DE3430473A1 - Composite moulding - Google Patents

Abstract

The invention relates to a composite moulding with a filling body which is provided on its surface with an outer layer. In order to achieve a very high stability, the filling body is formed by a cured matrix material which is pourable before curing and ferrosilicon particles embedded therein, at least 60 per cent by weight of the filling body being ferrosilicon particles.

Description

Composite molded body

The invention relates to a composite molded body with a filler body, which is provided with an outer layer on its surface.

Composite molded bodies are used nowadays for a wide variety of purposes z. B. plate-like shape, in which Q8e; externally applied layer (s) in Material to the externally desired properties such as corrosion protection, surface quality etc. are adapted and the inner packing, which gives the molded body its stability gives, covers to the outside, so that the packing without consideration can develop the desired external properties.

The present invention is based on the object of such To create composite molded body which is made from simple materials and corresponds to the highest stability requirements.

This object is achieved according to the invention in that the filler body of a hardened matrix mass which can be poured before hardening and therein embedded iron silicon particles is formed, at least 60 percent by weight of the filler body are iron silicon particles.

In a particularly simple and cheap way, the matrix mass of hydraulically set cement are formed.

A shaped body with such a filler body has an extremely high Compressive strength and breaking strength, with tests for a plate-shaped Composite body has shown a breaking strength of 300 - 342 N / mm2. This strength is retained even at low temperatures.

The density of the packing is expediently in the range between 5.0 utndi 6.4 g / cm3, so it is also very high.

A shear modulus of expediently 20,000 - 36,000 N / mm2 and a modulus of elasticity of up to 85,000 Achieve N / mm2.

The composite body according to the invention can thus preferably be there anywhere used where very high mechanical loads occur. There is one Corrosion of the iron silicon particles is not to be feared, since the packing is after is covered on the outside. Optionally, the iron silicon particles could be presented the production of the filling body also with a protective coating, for example Nickel plating or chrome plating.

A preferred field of application is the production of transport and / or storage containers for radioactive fuel elements of a nuclear power plant which even a fall from a height of several meters does not endanger the environment Damage to the container. In this case the container wall and optionally also the bottom and the lid of the container according to the present invention educated. The use of iron silicon particles is the further one The advantage that these are plastically deformable, so that for example at In the event of a container crash, a large part of the fall energy is due to plastic deformation is destroyed.

The iron silicon particles and thus the entire filler body (because of the adjacent distribution of the iron silicon particles hinders the Matrix mass hardly any heat transfer) also have a high thermal conductivity, which is also the case, for example, with the aforementioned containers for radioactive fuel elements is cheap. The fuel elements sitting in the interior of the container develop namely a large amount of heat that must be dissipated to the outside as quickly as possible. is If the container wall is a composite molded body according to the invention, this heat dissipation takes place quickly and safely through the container wall.

It goes without saying that this thermal conductivity property of the filler body also has a beneficial effect in other applications if it involves a rapid supply of heat or discharge by the respective shaped body arrives through.

As a material for the outer layer or for panel-like composite molded bodies of the two outer layers, steel is ideal. This is because, for example, since the composite molding according to the invention has a coefficient of thermal expansion, which is in the range of steel, so that regardless of the prevailing temperature a secure network is always guaranteed. The steel also hampers this if necessary desired heat transfer not.

It goes without saying that, depending on the use of the composite molding can also choose materials other than steel for the outer layer (s). So come for example also copper, aluminum, plastic (e.g. polyamide), asbestos, Graphite, Eternit, wood or rubber are possible. In the case of a plate-like composite molded body with two opposing outer layers, these can also consist of different Materials exist.

The layer structure also makes the production very easy respective shaped body with itself. The outer layers can be called, so to speak Formwork walls are used, between which the pourable matrix mass and the Can pour iron silicon particles. After the hardening of the matrix mass then lies the finished composite molding before doing any additional work.

Further examples of the use of the composite molding according to the invention are the production of safe walls, Armor plates, machine parts Including machine beds, engine parts, rollers, cylinders or pressure vessels.

All of these articles can be used as composite molded articles according to the present invention Invention be formed. There are no limits to the variety of uses.

To further increase the strength, it is provided that the iron silicon particles are irregularly shaped, suitably jagged. With such a figure the particles are hooked together, so to speak, and are therefore better engaged together.

Another useful measure is that the grain size of iron silicon particles varies based on the total weight of iron silicon particles the weight percent increases with increasing grain size. This means' that several subsets of iron silicon particles <-with different grain size are present, the weight of the respective subset with increasing grain size increases. The grain size can vary in the range from almost 0 to about 30-40 mm. In the case of a particularly favorable grain size distribution, the result is in percent by weight the iron silicon particle / grain size diagram lying on a parabolic curve Points.

The following grain size distribution is expediently available: Grain size 0.2 5 0.5 1.0 2.0 4.0 8.0 16.0 55.5 Weight percentage 2 - 3 4 - 5 6 - 7 8 - 9 11-12 15-17 23-24 26-28 the FeSi part! If an even higher thermal conductivity of the composite molding is desired, in addition to the iron-silicon particles, metal particles, advantageously made of copper, can be embedded in the matrix mass in the filler body. It has been found to be favorable for a fuel assembly container that the ratio of iron silicon particles to copper particles is approximately 5 in terms of weight.

In addition, steel fibers and / or synthetic fibers, e.g. polyamide fibers, which can be embedded in the matrix mass, which is mainly the mechanical Strength is beneficial.

The filler body can also stiffening anchors and / or stiffening frameworks and / or cavities and / or channels or pipelines opening out to the outside, for example for carrying out a cooling or heating medium, e.g. B. water, or electrical lines contain. Such an installation can, depending on the intended use of the composite molded body to get voted.

It was already mentioned above that the matrix mass of hydraulically set Cement can be formed. Since with such a matrix mass the strength of the water-cement value in the production of the matrix mass of the composite molding depends on the water / cement mixture to be used particularly favorable water-cement ratio selected. This water-cement value, i.e. H. The relationship the amount of water in kg to the amount of cement in kg is in the range of about 0.4-0.5, expediently at about 0.45.

The properties of the matrix mass are further optimized by that the slump of the water / cement mixture used in their manufacture is in the range of about 34-38 cm.

If required, lubricants can also be added to the matrix mass will.

Instead of set cement, the matrix mass can be used depending on the use of the composite molding also made of a solidified, previously flowable plastic or made of metal, in particular aluminum or copper.

An exemplary embodiment of the invention will now be described with reference to the drawing briefly described. The figures show: FIG. 1 a plate-shaped composite molding according to FIG of the invention in cross section; and FIG. 2 is a diagram showing that contained in claim 6 Table clearly shows.

The plate-shaped composite molding according to FIG. 1 consists of a middle packing 1 and two outer layers 2, 3, each on one of the surfaces of the packing are put on. Overall, the result is a layered one Structure, wherein the packing layer 1, as described, a plurality of iron silicon particles 4 contains irregular shape with different grain sizes, which in a matrix mass 5 are embedded. The two outer layers 2, 3 can be formed from steel plates However, other materials are also possible, as already described has been. Furthermore, in Fig. 1 is still contained in the packing and on the facing outer layer 3 of attached stiffening anchor 6 indicated. In the end a pipeline 7 extending through the filler body 1 is also shown.

As explained above, in a preferred embodiment several subsets of iron silicon particles with different grain sizes are present, whereby the weight of the respective subset increases with increasing grain size.

This is illustrated in FIG. 2, from which it can also be easily seen is that the table according to claim 6 corresponding points in this diagram lie roughly on a parabolic curve.

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Claims (20)

Composite molded body Claims 1. Composite molded body with a filler body, which is provided with an outer layer on its surface, characterized in that, that the filler body is made of a hardened matrix mass which can be poured before hardening and forming ferrous silicon particles embedded therein, wherein at least 60 Weight percent of the packing is iron silicon particles. 2. Composite molded body according to claim 1, characterized in that the iron silicon particles are irregularly shaped, suitably jagged. 3. Composite molded body according to claim 1 or 2, characterized in that that the grain size of the iron silicon particles varies, based on the total weight of iron silicon particles, the weight percent increases with increasing grain size. 4. Composite molded body according to claim 3, characterized in that the grain size varies in the range from almost 0 to about 30-40 mm. 5. Composite molded body according to claim 3 or 4, characterized in that that the weight percent of the iron silicon particles / grain size diagram on a Points lying in a parabola-like curve result (FIG. 2). 6. Composite molded body according to one of claims 3 to 5, characterized in that there is approximately the following grain size distribution of the iron silicon particles: Grain size 0.25 0.5 1.0 2.0 4.0 8.0 16.0 31.5 Weight percent of FeSi-parts 2 - 3 4 - 5 6 - 7 8 - 9 11-12 15-17 23-24 26-28 7. Composite molded body according to one of claims 1 to 6, characterized in that that the matrix mass is formed by hydraulically set cement. 8. In the production of the matrix mass of the composite molding according to Claim 7 to be used water / cement mixture, characterized in that the Water-cement ratio of the mixture, d. H. the ratio of the amount of water in kg to the amount of cement in kg in the range of about 0.4-0.5, expediently about 0.45. 9. During the production of the matrix mass of the composite molding after Claim 7 to be used water / cement mixture, characterized in that the The slump of the water / cement mixture is in the range of about 34-38 cm. 10. Composite molded body according to one of claims 1 to 6, characterized in that that the matrix mass consists of a solidified, previously flowable plastic. 11. Composite molded body according to one of claims 1 to 6, characterized in that that the matrix mass consists of metal, in particular aluminum or copper. 12. Composite molded body according to one of claims 1 to 11, characterized characterized in that the density of the packing is in the range between 5.0 and 6.4 g / cm3 lies. 13. Composite molded body according to one of claims 1 to 12, characterized characterized in that the packing has a shear modulus of 20,000 - 36,000 N / mm2. 14. Composite molded body according to one of claims 1 to 13, characterized characterized in that the modulus of elasticity of the packing is up to 85,000 N / mm2. 15. Composite molded body according to one of claims 1 to 14, characterized characterized in that in the packing also metal particles, expediently made of copper, in the matrix mass are embedded. 16. Composite molded body according to claim 15, characterized in that the ratio of iron silicon particles to Copper particles by weight is about 5. 17. Composite molded body according to one of claims 1 to 16, characterized characterized in that steel fibers and / or plastic fibers, for. B. Polyamide fibers in which the matrix mass is embedded. 18. Composite molded body according to one of claims 1 to 17, characterized characterized in that the filling body stiffening anchor and / or stiffening framework and / or cavities and / or channels or pipelines opening out to the outside, for example for passing through a cooling or heating medium, e.g. Contains water or electrical wiring. 19. Composite molded body according to one of claims 1 to 18, characterized characterized in that the outer layer (s) consists of steel or consist. 20. Use of the composite molded body according to one of claims 1 to 19 for the production of transport and / or storage containers for radioactive fuel elements of a nuclear power plant, vault walls, armor plates, machine parts, engine parts, Rollers, cylinders or pressure vessels.