PL248762B1 - Metal-carbon laminate and method of producing it - Google Patents

Abstract

The subject of the application is a metal-carbon laminate, which is characterized in that in the central part of the laminate there is a first self-healing layer (1) with a thickness of 1 mm to 2 mm, consisting of glass fibers filled with isophorone diisocyanate and bonded with a thermoplastic resin, to both surfaces of which two layers of a thermoplastic composite based on carbon fibers (2) with a thickness of 0.04 mm each are adhesively adhered, to which a layer of polyester nonwoven fabric (3) with a basis weight of 339 g/m² and a thickness of 4 mm to 8 mm is adhesively adhered. Two layers of a thermoplastic composite based on carbon fibers (2) each 0.04 mm thick are adhesively adhered to the polyester nonwoven fabric layer (3), which are adhesively adhered to a second self-healing layer (4) 0.2 mm to 0.4 mm thick, consisting of microcapsules ranging from 25 µm to 100 µm in size, each consisting of a polyurethane coating of toluene diisocyanate polyisocyanurate in ethyl acetate in an amount of 48.8% by weight and a filler of isophorone diisocyanate in an amount of 51.2% by weight and carbon nanotubes ranging from 20 nm to 100 nm in size combined with a thermoplastic resin. The application also covers a method of producing a metal-carbon laminate, which consists in applying on both sides of two sheets (6) of a 1 mm thick nickel-titanium alloy having on both surfaces a ceramic layer (5) of a thickness of 5 µm to 12 µm microcapsules of a size of 25 µm to 100 µm, each of which consists of a polyurethane coating of toluene diisocyanate polyisocyanurate in ethyl acetate in an amount of 48.8% by weight and a filler of isophorone diisocyanate isocyanate in an amount of 51.2% by weight and carbon nanotubes of a size of 20 nm to 100 nm, wherein the microcapsules and carbon nanotubes are manually coated with a thermoplastic resin, and a second self-healing layer (4) of a thickness of 0.2 mm to 0.4 mm is obtained. Then, two layers of a thermoplastic composite based on carbon fibers (2), each 0.04 mm thick, are applied to one of the sheets (6) made of a 1 mm thick nickel-titanium alloy, having on both surfaces a ceramic layer (5) with a thickness of 5 µm to 12 µm and a second self-healing layer (4) with a thickness of 0.2 mm to 0.4 mm. Then, a layer of polyester nonwoven fabric (3) with a basis weight of 339 g/m² and a thickness of 4 mm to 8 mm is applied.

Description

Description of the invention

The subject of the invention is a metal-carbon laminate and a method of producing a metal-carbon laminate.

The most commonly known metal-fiber laminates are aluminum-based laminates with epoxy layers infused with glass, aramid, and carbon fibers. Currently, laminates called Glare®, based on an aluminum alloy with a polymer layer infused with glass fibers, are used in aviation. However, new technological and material solutions are being sought to reduce operating costs, particularly in the aviation and space industries, where fuel is expensive. Furthermore, the goal is for new materials to be lighter than previous ones while maintaining the same or even better strength and corrosion properties.

European patent description No. EP2576212 B1 describes a layered material comprising a fibrous, filamentary, particle or foam layer, wherein the fibers or continuous fibers are arranged parallel or perpendicular to each other.

A composite laminate with a self-healing layer is known and used from the US patent application No. US20130209764 A1, wherein the composite structure comprises a plurality of layers of composite material and at least one layer of self-healing material.

Additionally, U.S. Patent Application No. US20090191402 A1 discloses a laminate comprising a first layer composed of an elastomeric resin and a self-healing capsule-based layer bonded thereto. The laminate exhibits self-healing properties when a low-energy force is applied to the self-healing layers.

US Patent No. US9127915 B1 describes lightweight composite materials that are resistant to ballistic energy and fire. Their structure incorporates a semi-crystalline thermoplastic and nanoparticles that can create a self-healing layer.

In the article entitled “Recovery of Mode I self-healing interlaminar fracture toughness of fiber metal laminate by modified double cantilever beam test”, L. Shanmugam, M. Naebe, J.K. Russell, J. Varley and J. Yang in Composites Communications Volume 16, December 2019, Pages 25-29, a metal-fiber laminate consisting of thin metal sheets and a self-healing polymer layer and a polymer layer containing carbon fibers was presented.

The article entitled “The interlaminar resistance of carbon fiber-A1 laminate reinforced with hollow and core-shell microcapsules” by M.D. Shokrian, K. Shelesh-Nezhad, R. Najjar and E. Bigdeli Theoretical and Applied Fracture Mechanics Volume 110, December 2020, 102778 presents metal-fiber laminates based on aluminum and carbon composite containing carbon fibers, where a layer of microcapsules is used as a self-healing layer.

In the article entitled “Low Velocity Impact Behavior of Sandwich Composite Structures with E-Glass/Epoxy Facesheets and PVC Foam” by A. C. Balaban, K. F. Tee and M. E. Toygar describes sandwich structures consisting of two outer layers of polymer-glass composite fabric and a middle layer of PVC foam.

The article by J. Zhou, M. Z. Hassan, Z. Guan, W. J. Cantwell entitled "The low velocity impact response of foam-based sandwich panels" from the journal "Composite Science and Technology" describes laminates consisting of an inner layer of 20 mm thick PVC foam and two outer layers of composite fabric made of E-glass fibers and thermosetting resin.

The article by P. Jakubczak, M. Droździel, P. Podolak, J. Pernas-Sanche entitled "Experimental Investigation on the Low Velocity Impact Response of Fiber Foam Metal Laminates" describes metal-fiber laminates containing foam or nonwoven fabric in the structure using epoxy resin.

The aim of the invention is to produce a metal-carbon laminate resistant to impact and corrosion for use in the automotive and space industries.

The essence of the metal-carbon laminate having a layer of polyester nonwoven fabric with a basis weight of 339 g/ ^m2 , according to the invention, is that the central part of the laminate contains a first self-healing layer with a thickness of 1 mm to 2 mm, consisting of glass fibers filled with isophorone diisocyanate and bonded with a thermoplastic resin. Two layers of a thermoplastic composite based on carbon fibers, each 0.04 mm thick, are adhesively adhered to both surfaces of the first self-healing layer, to which a layer of polyester nonwoven fabric with a basis weight of 339 g/ ^m2 and a thickness of 4 mm to 8 mm is adhesively adhered.

Two layers of a thermoplastic composite based on carbon fibers, each 0.04 mm thick, are adhesively adhered to the polyester nonwoven fabric layer, which are adhesively adhered to a second self-healing layer, 0.2 mm to 0.4 mm thick, consisting of microcapsules ranging in size from 25 μm to 100 μm, each consisting of a polyurethane coating of toluene diisocyanate polyisocyanurate in ethyl acetate in an amount of 48.8% by weight and a filler of isophorone diisocyanate in an amount of 51.2% by weight and carbon nanotubes ranging in size from 20 nm to 100 nm combined with a thermoplastic resin. The second self-healing layer is applied over a 5 μm to 12 μm thick ceramic layer located on a 1 mm thick nickel-titanium alloy sheet having on its outer surface a 5 μm to 12 μm thick ceramic layer with a 0.2 mm to 0.4 mm thick second self-healing layer applied thereto.

The essence of the method for producing a metal-carbon laminate, according to the invention, is that on two sheets of a 1 mm thick nickel-titanium alloy sheet having on both surfaces a ceramic layer of a thickness of 5 μm to 12 μm, microcapsules of a size of 25 μm to 100 μm are applied on both sides, each of which consists of a polyurethane coating of toluene diisocyanate polyisocyanurate in ethyl acetate in the amount of 48.8% by weight and a filling of isophorone diisocyanate isocyanate in the amount of 51.2% by weight and carbon nanotubes of a size of 20 nm to 100 nm, wherein the microcapsules and carbon nanotubes are manually coated with a thermoplastic resin, and a second self-healing layer of a thickness of 0.2 mm to 0.4 mm is obtained. Two layers of a 0.04 mm thick carbon fiber-based thermoplastic composite are then applied to a 1 mm thick nickel-titanium alloy sheet having a 5 μm to 12 μm thick ceramic layer on both surfaces and a second self-healing layer 0.2 mm to 0.4 mm thick. A layer of 339 g/m2 polyester nonwoven fabric ⁴ mm to 8 mm thick is then applied, followed by two layers of a 0.04 mm thick carbon fiber-based thermoplastic composite, each layered, followed by a 0.5 mm to 1 mm thick layer of isophorone diisocyanate-filled glass fibers, which are then hand-laminated with a thermoplastic resin, to obtain a 1 mm to 2 mm thick self-healing first layer consisting of isophorone diisocyanate-filled glass fibers bonded with a thermoplastic resin. Next, two layers of a 0.04 mm thick carbon fiber-based thermoplastic composite are applied to the first self-healing layer, followed by a 4 mm to 8 mm thick polyester nonwoven layer weighing 339 g/ ^m² . Two layers of a 0.04 mm thick carbon fiber-based thermoplastic composite are applied to the polyester nonwoven layer. Next, a second 1 mm thick nickel-titanium alloy sheet is applied, with a 5 μm to 12 μm thick ceramic coating on both surfaces, and a second self-healing layer, 0.2 mm to 0.4 mm thick. A vacuum pack is then applied and the air is evacuated to a negative pressure of -0.08 MPa. The entire assembly is then cured for 24 hours at 23°C.

It is advantageous to apply two layers of a thermoplastic composite based on carbon fibers in an orientation of 0°/0° or 0°/90° or +45°/-45°.

It is advantageous to apply a layer of glass fibers filled with isophorone diisocyanate in an orientation of 0° or 90° or +45°.

A beneficial effect of the invention is that a metal-carbon laminate with high resistance and absorption properties to low-velocity impacts and anti-corrosion properties is obtained. The applied layer containing glass fibers filled with a self-healing agent and microcapsules inhibits the development of cracks in the laminate, and after 24 hours, the laminate achieves self-healing. Furthermore, the polyester nonwoven layer additionally acts as an absorption layer against impacts. The addition of nanotubes to the microcapsules acts as a reinforcement for the self-healing layers.

The invention is presented in an embodiment in the drawing, which shows a cross-section of the laminate.

Example 1

The method for manufacturing a metal-carbon laminate consisted of 300 x 400 mm, 1 mm thick Nitinol sheets (6) made of a nickel-titanium alloy (53% by weight nickel and 47% by weight titanium) were activated on the surfaces of sheets (6) made of a nickel-titanium alloy (53% by weight nickel and 47% by weight titanium) in a 10% phosphoric acid solution and rinsed in water for 5 minutes. The nickel-titanium alloy sheets (6) were then anodized in an industrial alkaline solution consisting of 300 g of copper nitrate in 1000 ml of 5% phosphoric acid. The process time was 3 minutes, the voltage was 450 V ±46 V, and the frequency was 30 Hz. After the anodizing process, the nickel-titanium alloy sheets (6) were rinsed in water for 5 minutes and left to dry at 23°C. A 5 μm thick ceramic layer 5 was obtained on both surfaces of a nickel-titanium alloy sheet 6. Microcapsules of 25 μm size were deposited on both sides of the nickel-titanium alloy sheets 6 having a 5 μm thick ceramic layer 5 on both surfaces, each consisting of a polyurethane coating of toluene diisocyanate polyisocyanurate in ethyl acetate in an amount of 48.8% by weight and a filler of isophorone diisocyanate isocyanate in an amount of 51.2% by weight and carbon nanotubes of 20 nm size, the microcapsules being mixed with the nanotubes in a ratio of 1:25. Then, the microcapsules and carbon nanotubes were manually coated with a thermoplastic resin, and a second self-healing layer 4 with a thickness of 0.2 mm was obtained. Then, on one of the sheets 6 made of a 1 mm thick nickel-titanium alloy, having on both surfaces a 5 μm thick ceramic layer 5 and a second self-healing layer 4 with a thickness of 0.2 mm, two layers of a thermoplastic composite based on carbon fibers 2 were applied in the 0°/0° orientation, each with a thickness of 0.04 mm. Then, a layer of polyester non-woven fabric 3 with a basis weight of 339 g/m ² and a thickness of 4 mm was applied. Two layers of a thermoplastic composite based on carbon fibers 2 in the 0°/0° orientation direction, each 0.04 mm thick, were applied to the polyester nonwoven fabric layer 3, onto which a layer of glass fibers filled with isophorone diisocyanate was applied in the 0° orientation direction, each 0.5 mm thick, which was laminated manually with a thermoplastic resin to obtain a first self-healing layer 1 with a thickness of 1 mm, consisting of glass fibers filled with isophorone diisocyanate and bonded with a thermoplastic resin. Then, two layers of a thermoplastic composite based on carbon fibers 2 in the 0°/0° orientation direction, each 0.04 mm thick, were applied to the first self-healing layer 1, onto which a layer of a polyester nonwoven fabric 3 with a basis weight of 339 g/m ² and a thickness of 4 mm was applied. Two layers of carbon fiber-based thermoplastic composite 2, each 0.04 mm thick, were applied to the polyester nonwoven fabric layer 3, in a 0°/0° orientation. Next, a second sheet 6 made of a nickel-titanium alloy was applied, with a 5 μm-thick ceramic layer 5 on both surfaces and a second, 0.2 mm-thick self-healing layer 4. The entire assembly was then placed on an aluminum mold and, using a vacuum pack, air was extracted to a negative pressure of -0.08 MPa. The entire assembly was then subjected to a curing process at 23°C for 24 hours. A thermoplastic resin with the trade name Elium® 351 EOT from Arkema was also used in the metal-carbon laminate production process.

In the produced metal-carbon laminate, in the central part there is a first self-healing layer 1 with a thickness of 1 mm, consisting of glass fibers filled with isophorone diisocyanate and bonded with a thermoplastic resin, to both surfaces of which two layers of a thermoplastic composite based on carbon fibers 2 with a thickness of 0.04 mm each are adhesively adhered, to which a layer of polyester nonwoven fabric 3 with a basis weight of 339 g/m ² and a thickness of 4 mm is adhesively adhered. Two layers of a thermoplastic composite based on carbon fibers 2, each 0.04 mm thick, are adhesively adhered to the polyester nonwoven fabric layer 3, which are adhesively adhered to a second self-healing layer 4, 0.2 mm thick, consisting of 25 μm microcapsules, each consisting of a polyurethane coating of toluene diisocyanate polyisocyanurate in ethyl acetate in an amount of 48.8% by weight and a filler of isophorone diisocyanate isocyanate in an amount of 51.2% by weight and 20 nm carbon nanotubes mixed together in a ratio of 1:25 and combined with a thermoplastic resin. The second self-healing layer 4 is applied to a 5 μm thick ceramic layer 5 located on a sheet 6 made of a nickel-titanium alloy consisting of 53% nickel by weight and 47% titanium by weight - Nitinol with a thickness of 1 mm, which has a 5 μm thick ceramic layer 5 on the outer surface with a 0.2 mm thick second self-healing layer 4 applied thereto.

The resulting laminate was subjected to low-velocity impact testing, where self-healing properties were observed after 24 hours, restoring structural integrity. The laminate was subjected to low-velocity impact testing at speeds below 5 m/s and energy of 5 J. The laminate was characterized by the destruction of the carbon fiber layer upon impact, while the nonwoven layer stopped the crack growth to the underlying layer. Furthermore, the laminate demonstrated increased resistance to environmental factors, particularly corrosion in NaCl solution.

Example 2

The method for manufacturing a metal-carbon laminate consisted of 300 x 400 mm, 1 mm thick Nitinol sheets (6) made of a nickel-titanium alloy (57% by weight nickel and 43% by weight titanium) were activated on the surfaces of sheets (6) made of a nickel-titanium alloy (57% by weight nickel and 43% by weight titanium) in a 10% phosphoric acid solution and rinsed in water for 5 minutes. The nickel-titanium alloy sheets (6) were then anodized in an industrial alkaline solution consisting of 300 g of copper nitrate in 1000 ml of 5% phosphoric acid. The process time was 3 minutes, the voltage was 450 V ±46 V, and the frequency was 30 Hz. After the anodizing process, the nickel-titanium alloy sheets (6) were rinsed in water for 5 minutes and left to dry at 23°C. A 12 μm thick ceramic layer 5 was obtained on both surfaces of a nickel-titanium alloy sheet 6. 100 μm microcapsules were deposited on both sides of the nickel-titanium alloy sheets 6 having a 12 μm thick ceramic layer 5 on both surfaces, each consisting of a polyurethane coating of toluene diisocyanate polyisocyanurate in ethyl acetate in an amount of 48.8% by weight and a filler of isophorone diisocyanate isocyanate in an amount of 51.2% by weight and carbon nanotubes of 100 nm in size, the microcapsules being mixed with the nanotubes in a ratio of 1:25. Then, the microcapsules and carbon nanotubes were manually coated with a thermoplastic resin, and a second self-healing layer 4 with a thickness of 0.4 mm was obtained. Then, on one of the sheets 6 made of a 1 mm thick nickel-titanium alloy having on both surfaces a 12 μm thick ceramic layer 5 and a second 0.4 mm thick self-healing layer 4, two layers of a thermoplastic composite based on carbon fibers 2 were applied in the 0°/90° orientation direction, each 0.04 mm thick. Then, a layer of polyester non-woven fabric 3 with a basis weight of 339 g/m ² and a thickness of 8 mm was applied. Two layers of a thermoplastic composite based on carbon fibers 2 in the 0°/90° orientation direction, each 0.04 mm thick, were applied to the polyester nonwoven fabric layer 3, onto which a layer of glass fibers filled with isophorone diisocyanate in the 90° orientation direction, 1 mm thick, was applied, which was laminated manually with a thermoplastic resin, to obtain a first self-healing layer 1 with a thickness of 2 mm, consisting of glass fibers filled with isophorone diisocyanate and bonded with a thermoplastic resin. Then, two layers of a thermoplastic composite based on carbon fibers 2 in the 0°/90° orientation direction, each 0.04 mm thick, were applied to the first self-healing layer 1, onto which a layer of a polyester nonwoven fabric 3 with a basis weight of 339 g/m ² and a thickness of 8 mm was applied. Two layers of carbon fiber-based thermoplastic composite 2, each 0.04 mm thick, were applied to the polyester nonwoven fabric layer 3, aligned 0°/90°. Next, a second sheet 6 made of a nickel-titanium alloy was applied, with a 12 μm-thick ceramic layer 5 on both surfaces and a second, 0.4 mm-thick self-healing layer 4. The entire assembly was then placed on an aluminum mold and, using a vacuum pack, air was extracted to a negative pressure of -0.08 MPa. The entire assembly was then cured at 23°C for 24 hours. A thermoplastic resin with the trade name Elium® 351 EOT from Arkema was also used in the metal-carbon laminate production process.

In the produced metal-carbon laminate, in the central part there is a first self-healing layer 1 with a thickness of 2 mm, consisting of glass fibers filled with isophorone diisocyanate and bonded with a thermoplastic resin, to both surfaces of which two layers of a thermoplastic composite based on carbon fibers 2 with a thickness of 0.04 mm each are adhesively adhered, to which a layer of polyester nonwoven fabric 3 with a basis weight of 339 g/m ² and a thickness of 8 mm is adhesively adhered. Two layers of a thermoplastic composite based on carbon fibers 2, each 0.04 mm thick, are adhesively adhered to the polyester nonwoven fabric layer 3, which are adhesively adhered to a second self-healing layer 4, 0.4 mm thick, consisting of 100 μm microcapsules, each consisting of a polyurethane coating of toluene diisocyanate polyisocyanurate in ethyl acetate in an amount of 48.8% by weight and a filler of isophorone diisocyanate isocyanate in an amount of 51.2% by weight and carbon nanotubes of 100 nm in size mixed together in a ratio of 1:25 and combined with a thermoplastic resin. The second self-healing layer 4 is applied to a 12 μm thick ceramic layer 5 provided on a 1 mm thick Nitinol sheet 6 of a nickel-titanium alloy consisting of 57% nickel by weight and 43% titanium by weight, which has a 12 μm thick ceramic layer 5 on the outer surface with a 0.4 mm thick second self-healing layer 4 applied thereto.

The resulting laminate was subjected to low-velocity impact testing, where self-healing properties were observed after 24 hours, restoring structural integrity. The laminate was subjected to low-velocity impact testing at impacts below 5 m/s and energy of 10 J. The laminate was characterized by the destruction of the carbon fiber layer upon impact, while the nonwoven layer stopped the crack growth to the underlying layer. Furthermore, the laminate demonstrated increased resistance to environmental factors, particularly corrosion in NaCl solution.

Example 3

The method for manufacturing a metal-carbon laminate consisted of 300 x 400 mm, 1 mm thick Nitinol sheets (6) made of a nickel-titanium alloy (55% by weight nickel and 45% by weight titanium) were activated on the surfaces of sheets (6) made of a nickel-titanium alloy (55% by weight nickel and 45% by weight titanium) in a 10% phosphoric acid solution and rinsed in water for 5 minutes. The nickel-titanium alloy sheets (6) were then anodized in an industrial alkaline solution consisting of 300 g of copper nitrate in 1000 ml of 5% phosphoric acid. The process time was 3 minutes, the voltage was 450 V ±46 V, and the frequency was 30 Hz. After the anodizing process, the nickel-titanium alloy sheets (6) were rinsed in water for 5 minutes and left to dry at 23°C. A 10 μm thick ceramic layer 5 was obtained on both surfaces of a nickel-titanium alloy sheet 6. On both surfaces of the nickel-titanium alloy sheet 6 having a 10 μm thick ceramic layer 5, 50 μm microcapsules were deposited, each consisting of a polyurethane coating of toluene diisocyanate polyisocyanurate in ethyl acetate in an amount of 48.8% by weight and a filler of isophorone diisocyanate isocyanate in an amount of 51.2% by weight and carbon nanotubes of 50 nm in size, the microcapsules being mixed with the nanotubes in a ratio of 1:25. Then, the microcapsules and carbon nanotubes were manually coated with a thermoplastic resin, and a second self-healing layer 4 with a thickness of 0.3 mm was obtained. Then, on one of the sheets 6 made of a 1 mm thick nickel-titanium alloy, having on both surfaces a 10 μm thick ceramic layer 5 and a second self-healing layer 4 with a thickness of 0.3 mm, two layers of a thermoplastic composite based on carbon fibers 2 were applied in the orientation direction +45/-45°, each with a thickness of 0.04 mm. Then, a layer of polyester non-woven fabric 3 with a basis weight of 339 g/m ² and a thickness of 6 mm was applied. Two layers of a thermoplastic composite based on carbon fibers 2 in the orientation direction +45/-45°, each 0.04 mm thick, were applied to the polyester nonwoven fabric layer 3, onto which a layer of glass fibers filled with isophorone diisocyanate was applied in the orientation direction +45°, 0.75 mm thick, which was laminated manually with a thermoplastic resin to obtain a first self-healing layer 1 with a thickness of 1.5 mm, consisting of glass fibers filled with isophorone diisocyanate and bonded with a thermoplastic resin. Then, two layers of a thermoplastic composite based on carbon fibers 2 in the orientation direction +45/-45°, each 0.04 mm thick, were applied to the first self-healing layer 1, onto which a layer of a polyester nonwoven fabric 3 with a basis weight of 339 g/m ² and a thickness of 6 mm was applied. Two layers of carbon fiber-based thermoplastic composite 2, each 0.04 mm thick, were applied to the polyester nonwoven fabric layer 3, aligned in the +45°/-45° direction. Next, a second sheet 6 made of a nickel-titanium alloy was applied, with a 10 μm-thick ceramic layer 5 on both surfaces and a second, 0.3 mm-thick self-healing layer 4. The entire assembly was then placed on an aluminum mold and, using a vacuum pack, air was extracted to a negative pressure of -0.08 MPa. The entire assembly was then subjected to a curing process at 23°C for 24 hours. A thermoplastic resin with the trade name Elium® 351 EOT from Arkema was also used in the metal-carbon laminate production process.

In the produced metal-carbon laminate, in the central part there is a first self-healing layer 1 with a thickness of 1.5 mm, consisting of glass fibers filled with isophorone diisocyanate and bonded with a thermoplastic resin, to both surfaces of which two layers of a thermoplastic composite based on carbon fibers 2 with a thickness of 0.04 mm each are adhesively adhered, to which a layer of polyester nonwoven fabric 3 with a basis weight of 339 g/m ² and a thickness of 6 mm is adhesively adhered. Two layers of a thermoplastic composite based on carbon fibers 2, each 0.04 mm thick, are adhesively adhered to the polyester nonwoven fabric layer 3, which are adhesively adhered to a second self-healing layer 4, 0.3 mm thick, consisting of 50 μm microcapsules, each consisting of a polyurethane coating of toluene diisocyanate polyisocyanurate in ethyl acetate in an amount of 48.8% by weight and a filler of isophorone diisocyanate isocyanate in an amount of 51.2% by weight and 50 nm carbon nanotubes mixed together in a ratio of 1:25 and combined with a thermoplastic resin. The second self-healing layer 4 is applied to a 10 μm thick ceramic layer 5 provided on a sheet 6 of a nickel-titanium alloy consisting of 55% nickel by weight and 45% titanium by weight of 1 mm thick Nitinol, which has a 10 μm thick ceramic layer 5 on the outer surface with a 0.3 mm thick second self-healing layer 4 applied thereto.

The resulting laminate was subjected to low-velocity impact testing, where self-healing properties were observed after 24 hours, restoring structural integrity. The laminate was subjected to low-velocity impact testing at impact speeds below 5 m/s and energy of 2 J. The laminate was characterized by the destruction of the carbon fiber layer upon impact, while the nonwoven layer stopped the crack growth to the underlying layer. Furthermore, the laminate demonstrated increased resistance to environmental factors, particularly corrosion in NaCl solution.

Claims (8)

Patent claims 1. A metal-carbon laminate having a layer of polyester nonwoven fabric with a basis weight of 339 g/ ^m2, characterized in that in the central part of the laminate there is a first self-healing layer (1) with a thickness of 1 mm to 2 mm, consisting of glass fibers filled with isophorone diisocyanate and bonded with a thermoplastic resin, to both surfaces of which two layers of a thermoplastic composite based on carbon fibers (2) with a thickness of 0.04 mm each are adhesively adhered, to which a layer of polyester nonwoven fabric (3) with a basis weight of 339 g/ ^m2 and a thickness of 4 mm to 8 mm is adhesively adhered, wherein to the polyester nonwoven fabric layer (3) two layers of a thermoplastic composite based on carbon fibers (2) with a thickness of 0.04 mm each are adhesively adhered, which adhesively adhere to the second self-healing layer (4) with a thickness of 0.2 mm to 0.4 mm, consisting of microcapsules of a size ranging from 25 μm to 100 μm, each of which consists of a polyurethane coating of toluene diisocyanate polyisocyanurate in ethyl acetate in an amount of 48.8% by weight and a filling of isophorone diisocyanate isocyanate in an amount of 51.2% by weight and carbon nanotubes of a size ranging from 20 nm to 100 nm combined with a thermoplastic resin, and a second self-healing layer (4) is applied on a ceramic layer (5) of a thickness ranging from 5 μm to 12 μm located on a sheet metal sheet (6) of a nickel-titanium alloy of 1 mm thickness, which on the outer surface has a ceramic layer (5) of a thickness ranging from 5 μm to 12 μm with a second self-healing layer (4) of a thickness ranging from 0.2 mm to 0.4 mm. 2. A method for producing a metal-carbon laminate characterized in that on two sheets (6) of a 1 mm thick nickel-titanium alloy having on both surfaces a ceramic layer (5) with a thickness of 5 μm to 12 μm, microcapsules with a size of 25 μm to 100 μm are applied on both sides, each of which consists of a polyurethane coating of toluene diisocyanate polyisocyanurate in ethyl acetate in the amount of 48.8% by weight and a filling of isophorone diisocyanate isocyanate in the amount of 51.2% by weight and carbon nanotubes with a size of 20 nm to 100 nm, wherein the microcapsules and carbon nanotubes are manually coated with a thermoplastic resin, and a second self-healing layer (4) with a thickness of 0.2 mm to 0.4 mm is obtained, and then on one of the sheets (6) made of a nickel-titanium alloy with a thickness of 1 mm, having on both surfaces a ceramic layer (5) with a thickness of 5 μm to 12 μm and a second self-healing layer (4) with a thickness of 0.2 mm to 0.4 mm, two layers of a thermoplastic composite based on carbon fibres (2) with a thickness of 0.04 mm each are applied, after which a layer of polyester non-woven fabric (3) with a basis weight of 339 g/m ² and a thickness of 4 mm to 8 mm is applied, on which two layers of a thermoplastic composite based on carbon fibres (2) with a thickness of 0.04 mm each are applied, on which a layer of glass fibres filled with isophorone diisocyanate with a thickness of 0.5 mm to 1 mm is applied, which is manually laminated with a thermoplastic resin, and a first self-healing layer (1) with a thickness of 1 mm to 2 mm is obtained, consisting of glass fibres filled with isophorone diisocyanate and bonded with a thermoplastic resin, then two layers of a thermoplastic composite based on carbon fibers (2) with a thickness of 0.04 mm each are applied on the first self-healing layer (1), on which a layer of polyester non-woven fabric (3) with a basis weight of 339 g/m ² and a thickness of 4 mm to 8 mm is applied, then two layers of a thermoplastic composite based on carbon fibers (2) with a thickness of 0.04 mm each are applied on the polyester non-woven fabric layer (3), then PL 248762 Β1, the second sheet (6) made of a nickel-titanium alloy with a thickness of 1 mm is applied, having on both surfaces a ceramic layer (5) with a thickness of 5 µm to 12 µm and a second self-healing layer (4) with a thickness of 0.2 mm to 0.4 mm, then a vacuum package is made and the air is sucked out to a negative pressure of -0.08 MPa, after which the whole is subjected to a hardening process for 24 hours at a temperature of 23°C. 3. A method according to claim 2, characterized in that two layers of a thermoplastic composite based on carbon fibers (2) are applied in an 070° orientation. 4. A method according to claim 2, characterized in that two layers of a thermoplastic composite based on carbon fibers (2) are applied in an orientation of 0790°. 5. A method according to claim 2, characterized in that two layers of a thermoplastic composite based on carbon fibers (2) are applied in the orientation of +457-45°. 6. A method according to claim 2 or 3, characterized in that a layer of glass fibers filled with isophorone diisocyanate is applied in the 0° orientation. 7. A method according to claim 2 or 4, characterized in that a layer of glass fibers filled with isophorone diisocyanate is applied in a 90° orientation. 8. A method according to claim 2 or 5, characterized in that a layer of glass fibers filled with isophorone diisocyanate is applied in an orientation of +45°.