NL2007415C2 - BUILDING ELEMENT. - Google Patents

Description

Short description: Building element.

DESCRIPTION

The invention relates to a building element, in particular an insulation panel constructed from two plate parts arranged at some distance from each other, as well as a core material arranged between the plate parts.

The invention further relates to a method for manufacturing such a building element.

Such building elements are generally known and are used in system construction for assembling or building wall parts, both as an inner wall or outer wall, and for assembling doors. In general, such building elements are composed of two plate parts which are situated at some distance from each other and provided with an intermediate space which in most cases is filled with a core material. The core material of such panels has a high strength and can therefore absorb many forces without the panel breaking, deforming or otherwise being damaged. Such compact panels are used for assembling outer walls, since they are very resistant to weather influences.

When assembling such a building element, spacers are provided between the two plate parts, whereafter the core material is added between the plate parts in the form of a curing foam. The use of spacers has a number of disadvantages. One of them is that the spacers act as a cold bridge, so that the insulation value of the building element is adversely affected. The use of a plurality of spacers also makes the manufacture of the building element cumbersome and expensive, and by loosening the connection between the spacers and the plate parts, the plate part can become unstable or even release. In addition, due to climatic influences such as shrinkage and expansion, the spacers and the plate parts can start to work relative to each other, which also adversely affects the quality, construction and service life of the building panel. This is because spacers often exhibit a different thermal and mechanical behavior than the panel parts.

The present invention has for its object to provide a solution for this purpose and for this purpose the structural element is characterized in that the plate parts 2 are connected to each other around their peripheral edge by means of a sealing material serving as a spacer.

This not only ensures a good seal, but also a stable building element with a long service life. By using a sealing material for sealing and assembling the building panel, which sealing material also functions as a mechanically loadable spacer, additional spacers can be dispensed with, which would otherwise adversely affect the quality, construction and service life of the building panel due to their different thermal and mechanical behavior. to influence.

More specifically, the sealing material is a sealing kit, whereby a good gas and vapor tightness of the building panel is also realized.

In another functional embodiment, the sealing material is a reactive hot melt material. Because the sealing material is arranged around the peripheral edge of the building element, good stability against deformation and damage is also realized.

According to a further embodiment, the hot-melt material is a moisture-reacting hot-melt material. As a result, a precisely controlled curing can be realized, while at the same time preventing moisture from entering into the building element.

In a preferred embodiment, the core material is made of an insulating material and may, for example, be a foam material. In another embodiment, the core material also comprises silica.

In order to realize a building element with a high insulation value, in a specific embodiment the core material is surrounded by a gas and vapor-tight enclosure by means of vacuum.

Thus, a building element with a high insulation value can be realized, which makes the building element very suitable for the construction of wall and facade structures, as well as doors.

In further exemplary embodiments, the plate parts can be light-transmitting and in particular made of glass.

In a further embodiment the building element is provided with sensor means, which measure the prevailing (under) pressure in the building element.

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The vacuum of the building element can hereby be checked in a simple and efficient manner, because the insulation value of the building element is partly determined by the vacuum that prevails in the building element and more particularly in the core material. If the vacuum of the building element / core material is affected and the prevailing pressure in the core material is below the standard, the insulation value of the building element can no longer be guaranteed. In this case, the building element must be replaced.

With the aid of pressure sensor means in the building element, the internal pressure in the building element or in the vacuum core material 10 can be determined at present. More specifically, the sensor means measure the prevailing (under) pressure in the core material.

The sensor means comprise at least one pressure sensor and optionally at least one temperature sensor. The temperature sensor enables the compensation to correct the measured underpressure on the basis of the (prevailing) instantaneous temperature in the building panel at that moment.

Furthermore, the sensor means are preferably wirelessly controllable and readable, which makes it possible to read out the building elements on site.

Due to the simple construction of a building element as described above, it is possible to manufacture it in different designs and dimensions. One can think here of insulation panels where the plate parts are designed in a responsible carrier which satisfies climatic properties such as glass. Depending on the application and the required strength, metals such as steel or aluminum can also be implemented.

The insulating material used as core material can for instance be an insulating foam or a mineral wool.

The invention also relates to a method for manufacturing a building element, in particular a building element according to the invention, comprising the steps of: i) providing a first plate part; ii) applying a core material to the first plate member; iii) placing a second plate member on the first plate member and the core material applied in step ii); Iv) applying a sealing material serving as a spacer around the core material and along the peripheries of the plate parts; v) curing the sealing material under the influence of an external stimulus.

The invention will be further elucidated with reference to the drawings, which drawing successively shows.

Figures 1 to 4 show different views and exemplary embodiments of an insulation panel according to the invention, also showing the method according to the invention.

For a better understanding of the invention, the corresponding parts will be designated in the following description of the figures with the same reference numeral. Figure 1 shows a first step of a method for manufacturing a building element according to the invention as well as such a building element.

Reference numeral 11 refers to a first plate part on which core material 13 is applied. Core material 13 is preferably made from a block of insulating material, such as mineral wool or an insulating foam that has been brought into a certain shape. In another embodiment, the core material also comprises silica.

In order to realize a building element 10 with a high insulation value, the core material 13 is surrounded by a vacuum (not shown) gas-tight and vapor-tight envelope. A building element 10 is thus realized with a high insulation value, which makes the building element very suitable for the construction of wall and facade structures and doors. As is clearly shown in Figure 1, the peripheral edge 11 'of the first plate part 11 is free.

A further step according to the method according to the invention as shown in figure 2 is provided over this relatively protruding peripheral edge and against the core material 13 a sealing material 15 which functions as a flexible gas-tight and vapor-tight seal, after a second plate part 12 has been shown as shown in figure 3. the core material 13 and the sealing material 15 are placed.

The sealing material is preferably a gas-tight and vapor-tight sealing material.

Because the sealing material 15 hardens, a good gas-tight and vapor-tight seal is obtained which, moreover, is dimensionally stable and resistant to deformations that can occur under different weather conditions.

By using only a sealing material, the use of separate spacers between the core material 13 and the two plate parts 11-12 is not necessary, which not only leads to a simplified design and manufacturing process, but moreover results in a building element with a higher insulation value. In addition, the use of a sealing material makes it possible to finish the building element in an airtight manner, so that no pressure differences between the building element and the outside environment can occur, which also extends the service life of the building element considerably and guarantees a good insulation value.

Spacers are superfluous in the manufacture of such a building element, because the sealing material, due to its material properties and manner of application (around the peripheral edge and against the core material), acts as a spacer and thus also ensures a stable and form-retaining construction, which is resistant is against distortion and damage.

An additional advantage of such a building element and in particular the method for manufacturing such a building element is that building panels with considerably smaller thicknesses can be manufactured while possessing a high insulation value and also score high in the field of vapor density, fire resistance, sound resistance and impact force. .

Due to the special construction of these panels with vacuum, a lower construction depth is achieved which also leads to a considerable weight and volume reduction. With a comparable insulation value, the installation depth will result in a considerable thickness reduction.

Multiple building elements according to the invention can thus combined form a wall part wherein the different building elements with their sealing edges can be placed against each other and can be manufactured into one coherent construction.

In addition to the higher insulation value, sound resistance and fire resistance, lighter wall constructions can also be built up due to the smaller thickness while maintaining the same mechanical properties, such as strength and distortion.

The plate parts can be made of glass, PVC, HPL, aluminum 6 or steel. These are light types of material which, however, have great strength. Thus, the building elements made of such materials can absorb many forces without the panels breaking, deforming or otherwise being damaged.

As clearly shown in Figure 3, the second plate part is here on the core material 13 and the sealing material 12 arranged along the peripheral edge 11 '-12' in order to realize an insulating panel whose space between the two plate parts 11-12 is completely filled by means of a core material (insulating foam or, for example, mineral wool, preferably by means of a vacuum surrounded by a foil covering). The foil wrapper can be a gas-tight and vapor-tight foil wrapper, and / or, for example, a foil provided with an aluminum cover layer.

The sealing material or kit can be a reactive hot-melt material, but other sealing materials can also be used, such as structural sealant, polyurethane or MS polymer.

Although not shown, in a further embodiment the building element 10 can be provided with sensor means, which measure the prevailing (under) pressure in the building element. The vacuum of the building element can hereby be checked in a simple and efficient manner (ex works or on site after installation), since the insulation value of the building element is partly determined by the vacuum which is present in the building element and more particularly in the core material prevails. If the vacuum of the building element / core material 12 is affected and the prevailing pressure in the building element / core material exceeds a desired standard pressure, the insulation value of the building element 10 can no longer be guaranteed. In this case, the building element must be replaced.

With the aid of pressure sensor means, the inside pressure in the vacuum core material can be determined at present. More specifically, the sensor means measure the prevailing (under) pressure in the core material 12. The sensor means may preferably be arranged in the core material.

The sensor means comprise at least one pressure sensor and optionally at least one temperature sensor. The temperature sensor makes it possible to compensate for the measured prevailing underpressure on the basis of the currently measured temperature in the building panel.

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Furthermore, the sensor means are preferably wirelessly controllable and readable (for example by means of RFID), which makes it possible to read the building elements on site. The read-out data values can be stored with suitable receiving equipment for further data analysis, in particular to detect a trend in the vacuum measured values measured over time. A slowly decreasing vacuum, for example due to a leaking sealing material, can thus be detected by a trend analysis of the pressure values measured over time. In addition to a quality guarantee, it is also easy to detect and replace defective, leaking building elements with a reduced insulation capacity.

Claims (16)

1. Construction element, in particular an insulation panel built up of two plate parts arranged at some distance from each other, as well as a core material arranged between the plate parts, wherein the plate parts are connected to each other around their peripheral edge by means of a sealing material serving as a spacer. A building element according to claim 1, characterized in that the sealing material is an edge sealing system or sealing kit. Building component according to claim 1 or 2, characterized in that the sealing material is a reactive hot-melt material Building component according to claim 3, characterized in that the hot-melt material is a moisture-reacting hot-melt material. 5. Building element according to one or more of the preceding claims, characterized in that the core material is an insulating material. Building component according to claim 5, characterized in that the core material also comprises silica. 7. Building element according to one or more of the preceding claims, characterized in that the core material is surrounded by an envelope by means of a vacuum. 8. Building element as claimed in claim 7, characterized in that the envelope is a foil envelope provided with an aluminum cover layer. 9. Building element according to one or more of the preceding claims, characterized in that the plate parts are made of glass, PVC, HPL, aluminum or steel. 10. Building element according to one or more of the preceding claims, characterized in that the building element is provided with sensor means, which measure the prevailing (under) pressure in the building element. 11. Building element according to claim 10, characterized in that the sensor means measure the prevailing (under) pressure in the core material. 12. Building element as claimed in claim 10 or 11, characterized in that the sensor means are arranged in the core material. Building component as claimed in one or more of the claims 10-12, characterized in that the sensor means comprise at least one pressure sensor. Building component as claimed in one or more of the claims 10-13, characterized in that the sensor means comprise at least one temperature sensor for compensating for the measured prevailing pressure for the current temperature in the building panel. Building component as claimed in one or more of the claims 10-14, characterized in that the sensor means can be controlled and read out wirelessly. 16. Method for manufacturing a building element, in particular an insulation panel according to one or more of the preceding claims, comprising the steps of: i) providing a first plate part; ii) applying a core material to the first plate member; iii) placing a second plate member on the first plate member and the core material applied in step ii); Iv) applying a sealing material serving as a spacer around the core material and along the peripheries of the plate parts; v) curing the sealing material under the influence of an external stimulus. 20