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Title:
LAMINATE OF MUTUALLY BONDED ADHESIVE LAYERS AND SPLICED METAL SHEETS
Document Type and Number:
WIPO Patent Application WO/2018/097720
Kind Code:
A1
Abstract:
Described is a laminate, comprising a stack of mutually bonded adhesive layers and metal sheets. The laminate comprises abutting metal sheet edges that extend along a length direction within a splicing region. A splice strap is connected to the stack at an outer surface of the stack across said splicing region, the splice strap comprising at least one layer of fiber-reinforced adhesive or of metal sheet, or stacked layers of fiber-reinforced adhesive and/or metal sheets. The laminate comprising the splice strap has specific shear properties.

Inventors:
GUNNINK JAN WILLEM (NL)
Application Number:
PCT/NL2017/050769
Publication Date:
May 31, 2018
Filing Date:
November 23, 2017
Export Citation:
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Assignee:
GTM ADVANCED PRODUCTS B V (NL)
International Classes:
B32B5/02; B32B3/10; B32B7/04; B32B7/12; B32B7/14; B32B15/04; B32B15/08; B32B15/14; B32B27/00
Domestic Patent References:
WO2017048122A12017-03-23
WO2015142170A12015-09-24
WO2015163764A12015-10-29
WO2015183080A12015-12-03
WO2007145512A12007-12-21
WO2007061304A12007-05-31
Foreign References:
EP2646242B12015-06-10
EP2763849A12014-08-13
US20120045606A12012-02-23
US5429326A1995-07-04
Other References:
ROBERT M. JONES, MECHANICS OF COMPOSITE MATERIALS, ISBN: 0-07-032790-4
Attorney, Agent or Firm:
BROUWER, Hendrik Rogier (NL)
Download PDF:
Claims:
A laminate comprising a stack of mutually bonded layers of fiber reinforced adhesive and metal sheets, wherein an outer metal sheet defining an outer surface of the slack is a spliced metal sheet with abutting metal sheet edges extending along a length direction and forming a splice within a splicing region; and a splice strap connected to the outer surface of the stack and extending in the length direction and in a transverse direction perpendicular to the length direction across said splicing region over a splicing region width, the splice strap comprising mutually bonded layers of at least one adhesive layer and at least one metal sheet, wherein a splice strap adhesive layer is provided for connection to the outer surface;

wherein the following relation is satisfied within the splicing region:

in which

n = the number of layers in the stack;

m = the number of layers in the splice strap;

for the outer spliced metal sheet in the stack

and wherein G, = 0 for any two other spliced metal sheets in the stack within the splicing region that are adjacent to each other and have splices that are within a distance in the transverse direction of 5 times the larger thickness ti of the two spliced metal sheets;

ti is the thickness, and Gj the shear modulus of the i* layer in the stack;

ti is the thickness and Gj the shear modulus of the j* layer in the splice strap; wherein at least one of the adhesive splice strap layers comprises reinforcing fibers forming a fiber reinforced adhesive splice strap layer;

wherein at least 30% of the reinforcing fibers in the stack are oriented at an acute angle with the length direction within the splice strap region, the acute angle being within the range between - 45° and 45° with respect to the length direction; and

wherein at least 50% of the reinforcing fibers in the splice strap are oriented at an acute angle with the transverse direction within the splice strap region, the acute angle being within the range between - 45° and 45° with respect to the transverse direction,.

2. The laminate according to claim 1 wherein 0.75

3. The laminate according to claim 1 or 2 wherein 0.85

4. The laminate according to anyone of the preceding claims, wherein at least one of the adhesive stack layers comprises reinforcing fibers forming a fiber-reinforced adhesive stack layer.

5. The laminate according to anyone of the preceding claims, wherein at least 30% of the

reinforcing fibers in the stack are oriented at an acute angle with the length direction within the splice strap region, the acute angle being within the range between -30° and 30° with respect to the length direction, and most preferably within the range between -15° and 15° with respect to the length direction.

6. The laminate according to anyone of the preceding claims, wherein at least 50% of the

reinforcing fibers in the stack are oriented along said acute angle with respect to the length direction.

7. The laminate according to anyone of the preceding claims, wherein at least 65% of the

reinforcing fibers in the stack are oriented along said acute angle with respect to the length direction.

8. The laminate according to anyone of the preceding claims, wherein at least 75%, and more preferably at least 90% of the reinforcing fibers in the stack are oriented along said acute angle with respect to the length direction.

9. The laminate according to anyone of the preceding claims, wherein at least 50% of the

reinforcing fibers in the splice strap are oriented at an acute angle with the transverse direction within the splice strap region, the acute angle being within the range between - 45° and 45° with respect to the transverse direction, more preferably within the range between -30° and 30° with respect to the transverse direction, and most preferably within the range between -15° and 15° with respect to the transverse direction.

10. The laminate according to anyone of the preceding claims, wherein the thickness of the spliced metal layer of the stack is at least 0.3 mm, more preferably between 0.3 mm and 1.3 mm, even more preferably between 0.4 mm and 1.2 mm, and most preferably between 0.6 mm and 1.0 mm.

1 1. The laminate according to any one of the preceding claims, wherein the spliced metal sheet comprises the metal sheet in the stack that is in contact with the splice strap.

12. The laminate according to any one of the preceding claims, wherein the spliced metal sheet comprises the thickest metal sheet in the stack.

13. The laminate according to anyone of the preceding claims, wherein a splice strap layer most closely arranged to the outer surface of the stack extends over a total transverse distance of at least 10 times the thickest metal sheet in the stack, more preferably over a total transverse distance of at least 25 times the thickest metal sheet in the stack.

14. The laminate according to anyone of the preceding claims, wherein the splice strap comprises a metal sheet layer that is connected to the laminate with a layer of fiber-reinforced adhesive.

15. The laminate according to anyone of the preceding claims, wherein an outer surface of the splice strap is flush with an outer surface of the stack.

16. The laminate according to any one of the preceding claims, having a blunt notch strength at a location of the splicing region ranging from

is the tensile strength of the stack of the laminate without the splice in the metal sheet, preferably is equal to or more than more preferably is equal to or

more than

17. Structural component for a vehicle, spacecraft, or aircraft, comprising a laminate according to any one of the preceding claims.

18. Wing of an aircraft, comprising a laminate according to any one of claims 1-17.

Description:
LAMINATE OF MUTUALLY BONDED ADHESIVE LAYERS AND SPLICED METAL

SHEETS

FIELD OF THE INVENTION

The present invention relates to a laminate comprising a stack of mutually bonded layers of adhesive and metal sheets. The invention further relates to a structural component for a vehicle, spacecraft, or aircraft, comprising a laminate according to the present invention. The invention further relates to an aircraft comprising a laminate according to the present invention.

BACKGROUND ART

Laminates of mutually bonded adhesive layers and metal sheets are used for structural purposes, for instance in the aircraft industry. In order to obtain large panels of such laminates, and because metal sheets are available in limited widths only, typical laminates comprise abutting and/or overlapping metal sheet edges, extending along a length direction within a splicing region of the laminate. This may for instance occur in wings of aircraft, where the longitudinal (spanwise) direction of the wing corresponds to the length direction. A laminate comprising a splicing region is for instance known from US 5,429,326, which discloses a laminated body panel for aircraft applications. The panel comprises at least two metal layers with a typical thickness of 0.3 mm, and an adhesive layer provided in between the metal layers. Some metal layers are composed of two or more metal sheets which are generally disposed coplanar in a layer and separated by a splice or splice line extending in a length direction of the laminate. Splices in a metal layer are typically staggered with respect to splices provided in other metal layers in order to prevent the laminate from weakening too much. Using splices in a laminate no longer restricts the maximum width of a laminate to a metal sheet width that is limited by present day metal sheet manufacturing technology. In some laminates, the splice region of the laminate is covered with a splice strap or doubler to prevent exposure of the splices to environmental conditions, and to strengthen the laminate in a direction transverse to the length direction of the laminate.

The known laminate may suffer from internal stresses, for instance induced by their manufacturing process. The internal stresses may negatively affect strength and fatigue life of the laminate, which strength and fatigue life are an important design parameter, in particular for aircraft structures. The negative effects on strength and fatigue life may be worsened in laminates having relatively thick and/or stiff metal layers, in particular exceeding 0.3 mm for aluminum layers, and /or at relatively low temperatures, for instance below 0°C. It is an object of the present invention to provide a laminate with an adequate strength and / or adequate stiffness and improved fatigue behavior.

SUMMARY OF THE INVENTION This and other objects are achieved by providing a laminate in accordance with claim 1.

The laminate comprises a stack of mutually bonded layers of adhesive and metal sheets, wherein an outer metal sheet defining an outer surface of the stack is a spliced metal sheet with abutting metal sheet edges extending along a length direction and forming a splice within a splicing region; and a splice strap connected to the outer surface of the stack and extending in the length direction and in a transverse direction perpendicular to the length direction across said splicing region over a splicing region width, the splice strap comprising mutually bonded layers of at least one adhesive layer and at least one metal sheet, wherein a splice strap adhesive layer is provided for connection to the outer surface;

wherein the following relation is satisfied within the splicing region:

wherein is defined as the shear stiffness of the laminate, i.e. including the splice strap

is defined as the shear stiffness of the stack of mutually bonded layers of adhesive and metal sheets, wherein the metal sheets do not have a splice in the metal sheets. does not

include the splice strap. As such, is a shear stiffness of the stack of mutually bonded

layers of adhesive and metal sheets having no splices in the metal sheets and having no splice strap attached to the stack. Please note that the shear stiffness has the dimensions of N/m, whereas a shear modulus has the dimensions of N/m 2 .

The shear stiffness of the laminate is defined by:

wherein m = the number of layers in the splice strap; l, is the thickness of the j lh layer in the splice strap; and Gj is the shear modulus of the j th layer in the splice strap.

The shear stiffness of the stack G stack is defined by:

wherein n = the number of layers in the slack; t i is the thickness of the i* layer in the slack, and Gj is the shear modulus of the i th layer in the stack; and wherein G; = 0 for the outer spliced metal sheet in the stack and wherein Gi = 0 for any two other spliced metal sheets in the stack within the splicing region that are adjacent to each other and have splices that are within a distance in the transverse direction of 5 times the larger thickness t i of the two spliced metal sheets. By using these equations, the shear stiffness of the laminate can easily be determined.

Furthermore, the shear stiffness of the stack of mutually bonded layers of adhesive and metal sheets, wherein the metal sheets do not have a splice in the metal sheets, is defined by:

wherein n = the number of layers in the stack; t i is the thickness of the i th layer in the stack, and Gi the shear modulus of the i th layer in the stack. As the metal sheets do not have a splice, all metal layers are taken into account in the calculation.

As defined herein, the shear modulus of each layer, Gi or Gj, is defined in the same direction as the shear stiffness of the whole stack and of the whole laminate For

instance, when the shear stiffness is to be calculated between the length and the transverse

directions, the appropriate shear moduli are those acting between the length and the transverse direction of the laminate.

The shear modulus of each layer, G; or Gj, may be determined experimentally, such as by using ASTM E143 - 13. Alternatively, and preferably, the shear modulus of each layer, Gj or G j , is calculated from tensile elastic moduli of the layer. For example, when calculating the shear modulus of an isotropic layer, such as a metal sheet, the shear modulus is defined by:

G = E / (2(l+v));

wherein G is the shear modulus of the isotropic layer; E is the tensile elastic modulus of the isotropic layer and v is the Poisson's ratio. For determining the elastic constants of a fiber- reinforced composite ASTM 3039 is commonly used. For determining the elastic constants of a metal, ASTM El 11 is commonly used.

When calculating the shear modulus of a non-isotropic layer, such as an adhesive layer containing reinforcing fibers under some angle(s), the shear modulus of the layer may be determined by the appropriate formulae for fiber composite materials. These formulae are well known to one skilled in the art and may be found in handbooks of composite materials, such as for instance "Mechanics of composite materials" by Robert M. Jones, ISBN 0-07-032790-4. The laminate in accordance with the invention has inter alia an improved fatigue life. An improved fatigue life, in the context of the present application means that the laminate may have a lower crack growth rate and/or higher number of load cycles to failure at a certain load. The splicing region in the laminate is defined as that region of the laminate wherein splice lines between abutting metal sheets and/or overlapping edge parts occur in at least one of the outer metal sheet layers of the laminate. The splicing region in a transverse direction (perpendicular to the length direction) of the laminate extends across at least one abutting edges of metal sheets or across at least one edge of a metal sheet that overlaps with another metal sheet. The adhesive layer between metal sheets is preferably continuous through the splicing region and therefore bridges splice lines and the like. A spliced layer in the laminate comprises two abutting metal sheets and/or two metal sheets with overlapping edge parts.

The shear stiffness of the laminate including the splice strap is at least 0.5 times the shear

stiffness of the stack of mutually bonded layers of adhesive and metal sheets without

splice. In this way, the shear stiffness of the spliced laminate at the splice strap supports a torsional stiffness of the laminate. In an example, such a laminate according to the present invention, when used in a wing of an aircraft, provides improved fatigue life. The shear stiffness of the laminate including the splice strap is at most 1.5 times the shear stiffness of the stack

of mutually bonded layers of adhesive and metal sheets without splice.

The adhesive layers in the laminate and/or the splice strap for some embodiments may be used as such. Preferred embodiments of the invention however provide a laminate and/or splice strap wherein the adhesive layers comprise reinforcing fibers to form a fiber-metal laminate and/or splice strap.

The splice strap extends across the splicing region, by which is meant that the width of the splice strap covers at least the width of the splicing region or a part of the width of the splicing region. The wording 'substantially' in the context of the present inventions means at least 90% of the indicated variable or subject.

Connecting the splice strap to the laminate may be achieved by any means such as by mechanical means or by an adhesive. Any adhesive may be used, including the same adhesive as that used in the adhesive layers of the laminate. Such adhesive may be applied as a separate layer. The strap bonding adhesive layer may also be provided with reinforcing fibers, if desired. It is also possible that the strap layer comprises a fiber reinforced adhesive layer, for instance in the form of a prepreg. Such splice strap may be bonded to the laminate as such, and the adhesive within the splice strap will partly form the adhesive layer connecting the splice strap to the laminate.

The splice strap in useful embodiments comprises a metal strip, for instance made from the same metal as the laminate metal sheets. In accordance with another embodiment of the invention, a laminate is provided wherein the splice strap comprises stacked splice strap layers, preferably of fiber-reinforced adhesive, in another embodiment of metal sheets, and in yet another embodiment of a combination of mutually bonded metal sheets and fiber-reinforced adhesive layers. The stacking sequence of the splice strap can be provided outside-in or, preferably, inside-out; meaning respectively that the smallest layer is adjacent to the laminate, or the widest strap layer is adjacent to the laminate

In an embodiment of the invention, the shear stiffness of the laminate including the splice strap is in the range at least 0.75 times the shear stiffness of the stack of mutually

bonded layers of adhesive and metal sheets without splice.

In a further embodiment of the invention, the shear stiffness of the laminate including the

splice strap is in the range at most 1.25 times the shear stiffness of the stack of

mutually bonded layers of adhesive and metal sheets without splice.

In yet another embodiment of the invention, the shear stiffness of the laminate including the splice strap is in the range at least 0.85 times the shear stiffness of the stack of

mutually bonded layers of adhesive and metal sheets without splice. In a further preferred embodiment of the invention, the shear stiffness of the laminate

including the splice strap is in the range at most 1.10 times the shear stiffness of the

stack of mutually bonded layers of adhesive and metal sheets without splice.

Although the invented laminate may be used in conjunction with any type of discontinuity in the laminate stack, an embodiment of the invention relates to a laminate comprising spliced metal sheets with abutting metal sheet edges. The advantages of the invention are particularly apparent for these types of splices.

In an embodiment of the invention, at least one of the adhesive stack layers of the stack comprises reinforcing fibers forming a fiber-reinforced adhesive stack layer. The fibers reinforce the stack thereby improving the mechanical strength and/or the crack growth performance. In an embodiment of the invention, at least one of the adhesive splice strap layers comprises reinforcing fibers forming a fiber reinforced adhesive splice strap layer. In an embodiment of the invention, at least 30% of the reinforcing fibers in the stack are oriented at an acute angle with the length direction within the splice strap region, the acute angle being within the range between - 45° and 45° with respect to the length direction, more preferably within the range between -30° and 30° with respect to the length direction, and most preferably within the range between -15° and 15° with respect to the length direction.

In a preferred embodiment, at least 50% of the reinforcing fibers in the stack are oriented at an acute angle with the length direction within the splice strap region, the acute angle being within the range between - 45° and 45° with respect to the length direction, more preferably within the range between -30° and 30° with respect to the length direction, and most preferably within the range between -15° and 15° with respect to the length direction.

In an embodiment, at least 65% of the reinforcing fibers in the stack are oriented along said acute angle with respect to the length direction. In an embodiment, at least 75%, and more preferably at least 90% of the reinforcing fibers in the stack are oriented along said acute angle with respect to the length direction.

In an embodiment, at least 50% of the reinforcing fibers in the splice strap are oriented at an acute angle with the transverse direction within the splice strap region, the acute angle being within the range between - 45° and 45° with respect to the transverse direction, more preferably within the range between -30° and 30° with respect to the transverse direction, and most preferably within the range between -15° and 15° with respect to the transverse direction.

In a preferred embodiment, at least 50% of the reinforcing fibers in the stack are oriented at an acute angle with the length direction within the splice strap region, the acute angle being within the range between -15° and 15° with respect to the length direction, and at least 50% of the reinforcing fibers in the splice strap are oriented at an acute angle with the transverse direction within the splice strap region, the acute angle being within the range between -15° and 15° with respect to the transverse direction. In this way, the fibers in the stack provide strength along the length direction while the fibers in the splice stack enhance the shear stiffness of the laminate. This combination is especially beneficial for providing adequate strength and improved fatigue behavior. In an embodiment, the thickness of the spliced metal layer of the stack is at least 0.3 mm, more preferably between 0.3 mm and 1.3 mm, even more preferably between 0.4 mm and 1.2 mm, and most preferably between 0.6 mm and 1.0 mm. The thickness of the metal sheets in the laminate is typically limited to 5-10 mm, in accordance with generally accepted definitions of what constitutes a foil, a sheet and a plate.

In an embodiment, the spliced metal sheet comprises the metal sheet in the stack that is in contact with the splice strap.

In an embodiment, the spliced metal sheet comprises the thickest metal sheet in the stack.

In an embodiment, the blunt notch strength of the laminate at a location of the splicing region lam is in the range of about is the tensile strength of

the stack of the laminate without the splice in the metal sheet, preferably is equal to or more than 0.85 * more preferably is equal to or more than 0.95

In an embodiment, a splice strap layer most closely arranged to the outer surface of the stack extends over a total transverse distance of at least 25 times the thickest metal sheet in the stack, more preferably over a total transverse distance of at least 50 times the thickest metal sheet in the stack.

In an embodiment, the splice strap comprises a metal sheet layer that is connected to the laminate with an adhesive layer and/or a layer of fiber-reinforced adhesive.

In an embodiment, an outer surface of the splice strap is flush with an outer surface of the stack.

The strap may comprise a number of strap layers, of which one is the widest splice strap layer. In such an embodiment, less wide strap layers may be closer to the laminate's outer surface than the widest strap layer. The widest strap layer may thus be connected to the laminate at its sides only, for instance symmetrically with respect to its central extension. The widest splice strap layer is then connected to the laminate over a transverse distance of at least 5 times the widest strap layer thickness at both sides of the splice strap layer. In case the splice strap comprises one layer only, the widest splice strap corresponds to this one strap layer. The strap may also comprise a number of strap layers of equal width. In this case, all the strap layers can be considered as the widest strap layer. According to the invention, the splice strap or a widest splice strap layer is connected to the laminate over a transverse distance of at least 10 times the widest strap layer thickness. In more preferred embodiments, a widest splice strap layer is connected to the laminate over a transverse distance of at least 25 times the widest strap layer thickness, even more preferred over at least 50 times the widest strap layer thickness, even more preferred over at least 80 times the widest strap layer thickness, even more preferred over at least 100 times the widest strap layer thickness, and most preferred over at least 200 times the widest strap layer thickness. Other preferred

embodiments relate to a laminate, wherein the widest splice strap layer is connected to the laminate over a transverse distance of at most 500 times the widest strap layer thickness, more preferably over at most 400 times the widest strap layer thickness, and most preferred over at most 300 times the widest strap layer thickness.

A particularly useful embodiment offers a laminate wherein the splice strap layers each have a width in the transverse direction across the splicing region, and the width of the layers decreases over the splice strap thickness towards the laminate to form staggered layers. In another embodiment, the splice strap layers each have a width in the transverse direction across the splicing region and the width of the layers increases over the splice strap thickness towards the laminate to form staggered layers.

The splice strap layers may be staggered on one or both sides of the splice strap to provide a splice strap with staggered edges. In an embodiment of the invention, the laminate is characterized in that the splice strap layers are staggered on each side of the splice strap by a length of at least 5 times the widest strap layer thickness, and more preferably by a length of at least 10 times the widest strap layer thickness. In another embodiment, a laminate is provided wherein the splice strap comprises a staircase edge over a stair cased transverse distance, and a virtual splice strap with a thickness equal to the thickness of the widest stair has a lower bending stiffness than the bending stiffness of one of the spliced metal sheets. A splice strap with tapered edges may have a continuously tapered edge, for instance linear, and/or a continuous variable edge, for instance parabolic. It is also possible to provide staircased edges, the staggered edges then showing discontinuities. In a further embodiment, the splice strap layers each have a width in the transverse direction across the splicing region, and the width of the layers is equal over the splice strap thickness, wherein the splice strap (the assembly of all bonded splice strap layers) has a lower bending stiffness than the bending stiffness of one of the spliced metal sheets. The splice strap extends in the trans verse direction of the laminate across at least a part of the splicing region. However, in some embodiments, the splice strap may extend across the splicing region or even beyond the splicing region. In further embodiments, the splice strap may even extend in the transverse direction of the laminate over substantially the complete laminate width. According to the invention, a laminate may be provided wherein an outer surface of the splice strap protrudes from the outer surface of the laminate by an off-set thickness, for instance ranging from 0% to more than 100% of the splice strap thickness. In a preferred embodiment, the off-set thickness is 0 (zero), and the outer surface of the splice strap is flush with the outer surface of the laminate. In such embodiment, the splice strap is embedded in the laminate and a substantially smooth outer surface of the laminate ensues. In embodiments having a non-zero off-set thickness, the splice strap protrudes from an outer surface of the laminate in the splicing region and a discontinuous outer surface of the laminate ensues in the splicing region. This will in particular embodiments provide a ridge that extends in the length direction of the laminate. The laminate according to the invention in some embodiments needs to accommodate a splice strap and/or overlapping metal sheet edges in the thickness direction. In order to provide a smooth continuous outer surface of the laminate, some metal sheets then are provided with a lower thickness or need to be deformed. A useful embodiment of the invention therefore provides a laminate wherein the splicing region comprises deformed metal sheets.

In embodiments wherein the splice strap extends substantially parallel to the length direction of the laminate, the deformed metal sheets are preferably bend along a line parallel to the length direction. Deforming metal sheets in the laminate may produce a laminate wherein, in an embodiment, the outer surface of the laminate is substantially smooth and a second outer surface opposite said outer surface is curved. The outer surface is then typically used as outbound surface of an aircraft component for instance, whereas the curved second outer surface is used as inbound surface of the aircraft component. The inbound surface may typically be covered with interior cladding and the like.

The laminates according to the present invention preferably comprise from 0 to 50 metal layers and about 1 to 49 adhesive layers. The metal layers may have any thickness such as the relatively thin metal layers of the prior art spliced laminates. Metal sheet thicknesses of between 0.1 and 2 mm may be used. The metal sheets in the present invention preferably have a thickness of more than 0.2 mm, more preferably more than 0.3 mm, and most preferably more than 0.6 mm.

The splice strap according to the invention preferably comprises from 0 to 8 metal layers and/or from 0 to 8 fiber-reinforced adhesive layers. The layers may have any thickness as long as the requirements of claim 1 are satisfied.

The metal sheets are preferably made from a metal having a tensile strength of more than 200 MPa. Examples of suitable metals are aluminum alloys, steel alloys, titanium alloys, copper alloys, magnesium alloys, and aluminum matrix composites. Aluminum-copper alloys of the AA2000 series, aluminum manganese alloys of the AA3000 series, aluminum-magnesium alloys of the AA5000 series, aluminum-zinc alloys of the AA7000 series, and aluminum-magnesium-silicon alloys of the AA6000 series are preferred. Some particularly preferred alloys are AA2024 aluminum-copper, AA5182 aluminum alloy, AA7075 aluminum-zinc, and AA6013 aluminum- magnesium-silicon. When improved corrosion resistance is desired, a sheet of AA5052 alloy or AA5024, AA5083 or AA5182 alloy may be included in the laminate. The laminates may also comprise metal sheets of a different alloy. Other useful alloys comprise aluminum-lithium alloys, such as AA2090, AA2098, and AA2198 alloys.

The adhesive layers of the laminate and/or splice strap are in preferred embodiments provided with reinforcing fibers, which fibers preferably bridge the splice lines and metal sheet edge overlaps and therefore are continuous across the splicing region. The reinforcing fibers may be oriented in one direction or in several different directions, depending on the loading conditions of the laminate structure. Preferred reinforcing fibers comprise continuous fibers made of glass, aromatic polyamides ("aramids"). carbon, basalt, and/or polymeric fibers such as PBO for instance.

Preferred glass fibers include S-2, S-3 and/or R-glass fibers, as well as carbonized silicate glass fibers, although E-glass fibers are also suitable. Preferred fibers have a modulus of elasticity of between 60 and 650 GPa, and an elongation at break of between 0.1 and 8%, preferably above 1.6%, more preferably above 2.0%, and most preferably above 3.0%

The adhesive layers preferably comprise synthetic polymers. Suitable examples of thermosetting polymers include epoxy resins, unsaturated polyester resins, vinyl ester resins, and phenolic resins. Suitable thermoplastic polymers include polyarylates (PAR), polysulphones (PSO), poiyether sulphones (PES), poiyether irnides (PEI), polyphenylene ethers (PEE), polyphenylene sulphide (PPS), polyamide-4,6, polyketone sulphide (PKS), poiyether ketones (PEK), poiyether ether ketone (PEEK), poiyether ketoneketone (PEKK), and others. The laminate and/or splice strap may be provided with additional adhesive in certain areas, apart from the adhesive present in the adhesive layers. The thickness of the adhesive layers may be similar to that of the metal sheets but adhesive layers in the laminate and/or splice strap are preferably thinner.

The reinforcing fibers in the laminate and/or splice strap layers may be provided in the form of prepregs, an intermediate product of reinforcing fibers embedded in a partly cured thermosetting resin or in a thermoplastic polymer. Typically fiber volume fractions range from 15 to 75%, and more preferably from 20 to 65% of the total volume of adhesive and reinforcing fiber in the adhesive layers. The effective fiber volume fraction in an adhesive layer may be lowered by adding plain adhesive layers to reinforced adhesive layers.

The laminate in accordance with the invention may be manufactured by a method that comprises the steps of providing a forming substrate with an upper surface; providing a splice strap on the upper surface of the forming substrate, the splice strap extending over part of the forming substrate in a length direction across a splicing region; providing a stack of at least one adhesive layer and metal sheets, of which edges extend along the length direction and abut and/or overlap within the splicing region, the stack extending beyond the boundaries of the splice strap; the splice strap having a smaller thickness than a thickness of a metal sheet, positioned adjacent to the splice strap in the stack; and applying heat and pressure to the thus obtained stack. Metal sheets may deform across the splicing region during the application of heat and pressure, and the deformed shape may be consolidated. The shape may be consolidated by curing the thermosetting resin in the adhesive layers, or by lowering the temperature below the melt temperature of a thermoplastic polymer in case such polymer is used in the adhesive layers. The metal sheets will bend towards the splice strap. The metal sheets may be deformed elastically (below the elastic limit) and/or may be deformed plastically (beyond the plastic limit). Which type of deformation prevails depends on the type of metal used, on shape and dimensions, on manufacturing conditions, and more.

In useful embodiments of the invention, a splice strap comprises stacked layers of fiber-reinforced adhesive. Several of such layers are preferably applied to the forming substrate on top of each other to build up thickness.

Another aspect of the invention finally relates to a structural component for a vehicle, spacecraft, or aircraft, comprising a laminate according to one of the described embodiments, and in particular to an aircraft comprising such a laminate.

BRIEF DESCRIPTION OF THE FIGURES

The invention will now be further elucidated on the basis of the exemplary embodiments shown in the figures, without however being limited thereto. The same or similar elements in the figures may be denoted by the same or similar reference signs. In the figures:

Figure 1 - is a view in perspective of a fiber-metal laminate according to the state of the art;

Figure 2 - is a view in perspective of a fiber-metal laminate according to the state of the art;

Figure 3 - is a cross-sectional view in a transverse direction of a stack of the laminate used as a reference for the laminate of an embodiment of the present invention, which is shown in Figure 4; Figure 4 - is a cross-sectional view in a transverse direction of the laminate according to the embodiment of the present invention;

Figure 5 - is a plane view of the fatigue loading direction of the stack of the laminate shown in Figure 3;

Figure 6 - is a plane view of the fatigue loading direction of the laminate shown in Figure 3; Figure 7 - is a schematic illustration of the fatigue results of the stack of the laminate of Figure 3 and the embodiment of the laminate of figure 4;

Figure 8 - is a plane view of a blunt notch strength specimen, cut from the stack shown in Figure 3; and finally

Figure 9 - is a plane view of a blunt notch strength specimen, cut from the laminate shown in Figure 4 in accordance with an embodiment of the invention.

DETAILED DESCRIPTION OF EXEMPLARY EMBODIMENTS With reference to figure 1 , a fiber-metal laminate according to the state of the art is shown. The laminate has a total number of three layers, of which layers 1 and 3 comprise a metal layer and layer 2 comprises a fiber-reinforced adhesive layer. Alternatively, layer 1 and 3 may comprise a fiber-reinforced adhesive layer and layer 2 a metal layer. Layers 1 and 3 may comprise the same metal alloy or may be built from a different kind of metal alloy. The fiber-reinforced adhesive layers may contain fibers in multiple directions as well as different fiber types. The laminate is typically built by providing a forming substrate, providing a first layer 3 on the forming substrate and stacking layers 2 and 1 on top of layer 3 to produce a stack of layers 1 -3, which stack is then consolidated under the application of heat and pressure into a cured laminate.

As shown in figure 2, a fiber-metal laminate may comprise more layers up to a layer n, where n may range from 4 to more than 30 for instance. The outer layers 1 and n may be metal layers and/or fiber-reinforced adhesive layers. In the laminate, metal layers generally alternate with fiber- reinforced adhesive layers. Metal layers may be built from one metal sheet having a width in a transverse direction 25 that is sufficiently large to cover the entire width 6 of the laminate. As shown in figure 2, metal sheets may not be available in widths covering the entire width 6 of the laminate, and metal layers may have to be built up of at least two metal sheets with abutting metal sheet edges that form a splice 7, extending along a length direction 24 of the laminate within a splicing region 8 of the laminate (an extension of one splice line only is shown in figure 2 for clarity reasons and as minimum coverage area of the strap). The at least two metal sheets may also comprise overlapping edge parts within a splicing region 8.

Experiments

Fatigue tests were performed on a fiber/metal laminate as shown in figure 3, as well as on a spliced laminate as shown in figure 4. The laminate of figure 4 comprises a spliced aluminum sheet having a constant thickness of 1.3 mm. A splice strap is attached to an outer surface of the spliced sheet and comprises 3 layers of S2-glass prepreg and an outer aluminum sheet having a constant thickness of 0.3 mm. The laminate of figure 3 is used as a reference and comprises a stack of layers 11-19. Layer 11 is a sheet of aluminum 2024-T3 with a nominal thickness of t = 1.3 mm. The layers 13, 15, 17, 19 comprise sheets of aluminum 2024-T3 with a nominal thickness of t = 0.4 mm. The layers 12, 14, 16, 18 are S2-glass prepreg layers with a nominal thickness of t = 0.26 mm and a fiber direction along a length direction 24, which is perpendular to the plane of viewing. The laminate of figure 3 does not have a splice in any of the aluminum layers (11, 13, 15, 17, 19). An embodiment of a laminate according to the present invention is shown in figure 4. The laminate comprises a stack of mutually bonded layers of adhesive and metal sheets 11 - 19, wherein a metal sheet 11 is a spliced metal sheet with abutting metal sheet edges extending along a length direction within a splicing region 7. Sheet 1 1 is split in two parts (1 1 a, l ib) that extend at both sides from a splice 28 running along the length direction 24. Furthermore the laminate comprises a splice strap 20 connected to an outer surface of the stack and extending across said splicing region 7 over a certain width in a transverse direction 25 perpendicular to the length direction 24. The splice strap comprises a layer 21 of aluminum 2024-T3 having a nominal thickness of t = 0.4 mm and a width of 140 m in the transverse direction 25. The splice strap further comprises layers 22, 23, 26, which are S2-glass prepreg layers with a nominal thickness of t = 0.13 mm. Each of the prepreg layers 22, 23, 26 comprises fibers, which are running substantially along the transverse direction 25 as indicated in figure 4. Layer 27 is an adhesive layer, which is provided to connect the splice strap 20 to the stack of the laminate. The width of the layer 22 is 1 10 mm, the width of the layer 23 is 80 mm; the width of the layer 26 is 50 mm; and the width of the layer 26 is 30 mm, each along the transverse direction 25.

The layers 22, 23, 26, 27 are arranged as staggered layers, wherein the widest layer 22 is arranged away from the stack of the laminate. The structure is flush at the strap side.

Shear stiffness

Aluminum 2024-T4 has a tensile ultimate strength of TUS = 465 MPa and an elastic (Young's) modulus E = 72.4 GPa. Consequently the shear modulus of the aluminum sheets is G = 0.38 * 72.4 = 27.51 GPa. Indeed, the Poisson's ratio v = 0.32.

The shear modulus of each of the fiber reinforced composite layers (12, 14, 16 and 18) can be calculated according to the Halpin-Tsai equations, known in the art, to be G = 5 GPa. The fibers in the composite layers (12, 14, 16, 18) extend in the transverse direction 25 and therefore do not substantially contribute to the strength of the laminate in the length direction 24 perpendicular to the transverse direction 25. The composite layers (between two successive metal layers) each have a thickness of t = 0.266 mm. The tensile ultimate strength of the S2 glass fibers TUS = 4,890 MPa.

The prepregs applied in each of the composite layers have a fiber volume fraction FVF =57%

The above result in a calculated shear modulus G stack = 27.51 * (1.32 + 4 * 0.38) + 5 * 4 * 0.266 = 83.5 GPa*mm. In the laminate shown in figure 4, the splice area 7 and splice 28 are covered by 3 layers of S2 glass prepreg 22, 23, 26 with reinforcing fibers running perpendicular to the transverse direction 25, each with a thickness of t = 0.133 mm and over it an aluminium 2024-T3 sheet 21 with a thickness of t = 0.3 mm.

The shear modulus of this combination is G kim = 27.51 * (0.27 + 4 * 0.38) + 5 * 4 * 0.266 + 5 * 3 * 0.133 = 56.6 GPa*mm. So the ratio between G ]am and G sta ck is 0.68 and the laminate of figure 4 therefore fulfils the requirements of the claimed invention. Fatigue results

The laminates according to figures 4 and 5 were subject to fatigue tests. Figure 5 shows a plane view of a fatigue specimen comprising a laminate according to figure 3. The fatigue loading direction of the laminate is parallel to the transverse direction 25 shown in figures 3 and 5. Figure 6 shows a plane view of a fatigue specimen comprising a laminate according to figure 4. The fatigue loading direction of the laminate again is parallel to the transverse direction 25 shown in figures 3 and 5.

The specimens as shown in figures 5 and 6 have a central crack 34 (saw cut) of about 4 mm extension. The crack in the laminate with splice 28 and strap 20 is applied at the splice location of this specimen. The fatigue loading direction is along the transverse direction 25 and therefore perpendicular to the extension of the saw cut 34.

A constant amplitude cycling test was applied at a maximum stress of 100 MPa and a minimum stress of 5MPa. The stress level of the spliced laminate with strap was determined by the cross section outside the strap location.

Figure 7 shows the fatigue test results of the two configurations of figure 3 and 4. The fatigue results for the laminate of figure 3 are annotated with V, while the fatigue crack growth results for the laminate with splice and strap of figure 4 are shown with the annotations S] (for crack growth at the underside of the stack) and with S s (for the crack growth at the side of the strap).

The spliced laminate with strap of figure 4 has a significant higher fatigue life compared to the stack of figure 3. The fatigue life of the spliced laminate with strap is at least 50% longer than the fatigue life of the laminate of figure 3. Secondly, a significant difference in fatigue crack growth could be observed for the spliced laminate with the crack at the strap side compared to the opposite side of this laminate.

Thirdly, the stack of Figure 3 test panel showed complete failure at about 45.000 cycles, while the spliced laminate with strap at 70,000 cycles was still in tact.

Blunt Notch Strength

The blunt notch strength of the laminate including the splice strap can be compared to the blunt notch strength of the stack of the laminate without a splice in any of the metal sheets and without the splice strap. The blunt notch strength can be determined experimentally, as described in relation to Figures 8 and 9.

For test specimens see Figures 8 and 9 showing a stack of the laminate specimen and a laminate with strap, respectively. In Figure 8 is shown in a plane view a test specimen of the stack without a splice shown in figure 3. In Figure 9 is shown in a plane view a test specimen of the laminate in accordance with the embodiment shown in figure 4. A circular hole 44 is provided in each of the laminates having a diameter of 6.35 mm. In the laminate shown in Figure 9, the circular hole 44 is arranged centrally within the splicing region 7 in both the length direction 24 and the transverse direction 25. The circular hole 44 is arranged at the splice 28 of the outer metal sheet of the stack of the laminate. The loading direction in the blunt notch strength test is along the transverse direction 25.

The test results of the blunt notch strength test show that:

According to the experimentally determined blunt notch strength, the ratio

between the blunt notch strength of the laminate including the strap and the blunt notch

strength of the stack is 0.88.