NL2009467C2 - CONSTRUCTION ELEMENT AND METHOD FOR MANUFACTURING SUCH A CONSTRUCTION ELEMENT. - Google Patents

Description

CONSTRUCTION ELEMENT AND METHOD FOR MANUFACTURING SUCH CONSTRUCTION ELEMENT

The invention relates to a construction element which contains a mixture of at least the following raw materials: a binder; - a basic material, and 10 - water.

Such a construction element is known per se and is a construction element made of concrete. Such a concrete construction element can have any desired shape and be suitable for various applications.

It is an object of the invention to improve the concrete construction element known per se.

To this end, the mixture further comprises: - a phase change material, and - a heat conducting material with a heat conductivity coefficient of at least 75 W / m * K in an amount such that the structural element has a heat conductivity coefficient of at least 5 W / m * K.

The phase change material, also referred to as a phase change material (PCM), is a material that undergoes a phase change at a certain change temperature or at a certain change temperature temperature gap, for example between solid and liquid, and thereby a relatively large amount of (latent) energy can save 30 or release. By including this material in the construction element of the type mentioned in the preamble, the construction element can store a relatively large amount of heat at temperatures above the cover temperature or the cover temperature trajeet, because the phase change material absorbs the heat and stores it as latent energy at undergoing the phase change from solid to liquid. The heat stored in the structural element 5 can be released at temperatures below the cover temperature or the cover temperature range because the phase change material exhibits an opposite phase change from liquid to solid and thereby releases the latent energy. The specific heat of the construction element according to the invention is at least 10 kJ / kg-K. Usually, concrete has a specific heat of about 0.85 kJ / kg * K.

Because the construction element according to the invention comprises a heat conducting material with a heat conductivity coefficient of at least 75 W / m-K, the construction element according to the invention has a relatively high thermal conductivity of at least 5 W / ncK. Usually, concrete has a heat conductivity coefficient of between 1 and 2 W / m * K. Due to the relatively high thermal conductivity of the construction element according to the invention, relatively much thermal energy can be stored or released in the construction element per unit time.

By using both the phase change material and the heat conducting material in the construction element according to the invention, a construction element is provided which can efficiently absorb and / or release and / or release a considerable amount of thermal energy.

The construction element according to the invention can for instance be used as a pavement for infrastructural purposes. Such a pavement is understood to mean any pavement over which traffic moves, such as, but not limited to, roads, bridges, parking areas, runways, footpaths, cycle paths, etc. The construction element can be used as closed pavement, but also as separate elements in the form of, for example, clinkers, tiles, stones, etc. Such a construction element can be used efficiently in both relatively warm and relatively cold areas.

For example, in areas where the temperature can drop below freezing point, the paving may contain a phase change material with a cover temperature or cover temperature range of about 1 ° C - 2 ° C, so that the hardening can store thermal energy therein and at temperatures above about 2 ° C and at temperatures below about 0 ° C can release the energy stored therein, such that the paving can be efficiently kept frost-free. This can prevent or at least reduce the hardening caused by freezing, so that fewer accidents occur. Also, this means that no or at least fewer other means have to be used to prevent the hardening from freezing, for instance less salt has to be sprinkled, which is cost-saving and can also be good for the environment.

It has been found by the applicant that by applying both the phase change material and the heat conduction material a hardening is obtained which can be kept frost-free for more than 20 days and / or nights at an ambient temperature which is at least lower than 0 ° C at least overnight . Without the heat conducting material and with only the phase change material, the hardening can remain frost-free for approximately 1 day and / or night at an ambient temperature which is at least lower than 0 ° C at least at night. The concrete construction element known per se cannot be kept frost-free without additives and / or additives and / or other aids.

For example, in relatively warm areas where the temperature can rise above 30 ° C, the paving 5 can contain a phase change material with a cover temperature or cover temperature range of approximately 30 ° C, so that the hardening can store thermal energy therein and above 30 ° C can release the energy stored therein at temperatures below approximately 30 ° C. Hereby it can be prevented or at least reduced that the pavement becomes too hot, which can otherwise cause ripples in the pavement. This allows the quality of the paving to be maintained for a longer period of time.

In an embodiment of the construction element according to the invention, the phase change material may, for example, contain paraffin (C n H 2 n + 2) and / or salt hydrates (M 2 H 2 O), which materials have both been found to be suitable for inclusion in the construction element according to the invention.

In another embodiment of the construction element according to the invention, the phase change material can have a cover temperature or cover temperature range that is in the range of 0 ° C - 4 0 ° C.

In particular, a cover temperature or cover temperature range of about 1 - 2 ° C or about 30 ° C have been found to be suitable for relatively cold or relatively warm areas, as explained above. Depending on the desired application, a phase change material can be selected with the desired change temperature or change temperature threshold.

Practically, the phase change material can be a granulate. A granular phase-change material offers the advantage that the phase-change material can be mixed well with the other materials of the structural element, so that the phase-change material is arranged dispersed throughout the structural element, and so that the structural element has a more or less homogeneous specific heat shows. The granulate particles can have a dimension that is between 1 and 8 mm, which dimension substantially corresponds to the dimension of sand, or a dimension that is between 10 and 2.5 cm, which dimension substantially corresponds to the dimension of gravel. In this way a part of the base material can be replaced by the phase change material.

In an embodiment of the construction element 15 according to the invention, the heat-conducting material is selected from the group comprising graphite, silicon, diamond, carbon, metals with a heat-conducting coefficient of at least 75 W / mK, for example zinc, copper, aluminum, and mixtures of these materials.

Such materials have a relatively high heat conductivity coefficient, so that they can be accommodated with a limited volume in the construction element in order to provide the construction element with the desired heat conductivity coefficient of at least 5 W / m-K. In particular, graphite has a heat conductivity coefficient of 160 W / mK, silicon a heat conductivity coefficient of 148 W / mK, diamond a heat conductivity coefficient of at least 900 W / mK, aluminum a heat conductivity coefficient of 237 W / mK, and 30 carbon a heat conductivity coefficient of 140 W / mK mK.

The applicant has found that graphite and silicon in particular are suitable heat-conducting materials.

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Practically, the heat conducting material can be a granulate or powder. A granular or powdered heat-conducting material offers the advantage that the heat-conducting material can be easily mixed with the other materials of the construction element, so that the heat-conducting material is arranged dispersed throughout the construction element, and so that the construction element has a more or less homogeneous heat-conducting coefficient shows.

The binder can for example be a cement.

The base material can be selected from the group comprising sand, gravel, crushed stone, and mixtures thereof.

As described above, the phase change material replaces part of the base material, wherein depending on the size of the phase change material, the sand and / or the gravel and / or crushed stone can be replaced.

The applicant has found that with a correct mixing ratio of the different materials, the construction element according to the invention has a compressive strength of at least 5 MPa after 28 days, which compressive strength is comparable to the compressive strength of the concrete construction element known per se.

For example, the proportions of the different materials in the construction element are such that the percentage of binder is 5-15 volume percent, the percentage of base material is 40 - 70 volume percent, the percentage of water is 5-10 volume percent, the percentage of phase change material 20 - 40 volume percentage and the percentage of heat conducting material is 2-4 volume percent.

The invention also relates to a method for manufacturing a construction element as described above, comprising the steps of: a) providing the following raw materials: a binder; - a basic material; - water; 5 - a phase change material, and - a heat conduction material with a heat conduction coefficient of at least 75 W / m-K; b) mixing the raw materials provided in step (a), and c) allowing the mixture formed in step (b) to harden to form the structural element, wherein in step (a) the heat-conducting material is placed in such a way amount is provided that the structural element has a heat conductivity coefficient of at least 5 W / 15 m · K.

In an embodiment of the method according to the invention, the method further comprises the step to be carried out prior to step (c): d) pouring the mixture formed in step (b) into a formwork.

By pouring the mixture formed in step (b) into a formwork, the structural element can be given any desired shape because the structural element takes the form of the formwork. The pouring of the concrete can take place both at the final construction site and, for example, in a factory, the construction element being a so-called prefab construction element.

Optionally, in step (d), a reinforcement can be arranged in the formwork, such that after hardening a reinforced structural element is obtained.

In another embodiment of the method according to the invention, the phase change material contains paraffin and / or salt hydrates.

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In yet another embodiment of the method according to the invention, the phase change material has a change temperature or change temperature range in the range of 0 ° C - 40 ° C.

Practically, the phase change material is a granulate, such that it can be easily mixed with the other materials of the structural element. In this way a construction element with more or less homogeneous properties is obtained.

The heat-conducting material is for example selected from the group comprising graphite, silicon, diamond, aluminum, carbon, and mixtures thereof, which materials exhibit a relatively high heat-conducting efficiency.

In practical terms, the heat-conducting material can be a granulate or powder such that it can be easily mixed with the other materials of the structural element. In this way a construction element with more or less homogeneous properties is obtained.

The invention is not limited to the described embodiments, but also extends to variants within the scope of the appended claims.

Claims (15)

A construction element comprising a mixture of at least the following raw materials: 5. a binder; - a base material, and - water, characterized in that the mixture further comprises: - a phase change material, and 10. a heat conducting material with a heat conductivity coefficient of at least 75 W / m * K in such an amount that the structural element has a heat conductivity coefficient of at least 5 W / mK. 15 Construction element according to claim 1, wherein the phase change material contains paraffin and / or salt hydrates. A construction element according to claim 1 or 2, wherein the phase change material has a cover temperature or cover temperature range that is in the range of 0 ° C - 40 ° C. A construction element according to any one of the preceding claims, wherein the phase change material is a granulate. 5. A construction element according to any one of the preceding claims, wherein the heat-conducting material is selected from the group comprising graphite, silicon, diamond, carbon, metals with a heat-conducting coefficient of at least 75 W / mK, for example zinc, copper, aluminum, and mixtures of these materials. 6. A construction element according to any one of the preceding claims, wherein the binder is a cement. 7. Construction element as claimed in any of the foregoing claims, wherein the base material is selected from the group comprising sand, gravel, crushed stone, and mixtures thereof. A construction element according to any one of the preceding claims, wherein the percentage of binder is 5-15 volume percent, the percentage of base material is 40 - 15 volume percent, the percentage of water is 5-10 volume percent, the percentage of phase change material is 20 - 40 volume percent and percentage of heat conducting material is 2-4 volume percent. 20 9. Construction element as claimed in any of the foregoing claims, wherein the construction element is intended and adapted to form at least a part of a pavement for infrastructural purposes. 25 A method of manufacturing a structural element according to any of claims 1-9, comprising the steps of: a) providing the following raw materials: 30. a binder; - a basic material; - water; - a phase change material, and - a heat conduction material with a heat conduction coefficient of at least 75 W / m-K; b) mixing the raw materials provided in step (a), and c) allowing the mixture formed in step (b) to harden to form the structural element, wherein in step (a) the heat conducting material is placed in such a amount is provided that the structural element has a heat conductivity coefficient of at least 5 W / 10 m · K. 11. A method according to claim 10, further comprising the step to be performed prior to step (c): d) pouring the mixture formed in step (b) into a formwork. The method of claim 10 or 11, wherein the phase change material contains paraffin and / or salt hydrates. 20 The method of any one of claims 10 to 12, wherein the phase change material has a cover temperature or cover temperature range in the range of 0 ° C - 40 ° C. 25 The method of any one of claims 10 to 13, wherein the phase change material is a granulate. 15. A method according to any one of claims 10-14, wherein the heat-conducting material is selected from the group comprising graphite, silicon, diamond, aluminum, carbon, and mixtures thereof.