RO135666A0 - Process for bending layered sructures and bent layered product - Google Patents

Abstract

The invention relates to a process of bending layered structures and to a bent layered product. According to the invention, the process consists, in a first step, in laying horizontally a laminated panel having two outer layers (1 and 2) as sheets made of a malleable material and an inner homogeneous or inhomogeneous filling layer (3), which is integral by adhesion with the outer layers (1 and 2), on a rigid fixed or movable support, after which a distributed load is applied on the upper face of the first layer/upper layer (1), along the entire panel length or width, with a constant or variable pitch (p), causing the local descent of the first layer (1), on a depth (h), in the form of depressions, making it bend, which causes the compression of the adhesion part of the filling layer (3) with the first layer (1), thus resulting in the bending of the layer (3) which, in its turn, due to the adhesion with the layer (2) bends it too, a desired radius (R) of the bent layered product being determined by the depth of a drawing (h) performed by the distributed load (F), as well as by the size of a pitch (p), the load (F) being taken over by a tension (T) in the filling layer (3), the tension (T) being applied to the first layer (1) and being transmitted through the material of the third layer (3) to the second layer (2), causing a moment (M) to occur which produces the bending of the second layer (2) together with changes in the density distribution in the third layer (3) and, by the adhesion forces between the layers (2 and 3), leading to the bending of the layer (2), as well. According to the invention, the product has two outer layers (1 and 2) as malleable sheets and an inner layer (3), forces being applied to the panel, which determine a desired radius (R) of curvature of the bent layered product representing the final product.

Description

______RO 135666 AO

Mί-iuL CS PENIRU STATE INVENTIONS AND MAPC ί Patent application

CL 2p <op 4?^ ' - Q^-4r ^noz it · · · -V. J?.; O Him,

Process of bending layered structures and curved layered product

[001] The invention of the process of bending layered structures and curved layered product refers to the process of bending building elements such as panels made of several layers and to a curved layered product made by that process, used in the field of construction.

[002] There are known processes for making curved laminated products having two outer layers in the form of metal sheets and an insulating/thermo-insulating inner layer, which have the disadvantage that they provide for the prior arrangement/bringing to the curved shape of the elements of the layered structure, respectively the sheets metal and then solidifying and filling them with the insulating layer, which complicates the process of making curved layered structures, also involving high production costs.

[003] The technical problem that the invention solves is the realization of a curved laminated panel from a flat, folded laminated panel or the modification of the curvature of an existing curved laminated panel.

[004] The process of bending the layered structures according to the invention solves the technical problem in that on one of the malleable outer layers of a flat layered panel, having two flat or folded outer layers and an inner filling layer, which forms a common body through adhesion with outer layers, is applied transversely along the full width, length or diagonally, a compressive force which causes the local lowering of the first layer, in the form of a symmetrical or asymmetrical depression, the force which is successively applied across the full width, lengthwise or diagonally across the panel, causing parallel or non-parallel embossing, by moving the panel or the force in steps, the required radius being obtained by correlating the size of the force with the size of the step, resulting in the final product of the process.

[005] The curved layered product made according to the process comprises a first layer of a given thickness, a second layer of a different or the same thickness and a third inner layer of filling of a certain thickness, on the first layer applying a force that determines the descent local of the first layer, the force being taken over by the tension in

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RO 135666 AO the material of the third layer, tension that is applied to the first layer and is transmitted through the material of the third layer to the second layer causing the appearance of a moment that forms the curvature of the third layer together with changes in the distribution of of the density in the third layer and through the adhesion forces between the third layer and the second layer, resulting in the curvature of the second layer as well, the required radius obtained by correlating the size of the force with the size of the step, resulting in the final product of the process.

1006] By applying the invention, the advantages are obtained:

- increasing productivity;

- reducing the costs of curved panels;

- allows the use of the usual flat laminated panels in curved panels according to any set radius with minimum expenses;

[007] Below is an example of the process of bending layered structures and of a curved layered product made according to the process, in connection with fig. 1 and fig. 2 which represents:

- Fig. No. 1, section through laminated panel before bending and

- Fig. No. 2, section through curved laminated panel.

[008] With reference to fig. 1 and fig.2, the process of bending the layered structures according to the invention includes the following steps:

A layered structure is taken as a layered panel having as outer layers two sheets of flat or corrugated sheets 1,2 and thickness δ1, between which there is a filling material 3 consisting of polyurethane foam with thickness δ3 which forms a common body through adhesion with the layers outer 1 and 2;

The laminated panel is placed horizontally on a rigid support, for example on a wooden table, the support can be fixed or mobile, the panel having the length or width in the direction of the movement of the support, or of the distributed load, depending on how the curvature of the panel is desired - lengthwise or widthwise. Also, depending on the desired shape of the curved panel, the initially laminated panel can be placed obliquely on the rigid support, with the distributed load F applied perpendicular to the direction of travel.

RO 135666 AO

It is applied to the upper face of the upper plate (above) 1 having a thickness of 51, successively, over the entire length/width of the panel, with a step p, a distributed force/load F, perpendicular to the direction of travel, over the entire width, respectively the length (i.e. transversally), the distributed load F causing the local lowering of the upper layer 1 to a depth h, in the form of symmetrical, parallel depressions (embossments), which determine the curvature of the upper layer 1 in order to obtain a predetermined radius R; Also, depending on the desired shape of the curved panel, the distributed load F can be applied obliquely to the direction of travel, and the embossing can be asymmetrical and/or non-parallel.

[009] The distributed load F is thus taken over by the tension T in the material of the third filling layer 3, tension which is applied to the first layer 1 and is transmitted through the material of the third layer 3, to the second layer 2 causing the occurrence of a moment M which bends layer 3, together with density distribution changes in this layer 3, and through the adhesion forces between the second outer layer/bottom plate (below) 2 and the filler layer 3, thus also bends the lower layer (2);

[010] in the concrete embodiment, the recess has the shape of the letter "\F, and the size of the depth (h) correlated with the distributed load F forms the desired radius R, of the curved laminated panel;

[011] The distributed load F is successively applied along the entire length, respectively the width of the panel, either by moving the distributed load F, or by moving the panel according to the established step p, which in the embodiment, where it is desired to obtain a layered panel in the form of a part of the jacket (of a crown segment) cylindrical circular, is constant being a submultiple of the length/width of the panel. The pitch size p correlated with the distributed load (size of load) F determines the radius R of the curved layered product, representing the final product.

[012] The step p representing the distance between two neighboring embossings can also be variable, but with a symmetrical variation with respect to the symmetry axis of the panel, parallel to the embossings, if it is desired to obtain a layered panel in the form of a part of a shirt ( of a crown segment) cylindrical parabolic.

[013] The process described above can also be applied to an already curved panel, made by methods known in the state of the art in order to modify the curvature.

RO 135666 AO

[014] The curved layered product made by the above process consists of a first outer layer 1, located towards the inside of the curved area/portion of thickness δ1, showing some symmetrical or asymmetrical recesses made by applying a distributed load F, a second layer outer 2" located towards the outside of the curved area/portion of thickness δ2, equal to or different from that of the first layer, and a third filler layer 3 of thickness δ3 located between the first two layers and bonded to them. A distributed load F is applied to the first layer 1, which causes the local lowering of the first layer with the size h, causing its curvature. The distributed load F is taken over by the tension T in the material of the third layer 3, which is applied to the first layer 1 and is transmitted through the material of the third layer 3 to the second layer 2, causing a moment M which also bends the second layer 2 together with density distribution changes in the third layer 3, and by the adhesion forces between the layers resulting in the bending of the whole panel. The distributed load F applied to the first layer 1 with a step P, the size of the step being correlated with that of the distributed load forms the set radius R.

[015] The process of bending the layered structures and the curved layered product can have the outer layers 1 and 2 of metal or other malleable materials, and the inner layer 3 of filling materials such as polyurethane foam, polystyrene, mineral wool or the like.

[016] The magnitude of the curvature R of the curved layered product is dependent on the local dip h of the first layer 1 and the magnitude of the distributed load F applied to the first layer 1.

Claims (5)

RO 135666 AO demand 1. Process of bending layered structures that includes the following stages: a layered panel is placed horizontally, having two outer layers in the form of sheets made of a malleable material (1, 2) and an inner layer (3), of homogeneous or inhomogeneous filling that forms a common body through adhesion with the outer layers (1, 2), on a rigid support, the support being fixed or mobile; a distributed load (F) is applied to the upper face of the first layer/top layer (1), along the entire length or width of the panel, with a constant or variable pitch (p), transversely on the entire side, the said distributed load (F), causing the local lowering of the first layer (1), to a depth (h) in the form of depressions, which causes its curvature, which causes the compression of the adhesion part of the filling layer (3) with the first layer (1) thus resulting in the curvature layer (3) which in turn, due to the adhesion with layer (2) bends it as well, the desired radius (R) of the curved layered product being determined by the depth of embossing (h) performed by the distributed load (F) as well as the size step (p), the distributed load (F) being taken up by a tension (T) in the filler layer (3), the tension (T) being applied to the first layer (1) and transmitted through the material of the third layer ( 3) to the second layer (2), determining the water rity of a moment (M) which produces the bending of the second layer (2) together with density distribution changes in the third layer (3) and by the adhesion forces between layer (2) and the third layer ( 3), leading to the curvature of layer two (2). 2. The process as in claim 1 in which the distributed load (F) can be, depending on the desired shape of the curved panel, applied obliquely to the direction of movement, the resulting embossings can be asymmetric and/or non-parallel. 3. The method as in claim 2 in which, depending on the desired shape of the curved panel, the initially layered panel can be placed obliquely on the rigid support, the distributed load (F) being applied perpendicular to the direction of travel. RO 135666 AO 4. Curved layered product obtained by applying the process of claim 1, characterized in that it comprises, a first layer (1) in the form of a sheet made of a malleable material of given thickness (δ1), located towards the inside of the curved area/portion , presenting some symmetrical or asymmetrical indentations made by applying a distributed load (F), which determined its curvature, a second layer (2) in the form of a sheet of malleable material of equal or unequal thickness (δ2) to the first layer , located towards the inside of the curved area/portion, and a third filler layer (3) forming a common body by adhesion with said layers (1, 2) of given thickness (δ3), the outer layer (2) and the filler layer ( 3) being curved as a result of the cubing of the first layer (1). 5. The method as in claim 4 where the outer layers (1) and (2) are metallic, the filling layer (3) being one of the materials: polyurethane foam, polystyrene, mineral wool, foam rubber, or a combination thereof.