NL2025202B1 - CONSTRUCTION SYSTEM - Google Patents

Abstract

L Construction system comprising several columns arranged on a substrate and panels arranged between adjacent columns, with the special feature that the columns are made of a cellulosic material and are of the same shape, each column having a U-shaped cross-section with two parallel legs and one in between base, and wherein the legs of the U-shaped cross-section are bent to form grooves extending in the longitudinal direction of each column. The invention also relates to said column as such for use in a construction system.

Description

CONSTRUCTION SYSTEM The invention relates to a construction system, such as a wall system, comprising several columns arranged on a substrate and panels arranged between adjacent columns 53. Such systems are suitable for creating, for example, walls, ceilings, floors, and other surfaces. Such a construction system is generally known, for instance as a wall system. In the known system use is made of columns or posts to be arranged on a substrate, such as a floor, which are provided with panels, for instance of plasterboard. The columns made of metal have a U-shaped or C-shaped cross-section against which the panels are fastened by means of screws. As an alternative, columns, or posts, made of wood can also be used, which are generally rectangular and solid in design.

A drawback of the known construction system is that its fire resistance falls short in practice. In particular, it has been found in practice that the columns of the known system collapse {too} quickly in the event of a fire, so that their resistance to fire breakdown {flames pass through the system} does not meet increasingly higher safety requirements. More particularly, the screws in the known system appear to conduct the resulting heat very well in the event of a fire, which leads to heating of the relevant plaster panel and the relevant leg (flange) of the U-shaped (or C-shaped) cross-section. of the column in question. As a result, its U-shaped cross-section warps (bi-metal effect) and the plaster panel splashes off. Finally, the components of the known system are either too light to have sufficient structural strength {which must be comparable to a so-called "metal stud wall"} or too heavy to be easily transported and applied. The object of the invention, among other objects, is to overcome the above-mentioned drawbacks of the prior art, i.e. to provide a construction system with columns and panels which is fireproof and dimensionally stable, inter alia in the sense that the columns thereof and greater resistance to fire penetration. Furthermore, according to the invention, the columns and the panels should be sturdy, yet light in weight, whereby the columns and panels can be easily manufactured, processed, transported and applied, and where the system is able to withstand high forces applied thereto,

To this end, a construction system of the type mentioned in the preamble according to the invention has the special feature that the columns are made of a cellulosic material and are mutually identical, each column having a U-shaped cross-section with two parallel legs and a base located between them. and wherein the legs of the U-shaped cross-section are turned (inwardly) to form grooves extending in the longitudinal direction of each column, each groove being therefore bounded by one of the legs of the U-shaped cross-section and its flanged portion thereof . Preferably, a support material and/or an insulating material is included in the grooves. The support material serves to efficiently and firmly screw the panels, such as wall tiles, onto the columns. The support material and the insulation material ensure that the columns remain intact for longer in the event of a fire, without the integrity of the columns being adversely affected in the event of fire. It is preferred that the support material and/or the insulation material is/are slat-shaped. so that the slats can be mounted in the grooves. If the backing material is lined in the grooves. the support material also functions as a reinforcing material. The construction system according to the invention has a durable composition, is easy to recycle, can be removed from soot plaster in one waste stream, and can be easily mounted. In particular, the system reduces CO‚ emissions compared to steel profiles, and can be recycled in the existing recycling streams for waste paper. The system also provides better acoustic insulation, has less influence on wireless signals, such as WiFi signals, and does not require grounding. Furthermore, it has smaller tolerances compared to existing alternatives. Finally, the system requires less material compared to existing alternatives in order to achieve equivalent constructive performance, whereby the material is also produced from biological material in an ecological way.

The columns of the construction system according to the invention are also referred to as "paper stud profiles".

In contrast to metal columns (also called “metalstud-proficles”™), paper-stud profiles do not warp excessively when heated. Fire tests have shown that a wall constructed with paper stud profiles, provided with a single plasterboard on both sides, is longer dimensionally stable than a wall provided with metal stud profiles. Paperstud profiles transmit less sound and, unlike metal, have no effect whatsoever on wireless signals.

Paper stud profiles are not electrically conductive, which means that they do not need to be grounded (in medical environments, for example). Finally, the manufacture of a cellulose profile requires less energy compared to an equivalent metal profile. Paper stud profiles are exceptionally light, can easily be shortened and processed dust-free, 53 have no toxic substances and no sharp edges, making the product very suitable for professional processing as well as for processing by private individuals with regard to legislation on working conditions.

Paperstud profiles are even easier to work with than wood. They are lighter, can be cut unlike wood, and an equivalent constructive result can be achieved with less material. Paperstud profiles transmit less sound than wooden studs, which promotes the acoustic isolation values between rams. The profiles are also more compact in transport. Paperstud profiles have minimal dimensional tolerances. Where solid wood is prone to warping and twisting, paper studs are straight.

[5 Paperstud profiles are “bio-based”. This means that the (cellulose) materialization is ecological and composts in a short period of time under regular natural conditions. Cellulose is also easy to recycle and thus functions as a raw material after use for other products in which cellulose is processed. Paperstud profiles can therefore be used several times as an element and as a raw material, making them an excellent fit for the purpose of a circular economy where waste and scrap is avoided. Paperstud profiles can be provided with coating material in various ways. When used vertically, they act as load-bearing structures for wall cladding and when used horizontally or diagonally, they serve as ceiling, roof or floor supports, for example. Material can be stuck to the profiles using glue or sealant. Another possibility is to use (double-sided) tape to make a connection. The profiles can optionally be provided with screwable strips, so that the material can also be screwed onto the profiles. Furthermore, it is possible to work with semi-permanent fastening means such as Velcro tape, zippers, binders, clips, clamps, coupling strips, or other semi-permanent fastening means known to the skilled person. Paperstud profiles have cellulose as the main component. Due to their absorbent capacity, the profiles can be impregnated excellently in order to increase the functional performance, such as increased fire resistance, reduction of smoke development during ignition. increased moisture resistance and constructive reinforcement of the profiles. Preferably, free ends of the bent legs of the U-shaped cross-section extend to the base thereof. More specifically, these free ends are glued to the base. The grooves are then each defined by one of the legs of the U-shaped cross-section, its flanged portion thereof, and the base of the U-shaped cross-section. Each groove then forms, as it were, a tube or channel with a triangular cross-section. The bent portion of each of the legs of the U-shaped cross-section therefore extends slenderly, i.e., at an obtuse angle to the base, thereby increasing rigidity. After all, the effective width of the base is then smaller.

It is noted that the panels are preferably manufactured from a plate material. In a preferred variant, the columns are arranged on the substrate 13 at a fixed mutual distance of 60 cm. If a greater bending stiffness is required, this mutual distance is 30 or 40 cm.

In a preferred embodiment of a construction system according to the invention, each column is manufactured from one blank. The blank is in particular provided with an elongate main panel, as well as elongate side panels arranged on either side of the main panel, wherein the side panels can be hinged relative to the main panel along a first fold line. The first fold line is preferably a single fold line, which is designed, for example, as a score line or perforation line.

In a further preferred embodiment of a construction system according to the invention, each side panel is connected to an elongate wing panel at a longitudinal edge thereof remote from the main panel, wherein the wing panel can be hinged relative to the side panel along a second fold line. In particular, the second fold line is a double fold line, for example it is formed by a double row line or double perforated line. In particular, the distance between the spaced fold lines (Le. double fold line) in the panel is then between 1.3 and 3 times the thickness of the blank, preferably approximately 2 times the thickness of the blank. Preferably, the first fold lines and the second fold lines are parallel to each other.

In a further preferred embodiment of a construction system according to the invention, the panels are arranged on the outside of the legs of the U-shaped cross-section. In this case, the panels are preferably screwed or glued to the outside of the legs of the U-shaped cross-section. In a further preferred embodiment of a construction system according to the invention, the 53 panels are made of a heat-insulating and/or sound-insulating material. The panels are preferably formed by plasterboards. In another preferred variant, the panels are made of Fermacell (a mixture of gypsum and paper fibres) or of magnesium-reinforced glass fiber or fire-resistant chipboard or fire-resistant MDF (medium density fireboard, 1st. wood fibers connected by resin}.

16 In a further preferred embodiment of a construction system in accordance with the invention, the columns are made of paper or cardboard, preferably of several cardboard layers glued together, preferably of so-called "EB quality". The cardboard is preferably built up of five layers of cardboard, namely a first corrugated cardboard layer and a second corrugated cardboard layer with a flat layer therebetween, the first and second corrugated cardboard layers being further provided on their outer sides with a flat cardboard layer. The first corrugated board layer has a corrugation height of preferably 2.5 mm, while the second corrugated board layer has a corrugation height of preferably 1.5 mm. The present construction system is eminently suitable for use in hospitals, since no use is made of metal, or in offices, since no use is made of materials that can disrupt wireless signals, for example for e-mail traffic and telephony. In particular, a groove with an at least substantially V-shaped cross-section is provided at a predetermined fold line, the groove extending through the cardboard layers up to the flat cardboard layer (ie outer layer) in order to form a hinge in the outer layer. for pivoting the side panels relative to the main panel and the wing panels relative to the side panels. This ensures that only the outer layer forms a hinge, while no other material is present on site. The panel can therefore easily bend in situ. Optionally, the outer layer is weakened at the location of the predetermined bend line.

In a further preferred embodiment of a construction system according to the invention, holes are provided in the base for guiding utility lines and/or pipes therethrough. The invention also relates to a column as such for use in a construction system according to the invention, wherein the column is made of a cellulosic material, the column has a U-shaped cross-section with two parallel legs and a base located therebetween, and wherein the legs of the U-shaped cross-section are bent to form grooves extending in the longitudinal direction of each column. The invention will be further elucidated with reference to the figures shown in the drawing, in which figures I and 2 represent a schematic and perspective view of a cardboard blank for the manufacture of a column in a precursor variant of a construction system according to the invention, wherein the blank is viewed from a wedge-folded (“flat”) state (Figure 1} can be folded via a partially folded state (Figure 2} to a fully folded state {Figure 3); — Figure 3 provides a perspective and schematic view of a U-shaped column from the blank of figures 1 and 2, wherein a jat-shaped support material is slid into the grooves formed, — figure 4 corresponds to figure 3, except that holes for utility pipes are also provided in the base of the L-shape, and — figure § shows a perspective and schematic view of the columns and {wall} panels of figures 1, 2, 3 and 4, but now in mounted condition. Shown from which a column 1 can be manufactured by folding along different folding lines F1, F2 in the longitudinal direction of the blank P {corresponding to the longitudinal direction of the column 1} manufactured therefrom. Figure 1 shows the unfolded or “flat” condition of the blank P. In the flat condition, several blanks P can be stacked easily and transported efficiently, as there is virtually no empty space between the multiple blanks.

The blank P consists of a cellulose-containing material, such as cardboard. The material can consist of several layers, which are preferably glued together. In the present example from Figure 1, the cardboard consists of at least two outer flat cardboard layers with a core layer of profiled cardboard in between. The core of profiled cardboard provides the blank P with the necessary strength without having to add significant weight. For example, the profile of the paperboard is corrugated, with the ridges of the corrugations preferably pointed to create triangular volumes between the outer flat paperboard layers. Such a triangular shape provides strength and some thickness for the cardboard,

without significant weight gain. The volumes that are created in the cardboard ensure that stagnant fumes can be contained therein, as a result of which the cardboard has excellent insulating functionality.

53 The blank B ut Figure | is divided into a main panel P1, two side panels P2, located on either side of the main panel P1, and two wing panels P3 which extend outwardly from a longitudinal side of each side panel P2 remote from the main panel P1. Folding lines F1, F2 are arranged between the individual panels P1, P2, B3, so that the blank P can be folded on the fold lines F1, F2 tc. Between the main panel P1 and the side panels PZ there are single fold lines F1, and between the side panels P2 and the wing panels P3 there are double fold lines F2. A double fold line, such as fold line F2, comprises two parallel single fold lines arranged at some distance from each other. A double fold line is advantageous when the fold to be made has a fold of more than approximately 90°. The double fold, as to be made between the side panels P2 and wing panels P3 [3] essentially comprises two consecutive single folds of approximately 90°, effectively obtaining a fold of approximately 180°. The single fold lines F1 and double fold lines F2 extend substantially parallel in the longitudinal direction of the piano P.

Figure 2 shows a partly folded-up position of the blank P, wherein the blank P is located between the flat position and the final position. In the final position, the blank P forms the column 1 according to the invention. In the intermediate state shown, some features of column 1 can already be recognized. The main panel P1 forms the base 3 of the column 1, and the side panels P2 and wing panels P3 together form the legs 4 of the column 1. The legs 4 and the base 3 together form a U-shaped profile in the final condition, as can be seen in the following figures.

Due to the double folding line F2 between the wing panels P3 and the side panels P2, a longitudinally extending groove 5 is created in the central position, being a space formed in a leg 4 of the column 1 between the double folding line F2, the base 3, and the side panel P2 and wing panel P3 of the leg 4. The folding lines F1, F2 provide the column 1 with the necessary strength against bulging, so that it functions as a sturdy construction clement. The groove 5 can also provide an insulating function, since it can contain stagnant air. The double folds F2 1s in the figures are somewhat exaggerated for clarity. In practice, the two fold lines of the double fold sheet F2 are preferably relatively close to each other, so that the groove 51 has a substantially triangular cross-section. However, it is also possible to choose the distance between the two fold lines of the double fold line FZ such that a groove 5 with rectangular cross-section or even with a trapezoidal cross-section is obtained.

In Figure 3, the final state, te. fully folded-up state, shown of the blank P, whereby it forms the column 1. The column 1 comprises a base 3 and two legs 4 extending parallel to each other. The base 3 and the legs 4 thereby form a substantially U-shaped angular profile, or C-shaped profile. The groove 5 has a triangular cross section which reduces the effective width of the base 3 . As a result, the bending strength of the column 1 is improved. The longitudinal edges 10 {see Figures 1 and 2} of the wing panels P3 are preferably in contact with the base 3, 1.0. the main panel P1, 19 is the emd state. The longitudinal edges 19 extend in the longitudinal direction of the column 1, and may be joined to the base 3 for further reinforcing the column 1. As shown in Figure 3, a reinforcing material 6 is provided in the groove 5, which is slat-shaped and con- lenght. which substantially corresponds to the length of the column 1, so that the reinforcing material 6 at least substantially fills the groove when it is completely fitted [3]. In Figure 3 1s the reinforcing material is only partly applied in one of the grooves

5. The reinforcement 6 can optionally be glued to the inner surface of the groove 5. The reinforcement © provides the column 1 with additional strength. Also, the reinforcing material 6 may have insulating, fire-resistant, fire-retardant, smoke-developing, mitigating, or other useful characteristics.

Figure 4 shows the column 1 from a perspective bottom view. In Figure 4, both grooves 5 of the column 1 are now provided with reinforcing material 6. The column 1 shown is therefore ready for use as a construction element. Furthermore, holes 7 are provided in the base 3 of the column 1 for guiding utility lines and/or pipes (not shown) therethrough. One can think of electricity cables or pipes, water pipes, gas pipes, heating cables, telephone cables, heating pipes, fiber optic cables. etcetera. The column 1 according to Figure 4 comprises two rounded rectangular holes 7. The column | may also include another number of holes 7, or even no holes 7 at all. The holes 7 can also have a different shape, such as circular, square, star-shaped, ef cetera. Also, a hole 7 can be arranged in such a way that flanges {not shown} are formed thereby, which can function as support element for cables, and other utility pipes and /or —tubes. Figure 5 shows an embodiment of a construction system according to the invention. The construction system comprises columns 1. as described above, front panels 27 and rear panels 27°, such as wall panels of for instance plasterboard, optionally falling material 8. and fastening means 9, such as screws. The front panels 27 and rear panels 277 are attached with fastening means 9 to the outside of the legs 4 of the columns |. Therefore, the surfaces of the panels 27, 277 facing the columns 1 are in contact with the side panels P2 of the columns 1. The fastening means © extend partly or completely through the legs 4 of the columns, i.e. through the side panels PZ. in particular through the reinforcement 6, more particularly through the wing panels P3, and still more particularly into the filling material 8. The filling material 8 may contain various suitable materials, such as fire-resistant, fire-retardant, heat-insulating, sound-insulating, and /or reinforcing material, or other materials known to those skilled in the art.

The construction system can function as various types of construction elements, such as a floor element, a ceiling element, a wall element, a roof element, or combinations thereof. Other constructive applications are also conceivable, In some cases one of the panels 2°, 277 can be replaced by An existing panel, such as a masonry wall, a foundation, structural beams, etc., with the existing panel replacing one of the panels 2°, 277.

Therefore, the present invention can be used, for example, to insulate existing walls, floors, ceilings, or roofs. embodiments.

Claims (1)

CONCLUSIONS I. Construction system comprising several columns (1) arranged on a substrate and panels (2) arranged between adjacent columns {1}. characterized in that the columns {1} are made of a cellulosic material and are similar in shape, the tender column {1} having a U-shaped cross-section with two parallel legs {4) and a base (3) located therebetween, and wherein the legs (4) of the U-shaped cross-section are bent to form grooves (5} extending in the longitudinal direction of each column (1). A construction system according to claim 1, wherein each column {1} is made from one blank (P). Construction system according to claim 2, wherein the blank is provided with a main panel (P1) and with side panels {P2} arranged on either side of the main panel {B1}, and wherein the side panels {P2} relative to the main panel {P1 } can be hinged along a first fold line (F1}. A construction system according to claim 3, wherein the first fold line (F1) is a single fold line. Construction system according to claim 3 or 4, wherein each side panel {PZ} is connected to a wing panel (P3) on a longitudinal edge thereof remote from the main panel (P1}, and wherein the wing panel (P3} is relative to the side panel (P2}). can be hinged along a second fold line (F2}. A construction system according to claim 5, wherein the second folding line {F2} is a double shaping line. A construction system according to any one of the preceding claims 1 to 6, wherein a support material (6) and/or an insulating material 1s is received in the grooves. Co-construction system according to claim 7, wherein the support material (6) is slat-shaped. 9. Construction system according to one of the preceding claims 1 to 8, wherein the panels {27,277 are arranged on the outside of the legs {4} of the U-shaped cross-section. A construction system according to claim 9, wherein the panels (27,277) are screwed or glued to the outside of the legs (4) of the U-shaped cross-section. A construction system according to any one of the preceding claims 1 to 10, wherein the panels {2} are made of a heat-insulating and/or sound-insulating material. 16 12. Construction system according to claim 11, wherein the panels (2) are formed by plasterboards. 13. A construction system according to any one of the preceding claims 1 to 12, wherein holes {7} are provided in the base {3} for guiding utility lines and/or pipes therethrough. 14. A construction system according to any one of the preceding claims 1 to 13, wherein the columns are manufactured from white cardboard, preferably from several cardboard layers glued underneath. 15. Column (1) for use in a construction system according to one of the preceding claims 1 to 14, wherein the column (1) is made of a cellulosic material, the column (1) has a U-shaped cross-section with two parallel legs {4} and a base (3} located therebetween, and wherein the legs (4) of the U-shaped cross-section are converted to form grooves (5) extending in the longitudinal direction of each column (1).