maximum Measured in terms of manufacturing identity as a prerequisite for uniform material characteristics.

In contrast to the device according to the DE 25 48 218 B2 the cement is not inhomogeneous, but rather homogeneously distributed over the entire layer thickness. This feature of the invention also serves for simple production handling, a maximum of manufacturing identity and as a prerequisite for uniform material parameters.

One Another feature of the invention is that the facing each other adjacent layers with their interfaces firmly connected are. Here, a gap-free homogeneous compound is preferred, which, for example, by gluing the facing each other interfaces adjacent layers can take place. Through this solid connection formed adjacent layers by means of their interfaces an integrated component.

Especially It is important that neighboring layers are dependent on each other of cement content and / or dependency have different densities from the degree of compaction.

Within the scope of application of that inventive feature is a special advantageous combination in that both adjacent to each other Layers of the same mixture of cellulosic elements and / or cellulosic elements of all fractions of the same Siebkennlinie However, the one layer meanwhile a relatively small Cement content and the other layer a relatively large proportion of cement includes.

One has such a composite component, on the one hand due to the Layer with the relatively low cement content, along with a lower density, a very good thermal insulation value and on the other hand because of the layer with the relatively large proportion of cement, along with a greater density, over one very good support function.

One equally advantageous, good thermal insulation function and good support function in unifying element according to the invention is achieved when you go for both layers a mixture with the same recipe and with cellulosic elements or cellulosic elements of the same grading curve used and one of the two layers not or only slightly compacted. On this way has the latter layer with the lower one Bulk density very good thermal insulation properties, while the adjacent other layer is compressed to a greater bulk density, associated with a good support function to achieve.

As already mentioned, should both adjacent layers of the device according to the invention with their interfaces be firmly connected. In a special embodiment of the Invention this happens in such a way that the adjacent Penetrate layers in the area of their facing interfaces, wherein the penetration area is a cohesive and positive Represents composite forming zone.

In In practice, this is done so that the first layer with the example larger cement content initially in poured a mold and a certain setting time without one utter corroboration is done, is waiting and then the lower cement content exhibiting second still quite flowable layer is applied. In this way, results at the interfaces of the two layers an interlocking of the cellulose elements or the cellulosic Elements both a form-fitting Composite as well as by the inflow of the second layer in the cavities the first layer a cohesive Composite.

As already mentioned, an essential feature of the invention is that the layer with the respective lower bulk density the heat insulation function and the layer with the respective larger density fulfills the supporting function of the device.

Furthermore is the bulk density by variation of the cellulose elements or the cellulosic elements in addition to be determined or varied. This happens according to the invention by that the bulk density in addition by the density of the cellulosic elements or the cellulosic one Elements is determinable. Hardwoods, especially hard tropical woods, have one greater density on as softwoods.

According to the invention, the bulk density for changing particular physical properties, for example, to change the sound transmission properties, additionally be varied in that the mixture regardless of the cement content mineral admixtures, such as a specific particular heavy addition in the form of barium sulfate, admits.

As already mentioned, the invention provides, the density of a layer in dependence to vary the degree of compaction. This can be done accordingly Invention features thereby happen that the degree of compaction determined by mechanical action, in particular by vibration is.

Farther allows the invention, the degree of compaction by adding To determine pore formers. Pore formers can be made from a reaction mixture made of lime, water and metal powder. As metal powder is Aluminum powder or zinc powder is preferred. When using such Pore forming agent is hydrogen, with the effect that the layer similar to their solidification like a batter, forming pores, "rises".

Around a good composite of cellulosic elements or cellulosic To ensure elements within the layer, the invention provides suggest that the cellulosic elements or the cellulosic elements a mineralized surface exhibit.

According to the invention, a such mineralization happen by the surface of the Cellulose elements or cellulosic elements by means of water glass is mineralized. Another variant of the invention is that the surface the cellulose elements or the cellulosic elements by means of amorphous silica is mineralized.

Also, in this connection, the invention provides that the surface of the cellulosic elements or of the cellulosic elements is mineralized by means of lime milk or cementmilk. Thus, for example, provided with a thin cement coating wood shavings according to the DE 195 31 481 C1 be advantageously used as mineralized cellulose elements for the production of components according to the invention.

Corresponding another embodiment The Efindung provides that at least one shift, in particular the supporting function of the component fulfilling layer, with reinforcing elements, such as. with elongated and / or lattice or net-like reinforcing elements made of metal, plastic, glass fiber or carbon.

Also the invention provides that in the context of a far-reaching prefabrication of components, at least one layer of line elements for transmission of fluids and / or of electric current.

External electric influences (so-called "electrosmog") can be shield according to the invention characterized in that at least one Layer graphite elements, in particular graphite powder contains.

Finally sees the invention proposes to add at least one layer of heat balance elements, which are able, due to the phase change, e.g. during the Sunlight, to absorb heat and give off heat when the sun's radiation ceases. Such elements, the main ones made of paraffin, are called "PCM" (Phase Change Material) have become known and are for example by the RUBITHERM GmbH, Worth dam 13-27, 20457 Hamburg, distributed.

In The preceding description is always of two adjacent ones Layers the speech. Of course can be a device according to the invention contain more than two layers, of which, however, always two are adjacent to each other.

The invention further relates to a method as according to the features of the preamble of claim 18 by the DE 25 48 210 B2 has become known.

As already mentioned, the known method requires a very cumbersome method of production. According to the features of the characterizing part of claim 18, this method of preparation is considerably simplified by classifying the cellulosic elements and / or the cellulosic elements with all fractions of a particular first grading curve to produce a first layer comprising the cellulosic elements or the cellulosic elements with cement and water are mixed into a mixture, that the mixture is filled into the mold, that the mixture is shaken or vibrated to increase the degree of compaction, whereupon the second layer is produced as a mixture, which cellulose elements corresponding to the grading curve of the first layer or another Sieblinie or cellulosic elements as well as cement and water, and that the second layer is applied to the first layer is brought.

Further Invention features are additional dependent claims refer to.

In The drawings are preferred embodiments accordingly the invention shown, it shows

1 a schematic longitudinal sectional view of a vibrating table with attached form for producing a composite plate,

2 a partial longitudinal section through an outer wall,

3 a partial longitudinal section through a bottom plate,

4 a partial longitudinal section through a ceiling,

5 a partial longitudinal section through a roof panel,

6 a graphical representation of the thermal conductivity lambda in relation to the gross density of different materials and

7 the compressive strength Sigma D in relation to the bulk density compared different materials.

In The drawings are mutually analogous elements or analogous to each other Always provide areas with the same reference numerals.

On a vibrating table 10 is a shape box 11 put on which form side walls 12 as well as a mold bottom 13 having.

The vibrating table 10 is connected in a conventional manner with a vibrator or other unbalance exciter, which in 1 is symbolized by the two arrows labeled R.

In the open-top mold box 11 are successively filled two layers A and B, the layer thickness is denoted by S. Both layers A and B, which in each case represent a layer of wood-light concrete, hereinafter referred to as "HLB", in the present case each have a mixture with the same formulation The mixture consists of about 12% by weight of wood shavings, from about 45% by weight Cement and about 43 percent by weight of water.

In the mold box 11 First, a first mixture for producing a first layer A is filled and pulled smooth. Then the vibrating table 10 activated, so that the layer A is compressed. After a particular to be determined setting time, which can be shortened by prior addition of a setting accelerator, eg water glass, to the mixture, the second layer B is filled after an initial solidification of the layer A on the latter. The layer B is subjected to no or only a short-term shaking movement, that is not compacted, so that after curing of both layers A and B, the layer A has a greater bulk density than the layer B.

The the layer B facing interface the layer A is with FA and the layer A facing the interface of Layer B is labeled FB. Meanwhile, after pouring the flowable mixture the layer B in the area of the interfaces FA and FAB one with a dashed wavy line indicated mixing zone M formed, which the two layers A and B form fit and cohesively with each other combines. In particular, the cellulose elements, in the present case Wood shavings, take care of a form-fitting Composite within the mixing zone M.

The different densities of the layers A and B come in the present Case not by a different recipe, but only by it caused that the layer A by shaking or by vibration was mechanically compressed while the layer B no mechanical or only a short-term compression subject.

on the other hand For example, in the present case it is possible to calculate the bulk density, e.g. of the Layer A by adding a larger proportion of cement to increase.

It is also essential for layers A and B that both layers contain cellulose elements (in the present case wood shavings) corresponding to the same grading curve with all fractions of this grading curve. For example, a grading curve (sieve residue curve) was determined as follows:

I =

Siebgröße;

II =

Siebrückstand;

III =

Siebrückstands-Summe;

IV =

prozentualer Siebrückstand;

V =

Summen der prozentualen Siebrückstände.

Here, the Roman numerals mean the following:

I =

screen size;

II =

sieve residue;

III

Sieve residue-sum;

IV =

percentage of sieve residue;

V =

Totals of percentage sieve residues.

The table values given above represent an average of about 600 screenings of wood shavings, which are subsequently coated with a thin layer of cement according to the DE 195 31 481 A1 provided - ie mineralized - were, so that the so-mineralized wood shavings can form an intimate bond with the surrounding material of the respective layer A, B.

After sufficient curing, the finished composite panel component P can be removed from the molding box 11 demoulded and removed. In this case, such a mold box in a conventional manner with of the mold bottom 13 removable mold walls 12 be provided.

The use of a vibrating table 10 is not mandatory for the application of the mixture according to the invention. For example, floor slabs can be cast layer by layer in situ, and the individual layers can be compacted with mobile vibrators (so-called vibrating pears, for example).

This in 2 shown as a partial longitudinal section outer wall component E has a weatherproof outer layer 14 , eg a plaster layer, to which a layer B (thermal barrier layer) and subsequently a layer A (base layer) and a layer C join.

Also in the case of this outer wall component E can, as in the embodiment according to 1 , the same recipe for the layers A, B and C are assumed. Also, the production of the outer wall component E basically according to the in 1 shown type done. However, it would be useful to first cast the layer C, which forms a radiation heating layer and pipes through which a heat exchange medium flows 15 embeds.

there can the bulk density of the layer C of the apparent density of the subsequently poured Support layer A correspond. Both layers C and A receive accordingly the same degree of compaction while the thermal barrier coating B none or only a minor one Compaction is subjected and therefore compared to the layers C and A over the lower bulk density and therefore has the greater thermal insulation capacity.

If it for the individual application is appropriate, the thermal barrier coating B with heat compensation elements "PCM" (Phase Change Material) already described above be provided.

Analogous to the composite panel component according to 1 is also in the outer wall component E between the interfaces FA and FB as well as between the interfaces FA and FC respectively indicated by a dashed wavy line mixing zone M present, in which in each case between the individual layers B, A and C, a particularly intimate form and fabric composite consists.

In 3 a partial longitudinal section through a bottom plate component G is shown. Also, the bottom plate member G has three layers A, B and C, wherein the bulk density of the layer A to the layer C gradually decreases from layer to layer. With 16 designated points within the Layer A should symbolize a reinforcement, which may be formed as a metal, pulp or fiber reinforcement. Accordingly, the layer A with the greatest bulk density and with the reinforcement 16 ensures the strength of the bottom plate component G, give the layers B and C with the stepwise lower density, a good thermal insulation. Also in the bottom plate component G according to 4 In the area of the interfaces FA and FB as well as FB and FC form and material connection causing mixing zones M are present.

The according to 4 shown ceiling component D and according to 5 shown roof plate component DP differ from the bottom plate component G according to 4 basically not. However, the density of the reinforcement 16 designed differently according to the individual static conditions than the corresponding reinforcement 16 of the building board component G ( 4 ) and the ceiling tile component DP ( 5 ). Since the components D and DP otherwise largely correspond to the bottom plate component G, further explanations are unnecessary.

In the 6 and 7 Physical properties of the material according to the invention HLB (hollow lightweight concrete) are shown in comparison to other materials.

So is in 6 the thermal conductivity of various materials is represented as the ordinate lambda [W / mK] over the abscissa bulk density [kg / m ³ ].

With the material of the invention HLB are compared to the material lightweight concrete LB (concrete with air inclusions forming Elements, such as polystyrene and expanded clay), Lightweight bricks LHZ (lattice clay brick), cellular concrete PB (concrete with pore-forming agents in the form of aluminum and / or zinc powder) and Poroton PT (expanded clay roof tile).

Out 6 shows that it is possible with the material according to the invention HLB to achieve a very low thermal conductivity of about 0.05 W / mK. At a bulk density of about 1000 kg / m ³ , the material according to the invention HLB still has a relatively low thermal conductivity of 0.38 W / mK.

Out 7 It can be seen that the material according to the invention has a very high compressive strength of about 10.5 N / mm ² at the mentioned bulk density of 1000 kg / m ³ , with which a relatively low thermal conductivity of 0.38 W / mk is associated.

Finally draws the material of the invention HLB by a compared to the other aforementioned materials much larger bending and tensile strength.

Claims (22)

Component, in particular plate-like component (P) for use as a wall component (E), as a floor component (G), as a foundation component, as a roof component (DP), as a ceiling component (D), as a partition wall component, as a soundproofing wall component od. Like., Which at least two layers (A, B), each layer (A, B) containing cellulosic elements or cellulosic elements such as wood shavings, chips, shredded paper or the like, and wherein each layer (A, B) comprises cement as a binder and optionally contains additives, characterized in that each layer (A, B) substantially over the entire layer thickness (S) consists of a mixture of cellulosic elements or cellulosic elements of all fractions of the same grading curve that the cement evenly over the layer thickness (S ) is distributed, that the mutually facing adjacent layers (A, B) with their interfaces (FA, FB) are firmly connected to each other and that neighbors neigh arte layers (A, B) depending on the proportion of cement or depending on the degree of compaction have different densities. Component according to Claim 1, characterized that the adjacent layers (A, B) are in the range of their each other facing interfaces (FA, FB) penetrate, wherein the penetration area a one cohesive and interlocking Composite forming zone (M) represents. Component according to Claim 1 or according to Claim 2, characterized in that the layer (B) with the respective lower Density the thermal insulation function and the layer (A) with the respective larger bulk density the support function of the device (P, E, G, D, DP). Component according to one of claims 1 to 3, characterized in that the bulk density in addition is determinable by the density of the cellulosic elements or of the cellulosic elements. Component according to one of Claims 1 to 4, characterized that the gross density in addition Addition of mineral admixtures, e.g. by admixture of barium sulfate, can be determined. Component according to one of Claims 1 to 5, characterized that the degree of compaction by mechanical action, in particular by vibration, is determinable. Component according to one of Claims 1 to 5, characterized that the degree of compaction can be determined by adding pore formers is. Component according to Claim 7, characterized that the pore former from a reaction mixture of lime, water and metal powder exists. Component according to Claim 7, characterized the metal powder is aluminum powder or zinc powder. Component according to one of Claims 1 to 9, characterized that the cellulose elements or the cellulosic elements a mineralized surface exhibit. Component according to Claim 10, characterized that the surface the cellulose elements or the cellulosic elements by means of Water glass is mineralized. Component according to Claim 10, characterized that the surface the cellulose elements or the cellulosic elements by means of amorphous silica is mineralized. Component according to Claim 10, characterized that the surface the cellulose elements or the cellulosic elements by means of Lime milk or cement milk is mineralized. Component according to one of claims 1 to 13, characterized in that at least one layer, in particular the the supporting function of the device (P, E, G, D, DP) fulfilling layer (A), with reinforcing elements ( 16 ), such as with elongated and / or lattice or net-like reinforcing elements made of metal, plastic, glass fiber or carbon, is provided. Component according to one of claims 1 to 14, characterized in that at least one layer (C) line elements ( 15 ) for the passage of fluids and / or electricity. Component according to one of Claims 1 to 15, characterized that at least one layer of graphite elements, in particular graphite powder, contains. Component according to one of Claims 1 to 16, characterized that at least one layer (B) PCM (Phase Change Material) elements contains. Method for producing a component (P), in particular a plate-like component for use as a wall component (E), as a floor component (G), as a foundation component, as a roof component (DP), as a ceiling component (D), as a partition wall component, as a soundproof wall component od in which cellulosic elements or cellulosic elements, such as wood shavings, woodchips (shives), shredded paper or the like, cement, optionally additives and water, are introduced into a horizontally arranged mold, characterized in that for producing a first layer ( A) classifying the cellulosic elements and / or cellulosic elements with all fractions of a particular first grading curve by mixing the cellulosic elements or cellulosic elements with cement and water to form a mixture, 11 ), the mixture is shaken or subjected to vibration to increase the degree of compaction, whereupon a second layer (B) is prepared as a mixture containing cellulosic elements or cellulosic elements, as well as cement and water, corresponding to the grading curve of the first layer or other grading curve and that the second layer (B) is applied to the first layer (A). Method according to claim 18, characterized that the first layer (A) hardens or only partially hardened, before the second layer (B) is applied to the first layer (A) becomes. A method according to claim 18 or claim 19, characterized in that the mixture of the first layer (A) and / or the mixture of the second layer (B) a setting accelerator, such as. Water glass, we admitted. Component according to one of Claims 18 to 20, characterized in that the mixture of at least one layer (B) is a pore-forming agent added becomes. Method according to one of Claims 18 to 21, characterized that before the preparation of the mixture, the cellulose elements or the cellulosic elements to mineralize their surface in one intimate contact with milk of lime, cement milk, amorphous silicon dioxide or water glass and after hardening of the mineral surface of the Mixture be added.