EP0058287A1

EP0058287A1 - Prefabricated panel structure for the building industry and process for the production thereof

Info

Publication number: EP0058287A1
Application number: EP81830023A
Authority: EP
Inventors: Tiziano Rico; Giulio Togni
Original assignee: Salvarani SpA
Current assignee: Salvarani SpA
Priority date: 1981-02-18
Filing date: 1981-02-18
Publication date: 1982-08-25
Also published as: DE3175090D1; EP0058287B1; ATE21427T1

Abstract

Prefabricated panel structure for the building industry comprising two thick main slabs (1, 2) of laminated plastic, being kept spaced and mutually glued, so as to form a sealed, flat, box-like body, by thick laminate fillets (4) arranged perpendicularly to the surface of the slabs, (1, 2) along at least their contour; the chamber formed inside said sealed box-like body contains pressed insulating material (3).

Description

The object of the present invention is a prefabricated panel structure for the building industry, a process for the production thereof, and a method of using the panel itself.
More particularly, the panel structure according to the invention has been conceived for the complete self-contained construction of a so-called "services area", though it may find application, more generally, in the construction of all the inner partition walls of the building, especially in certain types of constructions as those intended for hotels.
By the general term "services area" is here meant the volume occupied by the bathrooms and kitchen which, according to the present invention, is concentrated around the piping system of the main installations - called also "technical block" - in a co-ordinate and functional whole.
Prefabricated panels, meant to speed up the construction of the inner partition walls of a building, or of at least part of such walls, are already widely known.
A type of panel at present in use comprises for example slabs of gypsum board, fixed onto a supporting metal structure, with the eventual interposition of an insulating core, made for example of rock wool. These panels are mounted onto a metal carrying francwork, previously anchored to the concrete structure of the building. The connection points between adjacent panels are covered with gypsum smoothing.
This type of has however several drawbacks:

- to start with, it is fragile: its edges, or even the entire panel, may easily break during transport, or else when handling the same during assembly;
- the metal carrying framework and the corresponding connection points form as many gaps in the wall, especially for what concerns its characteristics of themal and acoustical insulation;
- it requires, in any case, the application of a superficial protective and finishing layer, to be applied after complete mounting of the panels, and this may even involve lining with tiles, for example in the bathroom area.

A further known type of prefabricated panel, having in turn a sandwich structure, comprises two sheets of thin laminated plastic

- for instance of a thiclmcss between ten and twelve tenths of a millimeter - containing an insulating layer, consisting for example of bakelized honey-comb board. Also these panels are mounted onto a metal carrying framework. The connection points between adjacent panels are covered by metal or wooden fillet joints.

Compared to the previously mentioned type, these panels essentially have the advantage of providing a surface which - especially if used for partitions inside offices - can be considered as substantially finished.
For what concerns the rest, they equally have the drawback of a scarce impact strength and of an insufficient thernal and acoustical insulation. They moreover have scarce fire resisting properties.
They are furthermore totally unfit for application particularly in the services area, in that they are scarcely resisting to water and to dampness in general, and on the other hand, they are also not apt to support a damproof lining of the type with tiles.
Also other types of commercially known prefabricated panels - more particularly designed for the construction of partition walls for offices - essentially comprise the characteristics heretoforespe- cified, of a differently composed sandwich structure mounted onto a metal carrying framework.
For what concerns more specifically the construction of service rooms, prefabrication was initially limited to the construction of the already cited "technical blocks", that is, of single-block units containing the basic sanitary installations, apt to be connected with a few operations to the risers and drain pipes, or else already incorporating some sections thereof. Blocks of this type may generally contain, in addition to all the pipes and connections required for connecting the various sanitary apparatuses, drain traps, water drain and hot water tanks, conditioning or air ventilation systems, and/or electric systems.
Such blocks have been found in practise very useful, in that they actually reduce to a considerable extent the amount of time and labor required in the building yard for arranging all the connections for the sanitary apparatuses. The block - eventually incorporating also the risers and drain pipes - is in fact placed at a pre-established point of the building and all there is left to do is to connect the sanitary apparatuses thereto.
More recently, further solutions have however been proposed, consisting in the prefabrication of complete "cabins", that is, of unitary assemblies of walls, sanitary apparatuses and respective pipes, forming a service room.
Known solutions of this type are being sold by the Italian firms MONTEDIL and ICS, as well as by the German firm H.G. MOLLER. They usually comprise a shell of plastic material - as fiberglass-reinforced plastic or methacrylate - formed in two or more moulds, wherein the actual wall of plastic material is moulded so as to obtain therein, in one piece therewith, also the sanitary apparatuses, or any other containment or carrying spaces. The inner surface of the walls forming said shell is perfectly smooth and finished. whereas on the outer wall, the surface of which is instead rough, all the connecting pipes are applied.
Single-block cabin units thus realized are positioned in the building structure when it is still without partition walls, they are connected to the risers and drain pipes, whereupon curtain walls or sheathing or covering walls are leant against the rough walls of the cabin.
Of course, a single-block assembly of this type - which is carried to the building yard for instance by motor transport, then lifted by crane and positioned in its final position - has the great advantage of reducing the construction times in the building yard of the corresponding service room.
Nevertheless, it is not free from drawbacks. To start with, on account of its bulk - since it is in practise a complete room, though small - and of its weight, it requires special equipment both for its transport from the factory to the building yard and for its lifting and positioning. Furthermore, it always requires external curtain or sheathing walls, which evidently reduces the advantage of such a daring prefabrication. On the other hand, in the event of damages to the plant applied on the external part, it is very difficult to operate repairs. Finally, in case of breakage or even of simple damage due to wear of the sanitary apparatuses, their replacement is very difficult and problematic due to the fact that they are formed in one piece with the wall.
A further inconvenience derives from the fact that, since these cabins are produced starting from large moulds which are generally costly, it is practically impossible to produce them in several types and different shapes, whereby the building designer has to adapt the spaces to the structure of the cabin, rather than - as it normally happens - adapting the service roan to the general space requirements of the building.
Further types of single-block cabins now on the market, or equivalent solutions - such as described for example in the Canadian Patents No. 923,023 and No. 929,720 - substantially provide the same advantages, but also the same drawbacks.
A first object of the present invention is now to realise a nodular panel structure, being greatly improved compared to that of the known technique and providing, in particular:

- excellent characteristics of resistance to mechanical stresses, to ater and to dampness;
- a fundamental self-supporting capacity, so as to eliminate the requirement for connecting and carrying metal frameworks;
- a high dimensional precision and at least one perfectly finished surface, so as to allow a remarkably simple and quick assembly; in particular - on account of the characteristics of the laminate, which can be machined with highly precise mills - it has been possible to eliminate the need for any joint coverings;
- a minimum weight and size, with consequent easiness of transport and of handling during assembly;
- a lower and more constant factor of thermal and acoustical transmission;
- a relatively controlled cost.

These and other results are obtained with the panel structure according to the invention, which is substantially characterised in that it comprises two thick main slabs of laminated plastic, being kept spaced and mutually glued - so as to form a sealed, flat, box-like body

- by thick laminate fillets arranged perpendicularly to the surface of the slabs, along at least their contour, and in that the chamber formed inside said sealed box-like body contains pressed insulating material.

According to a particular characteristic of the invention, said spacing fillets are applied along a contour which is set back in respect of the edges of the slabs.
According to a further important characteristic, at least one of the outer faces of said main slabs has a finished surface.
A still further characteristic of the invention lies in the fact that said two main slabs comprise, on their faces turning towards the inside of the panel, symmetrically opposed grooves running along said setback contour and into which engage corresponding ribs of the spacing fillets.
To produce such a panel structure, one provides - according to the present invention - first of all to delimit said setback contour on the upward turning face of a first main laminate slab, positioned flat; then to apply along said contour, by means of adhesive, the lower edge of spacing fillets arranged perpendicularly to the first slab; to fill the volume confined between said fillets with a layer of insulating material being thicker than the width of said fillets; to lay over a second slab, with its inner face turning downward, applying it - also by means of adhesive - onto the upper edge of the spacing fillets; and to finally apply a pressure for tightening the slabs, one against the other and against the fillets, up to complete glueing thereof.
Preferably, said setback contour is delimited by the milling of grooves parallel to the edges of the slabs and set back in respect of such edges, the edges of the spacing fillets being engaged into said grooves with the interposition of adhesive.
After forming the panel structure in the manner heretofore described, one provides to trim its vertical edges, also by milling, forming thereon a shaped profile designed - in the juxtaposition of the panels one next to the other, in the manner better described hereinafter - to form a groove-and-tongue connection between said panels.
In the manner heretofore described, the present invention allows to form, on one hand, flat panel structures of modular dimension and, on the other hand, functional panel structures - such as corner panels or panels for T-connections - with which the first ones combine into a perfectly stable self-supporting whole.
A further aspect of the present invention consists in using the aforedescribed prefabricated panel structures in the building field and, in particular, for the construction of service rooms; for this purpose, one first of all places and fixes on the floor a guide defining the perimeter of the service room, then the single panels are brought with their lower edges into engagement with said guide and with their side-hy-side lateral edges into mutual engagement, after which a connecting guide is applied in correspondence and along the upper edges of the panels; thanks to the fact that the spacing fillets are set back in respect of the edges of the panels, a compartment housing the service piping system is formed at least along the vertical, side-by-side lateral edges.
Thus conceived, the structure according to the present invention, as well as its method of use, provide - compared to known technique - a great number of advantages:

- to start with, the single panels can be industrially produced complete of their respective means of mutual connection and anchorage and with fully finished surfaces; on the other hand, for the finishing of such surfaces, one may adopt any building or industrial techniques allowing to obtain the best characteristics according to the use foreseen for the panels: for residential houses, for hotels or for other large building complexes, and so on;
- moreover, said panels form in practise wall elements of nodular dimensions, which may be differently composed according to the structural and dimensional requirements of the project, so as to allow the most varied arrangements of service rooms;
- such panels, having essentially flat and smooth surfaces, may be easily piled up and packed with a minimum bulk; this forms a further advantage both for their storage in a very small space, and for their transport and/or lifting in the building yard;
- the setting up in the building yard is extremely fast, not only on account of the modest weight of the panels, but especially due to the fact that, on one hand thanks to their high dimensional precision and,on the other hand, due to the complete absence of supplementary connecting and carrying frameworks, it is possible to carry out the assembly very easily - almost as if it were a constructions game - without having to provide for any adjustments or arrangements in the building yard, including the connection of pipelines, especially electric lines, into the vertical or horizontal spaces formed, as said, by the spacing fillets which are set back in respect of the edges of the panels;
- thanks to the means of mutual connection and support, the set of panels thus assembled results perfectly rigid and stable, substantially like a group of stone walls. To set working the service room enclosed therein, it is sufficient to linlc the various sanitary apparatuses in correspondence of connection points and connect them with corresponding pipelines, provided in the "technical block", through passages suitably arranged into one of the panels leaning against the "technical block".

Further characteristics and advantages of the structure according to the present invention will anyhow result evident from the following description of some preferred embodiments thereof, given however by mere way of non-limiting example and illustrated in the accompanying drawings, in which:

Fig. 1 is a partial schematic horizontal section view of two juxtaposed panels;
Fig. 2 is a partially sectioned plane view of a panel;
Fig. 3 is a partial section view of the three elements of laminated plastic which form the panel;
Fig. 4 is a partially sectioned elevation view of a pair of assembled juxtaposed panels;
Fig. 5 is a partial head view of a panel, in correspondence of the point of anchorage to the floor;
Fig. 6 is a horizontal schematic section view of a panel forming a corner;
_Fig. 7 is a horizontal schematic section view of a panel having the form of a T or a double T connection;
Fig. 3 is a schematic plan view of a possible arrangement of a service area realized with the panels according to the invention;
Fig. 9 is a horizontal section view, on an enlarged scale, of the association of some of the panels used in the arrangement of fig. 3;
Fig. 10 is a schematic plan view of a different arrangement of a service area, inserted in a wider complex designed for hotel use;
Fig. 11 is a schematic elevation view of a partition wall used in the complex of fig. 10; and
Fig. 12 is a partial schematic vertical section view, on an enlarged scale, of the same wall of fig. 11 and of the respective anchoring system.

As shown, the panel according to the present invention is formed by a pair of thick main slabs 1 and 2 of laminated plastic.
By the term "laminated plastic" is meant at present a sheet product made up starting from sheets of high-quality cellulose, with high mechanical strength, imbued with a mixture of phenolic resins, superposed and pressed. Preferably, use is also made of a sheet of cellulose - or else of fabric, or even of veneering of wood, cork or the like - imbued with melaminic resin and on which an ornamental design may eventually be reproduced, forming a superficial layer, applied on one or on both faces of the "laminate" and having a decorative function. Such plastic laminates have been up to date produced in thicknesses usually not wider than ten to twelve millimeter tenths, and they have exclusively been used as sheets for covering and protecting a carrying structure, for example of wood.
Whereas, the "thick laminated plastic" is a laminate produced substantially with the same technique as described above, but sufficiently thick - for instance, 5 to 12 mm - to become, to a more or less large extent, self-supporting. A thick laminate of this type, though of very particular conformation, has been proposed in the Italian Patent application No. 24066 A/80 filed on 3th August 1980 in the name of the same Applicant.
The panel according to the present invention uses the two laminated plastic slabs 1 and 2, with the interposition of a layer 3 of insulating material, consisting for example of pressed cork. According to the invention, this insulating layer is delimited along its entire contour, by fillets 4, also made of thick laminated plastic.
Figures 1 and 2, but more particularly figure 3, show how to assemble the aforementioned elements 1, 2, 3 and 4. The faces of the slabs 1 and 2 turning towards the inside of the panel are provided - to delimit the contour enclosing the insulating layer 3 - with grooves 1' and 2', into which engage the fillets 4 with their opposed edges (if the grooves' 1' and 2' are wide enough) or, preferably, with ribs 4' formed on their edges.
The grooves 1', 2' and the ribs 4' are formed by milling, and. this - taking into account the highly compact and hard structure of the laminate - allows an execution of high dimensional precision, to the full advantage of the subsequent assembly and gluing operations.
In practise, to construct the panel one proceeds as follows:

- the slab 1 is positioned flat, with its inner face turning upwards, and adhesive is spread thereon, for instance cold adhesive of the "536 spray" type produced by the firm AREC. The fillets 4 are then applied, and their respective ribs 4' are engaged into the grooves 1'. The space delimited by the fillets 4 is filled with insulating material - preferably formed by cork sheets or the like - up to a thickness slightly exceeding the width of the fillets 4. Finally, the slab 2 is positioned thereon, being in turn previously spread with adhesive on its inner face, causing the ribs 4¹ of the fillets to get engaged into the grooves 2'. The panel thus formed is then subjected to pressure
- so as to press in particular the insulating material - and during this step the adhesive firmly sets.

In practise, it has been found that the engagement of the ribs 4' into the grooves 1' and 2' is not strictly indispensable, but the fillets may simply abut against the inner faces of the slabs 1 and 2 and be directly glued hereto. In this case it will evidently be necessary to provide means for temporarily keeping the fillets in a correct position, during pressing of the panels.
The result is anyhow a panel which - mainly on account of the box-like structure formed by the slabs 1 and 2 and by the fillets 4, but also owing to the compactness of the interposed insulating material - is perfectly rigid and self-supporting. On the other hand, due to the very absence of any metal carrying frameworks, such a panel is also extremely light and handy.
An important characteristic of the panels according to the invention lies moreover in the fact that the fillets 4 are set back in respect of the edges of the slabs 1 and 2, so that when two panels are juxtaposed, a chamber S - clearly shown in figure 1 - is formed therebetween, said chamber being apt to house service pipelines, and particularly electric lines.
For connecting several panels in succession - in order to form an entire wall - their vertical edges may be subjected to a further finishing operation, which consists in forming cog rib profiles 4"; each pair of profiles is apt to engage, by simple cogging, with a pair of mating profiles formed on the opposite side of each adjacent panel (as shown particularly in figure 1). This cogging allows to obtain a perfect airtight and watertight connection, without requiring the application of joint coverings.
Figures 4 and 5 show how the panels are fixed one to the other into a wall structure. For this purpose, a guide 5 is placed on the floor - firmly fixed by any known system, for example by riveting - comprising a metal rectangular section (as shown in figure 5) or an omega section, or the like.
To start with, each panel is positioned onto this guide 5, so that its bottom fillet 4 may substantially rest on the top of such guide, while the edges of the slabs 1 and 2, which extend beyond said fillet 4, embrace the guide 5 itself, as clearly shown, in figure 5.
Once a first panel P has been thus positioned, it will be simply anchored to the guide 5 with a bracket 6. This latter is fixed on one side, by means of a screw 7 or rivet or the like, to the top of the guide 5, and on the other side it is fixed to the vertical fillet 4 of the panel P by means of screws screwed into holes 6'.
The adjacent panel P' is positioned onto the guide 5 in the same way, being brought close to the panel P up to mutual connection of the cog rib profiles 4", so as to guarantee the correct anchoring of the panel P' to the side of the panel P. At its opposite side (not shown in figure 4) the panel r' is then fixed with a bracket 6, in an identical way as described hereabove.
Thus, as seen, each panel is fixed to the floor with a single bracket, its correct anchorage being furthermore guaranteed by the cogging of the vertical edges of the single juxtaposed panels.
For what concerns the anchoring at the top of each panel, this can be obtained in a similar way than done for the base, through a. guide symmetrical to the guide 5, especially when having to compose walls for a relatively compact service area, such as described hereinafter with reference to figure 8. Whereas, in the event of having to assemble a relatively long rectilinear wall without any transversal supports, a top anchoring system of the type described hereinafter with reference to figures 11 and 12 will be adopted.
Figure 6 shows a panel forming a corner. As can be seen, the fundamental structure is essentially the same as seen with reference to figure 1, that is, with slabs 1 and 2 of laminated plastic enclosing a thick layer 3 of pressed cork or other insulating material.
Each corner panel is however formed by two rectilinear panel parts, in each of which the contour of the insulating layer is defined by the heretofore described fillets 4 only on three sides of the panel, while in correspondence of the vertical corner side, the said layer is delimited by a wooden upright 8. This upright 3 has a double function:

- on one hand, it is in fact apt to reinforce the panel just in correspondence of its corner position, which is the most stressed part of structure;
- on the other hand, it is also apt to facilitate the mutual gluing of the two rectilinear panel parts, which gluing is carried out along the dashed line X-X.

Figure 7 shows a panel in the form of a T or a double T connection. This panel is used, as better illustrated hereinafter, for the construction of a rectilinear wall, to which are perpendicularly connected other walls. In the structure of figure 7, the main rectilinear panel P incorporates - in correspondence of the positions of connection to the walls perpendicular thereto - a wooden upright 9, in replacerment of the cork layer 3. A lath 10, also of wood, is furthermore applied - by gluing or even by screws or other known suitable means - on the outer face of the panel, in correspondence of the upright 9.
The lath 10 is used as guiding element for a panel section 11, forming the beginning of a perpendicular wall, and it acts just like the guide 5 used to anchor the panel to the floor. In fact, the section 11 is brought into engagement with the lath 10, so that the fillet 4 comes in contact with the lath and the ends of the slabs 1 and 2, extending beyond the fillet 4, can embrace the sides of the lath 10. The panel section 11 thus results perfectly positioned.
For anchoring the section 11 to the main panel 1, opposed holes 12 and 13 are provided, at regular distances, on the fillets 4 of the section 11 itself. A first smaller hole 12 is used for the passage of a screw 14 or the like, which anchors the section onto the lath 10 and onto the upright 9, while a second larger hole 13 is used for letting through a tool to drive in the screw 14.
It should be noted that the corner panel, as well as the T or double T panel, is assembled at the factory, and not in the building yard, whereby assembly can be done with the highest possible precision.

Figures 3 and 9 show a way of using the panels described so far. Figure 3 shows a possible arrangement of a services area, surrounding a volume V containing the delivery and drain pipes. Gn one side of the volume V is formed a bathroom B, while on the other side there is a kitchen C with sink 15 and cooker 16, and on the third side there is room for a cupboard A. All the hatched contour represents the partition walls formed with the panels according to the invention.

Figure 9 shows more in detail how the various types of panels are associated to realize a wall arrangement as that shown in figure 3. One can actually see rectilinear panels F, corner panels 11 and a double T panel 1'2, which latter is used to anchor the walls delimiting the technical volume V.
Figure 10 shows a different structural arrangement, of the twin type, designed for hotel use. It will be noted that with the panels according to the present invention it is possible to realise, not only bathroom areas B, placed by twos and each having a technical volume V of their own, or eventually some cupboard elements A, but also the entire partition walls D between one room and the next.
However, for these partition walls D, two additional problems have to be faced:

- in fact, on one hand, since this rectilinear wall is relatively long and has no transversal bracing connections, it is indispensable to provide for anchoring means not only at floor level but also at the ceiling;
- on the other hand, since these partition walls are actually designed to separate hotel rooms, higher soundproofing conditions may be required than those foreseen between service areas and rooms of the same living space.

The first of these problems is solved in the way shown in figure 11, and more in detail in figure 12, taking also into account the fact that, While the construction of the panels at the factory may be carried out with high dimensional precision, viceversa the concrete structures or the building structures in general have rather wide tolerances.
In view of this fact, it is foreseen to construct the panels whith a height about 5 cm below the room height planned in the building project. The panels are then fixed at the base by being placed astride of a metal guide, in the manner heretofore described. At the top, the panels are fixed by means of extending brackets 18 which are anchored directly to the ceiling at regular intervals. These brackets 18 may be simple L-shaped metal brackets. Alternatively, one may use brackets made of rubber or other similar resilient material, adapting more easily - by mere elastic deformation - to the distance differences between the ceiling and the top of the panels.
For what concerns instead the second problem, namely a more efficient soundproofing, this is solved - according to the present invention - by using a couple of shortly spaced panels, as illustrated in the constructive variant of figure 12. In this case, a bottom guide is used, formed by a pair of parallel ribs 5A and SB, connected by a flat intermediate portion 5C. On this flat portion 5C are set the means of anchorage to the floor, for example expansion screws 20, while the panels are placed astride of the ribs 5A, 5B.
At the top ends, after having fixed the panels by means of the bracket 18, the space lying between the top of the panels and the surface of the ceiling is filled with insulating material L, for example rock wool. Both sides of the double wall thus formed are then closed by masking frames 19. The frames 19 may have any configuration and be fixed by any suitable means of known type, whereby it seems unnecessary to give a detailed description of such means.
The intermediate space between the panels forms a practically sealed air chamber.
The practical tests carried out on the panels produced according to the present invention have given fully satisfactory results.
In actual fact, even if using for the main slabs 1 and 2, laminates of a relatively limited thickness - that is, of about 5-6 mm, instead of the 9-10 mm specified for example in the aforecited patent application No. 24066 A/80 - the panel offers surprising features of stiffness and mechanical strength. On the other hand, it is light and handy.
On account of its method of construction, the panel according to the invention provides furthermore very precise and uniform dimensional and qualitative characteristics, and this considerably facilitates the assembly operations in the building yard. It has been found in practice that, for constructing for example a bathroom, the construction time is reduced up to 70% compared to the traditional systems.
Moreover, the aforecited dimensional and qualitative characteristics are permanent in time, whereby there is no fear at all of any yieldings or deformations. The panel is in fact resisting to impact, abrasion and chemical etching; it is liquid-proof and thereby perfectly resisting to dampness which is normally present in services areas; it is furthermore quite fire-resisting.
The panels according to the invention have a good soundproofing or deadening power. With a panel of the type illustrated in figure 1, about 40-50 mm thick, an absorption of about 32-35 db has been observed, while a wall with two panels, as the one illustrated in figure 12, has been found to provide an absorption up to 48 db.
The high dimensional precision and the excellent finishing in the production of these panels allows them to be assembled simply juxtaposed, as shown in figures 1 and 4, without the need - as already said - for any joint coverings between one panel and the next. Moreover, the free space being formed between two juxtaposed panels - indicated with S in figure 1 - allows the passage of cables, pipes or the like, thereby eliminating the problems and additional costs involved in the prearrangement of canalizations or the like.
It should finally be noted that the particularly simple structure of these panels allows them to be produced both of standard modular dimensions, and of special dimensions on request of the designers, this allowing to satisfy high requirements of flexibility of use.

Claims

1) Prefabricated panel structure for the building industry, characterized in that it comprises two thick main slabs of laminated plastic, being kept spaced and mutually glued, so as to form a sealed, flat, box-like body, by thick laminate fillets arranged perpendicularly to the surface of the slabs, along at least their contour, and in that the chamber formed inside said sealed box-like body contains pressed insulating material.

2) Panel structure as in claim 1), wherein the laminated plastic forming the slabs and the spacing fillets is of a thickness of 5 to 10 mm, preferably 5-6 mm.

3) Panel structure as in claim 1), wherein said spacing fillets are applied along a contour which is set back in respect of the edges of the slabs.

4) Panel structure as in claim 1), wherein the outer face of at least one of the slabs of laminated plastic forming the panel has a finished surface.

5) Panel structure as in claim 1), wherein the insulating material contained in the sealed chamber consists of cork.

6) Panel structure as in claims 1) or 5), wherein said intermediate insulating material is formed of several superposed and juxtaposed sheets or sheet parts, pressed up to occupying the entire volume of said chamber formed by the sealed box-like body.

7) Panel structure as in claim 1), wherein at least the opposite vertical edges of each panel are shaped so as to obtain a simple groove--and-tongue engagement with the edges of the adjacent panels.

3) Panel structure as in claim 7), wherein said vertical edges of the panels have cog rib profiles.

9) Panel structure as in claim 1) or 3), wherein said two main slabs are provided, on their faces turning towards the inside of the panel, with symmetrically opposed grooves running along said setback contour, into which engage the edges of the spacing fillets.

10) Panel structure as in claim 9), wherein said grooves are less wide than the thickness of the spacing fillets and the latter are provided, on their opposite edges, with narrow ribs for engagement into said grooves.

11) Panel structure as in any one of the preceding claims, wherein the cavity formed between each spacing fillet and the ends of the main slabs extending beyond the fillet forms, in cooperation with the similar cavity of an adjacent panel, a space for housing service pipelines.

12) Panel structure as in any one of the preceding claims, presenting itself in the form of a flat panel.

13) Panel structure as in any one of the claims 1) to 11), presenting itself in the form of a corner panel.

14) Fanel structure as in claim 13), wherein the intermediate insulating material, in correspondence of the corner position, comprises at least one stiff wooden upright.

15) Panel structure as in any one of the claims 1) to 11), presenting itself in the form of a panel for T connections.

16) Panel structure as in claim 15), wherein, in correspondence of the T connection position, the insulating material of the main panel incorporates a wooden upright.

17) Panel structure as in claim 16), wherein, in correspondence of the connection position and externally of the rain panel, there is firmly fixed a wooden lath, acting as connection means for the secondary panel element arranged perpendicularly to the main panel.

18) Panel structure as in claim 17), wherein the dimensions of said lath are substantially equal to the volume of the cavity formed between the spacing fillet and the ends of the main slabs of the secondary panel element extending beyond said fillet.

19) Process for the production of a self-supporting panel as in any one of the preceding claims, comprising the steps of:

- delimiting on the upward turning face of a first main slab of lami-, nated plastic, positioned flat, a contour set back in respect of its edges;

- applying along said contour, with the interposition of adhesive, the lower edge of spacing fillets arranged perpendicularly to the slab;

- filling the volume confined between said fillets with a layer of insulating material being thicker than the width of the fillets;

- laying over a second main slab of laminated plastic, by applying it on the upper edge of the spacing fillets, also with the interposition of adhesive;

- subjecting the slabs to a clamping pressure, one onto the other and against the fillets, up to complete gluing thereof.

20) Process as in claim 19), wherein said setback contour is delimited by the milling of grooves running parallely to the edges of the main slabs and being shortly spaced in respect thereof, into said grooves being engaged, with the interposition of adhesive, the edges of the spacing fillets.

21) Process as in claims 19) or 20), wherein narrow ribs are formed by milling on the opposite longitudinal edges of said spacing fillets, said ribs being apt to engage into said grooves of the main slabs.

22) Process as in claim 19), wherein cog rib profiles are formed by milling at least on the opposite vertical edges of the main slabs of each assembled panel, said profiles forming a mutual cogging engagement with the adjacent panels.

23) Process as in claim 19), wherein for the construction of a corner panel, in each of the two flat panel parts arranged perpendicularly, and in correspondence of the respective corner position, the spacing fillet is replaced by a stiff wooden upright being used for the mutual connection of the two parts.

24) Process as in claim 23), wherein said mutual connection of the two corner panel parts is obtained by gluing.

25) Process as in claim 19), wherein for the construction of a T connection panel, a stiff wooden upright is incorporated in the insulating layer of the main panel, in correspondence of the connection position, and a wooden lath is moreover firmly fixed on the outside of the panel, and wherein a secondary panel element is fixed onto said lath, perpendicularly to the main panel, by means of screws passing through at least one vertical spacing fillet of said secondary panel element.

26) Use of a panel structure as in any one of the claims 1) to 18) in the building field, particularly for the construction of partition walls.

27) Use as in claim 26), wherein one determines the perimeter of the partition walls defining different areas of a single living space and, along said perimeter, one fixes to the ground a rest guide on which are mounted the panels, one next to the other, carrying furthermore into mutual engagement the respective vertical sides and using, time after time, flat panels, corner panels or T connection panels, up to completing the perimeter, whereupon one eventually applies a connection guide along the upper edges of the panels.

28) Use as in claim 26), wherein one determines the perimeter of the partition walls separating one living space from the next and, along said perimeter, one fixes to the ground a double rest guide, on each of the two guides being mounted the panels, one next to the other, carrying furthermore into mutual engagement the respective vertical sides and fixing the panels to the cciling of the building by means of anchoring brackets, the free space between the top of the panels and the ceiling being filled with scaled compensation joints, and a sealed air chamber being formed between the parallel adjacent panels fixed onto said two guides.

29) Use as in claim) 27) or 23), wherein the free space being formed at least along the vertical edges of the juxtaposed sides of the panels, is used for housing service pipelines.

30) Use as in any one of the claims 26) to 28), wherein at least one of the panels of said partition walls is leant against a "technical block incorporating the service pipelines or canalizations as well as the connections for support of the sanitary apparatuses and for connection to the respective piping system, said panel being provided with holes in correspondence of said connection points to allow said sanitary apparatuses to be connected directly.