Composite epoxy material with embedded MWCNT fibers and process of manufacturing

The invention claimed is: 1. A stacked composite material comprising: at least two glass fiber layers and at least three nanocomposite layers each comprising an epoxy matrix and carbon nanotubes, wherein said nanocomposite layers do not contain visible air bubbles and each comprise 0.75 to 1.5 wt % deagglomerated and randomly dispersed multiwalled carbon nanotubes relative to the weight of the epoxy matrix, wherein the glass fibers present in each glass fiber layer are surrounded with an epoxy matrix comprising carbon nanotubes; wherein each glass fiber layer is sandwiched between two nanocomposite layers and wherein a distance separating any two adjacent glass fiber layers of the stacked composite material ranges from 0.5 to 10 mm; wherein the glass fibers present in each glass fiber layer are unidirectionally oriented, and the glass fiber layers are oriented so as to enhance the quasi isotropic properties of the composite material; and wherein the stacked composite material has a glass fiber volume fraction ranging from 20% to 45% of a total volume of the stacked composite material. 2. The stacked composite material of claim 1 , which has a wt % of the multi-wall carbon nanotubes ranging from 1.0 to 1.5 wt % relative to the total weight of the epoxy matrix. 3. The stacked composite material of claim 1 , wherein a distance separating any two adjacent glass fiber layers of the stacked composite material ranges from 2 mm to 5 mm. 4. The stacked composite material of claim 1 , wherein a linear density of the glass fibers is between 0.10 g/m to 3.0 g/m. 5. The stacked composite material of claim 1 , wherein the multi walled carbon nanotubes have an outer diameter between 0.5 nm and 15 nm and a length between 1 μm and 50 μm. 6. The stacked composite material of claim 1 , wherein the epoxy matrix comprises 50%-90% by weight of at least one epoxy resin, relative to a total weight of the epoxy matrix, and 15%-45% by weight of at least one epoxy hardener relative to the total weight of the epoxy matrix, and wherein the epoxy matrix has a viscosity between 210 centipoise and 410 centipoise in a temperature between −5° C. and 15° C. 7. The stacked composite material of claim 6 , wherein the at least one epoxy resin comprises bisphenol A and/or bisphenol F and the at least one epoxy hardener comprises at least one selected from the group consisting of a cycloaliphatic amine, an aliphatic amine, and a thiol. 8. The stacked composite material of claim 1 , which has at least 17 total layers of the glass fiber layer and the nanocomposite layer, wherein the nanocomposite layer forms a first layer and a last layer of the stacked composite material. 9. The stacked composite material of claim 8 , wherein adjacent and noncontiguous glass fiber layers are oriented in a quasi-isotropic orientation with respect to the unidirectional glass fibers present within each glass fiber layer, and wherein the glass fiber layers have an orientation angle sequence of approximately 0°, approximately 45°, approximately 135°, or approximately 90° within the stacked composite material. 10. The stacked composite material of claim 9 , wherein the orientation angle sequence is a palindromic sequence organized by an orientation angle of each glass fiber layer. 11. The stacked composite material of claim 1 , wherein a glass fiber volume fraction is between 25% and 40% of the total volume of the stacked composite material. 12. The stacked composite material of claim 1 , which has a tensile strength between 25 mega pascals to 55 mega pascals and a tensile strain between 5 giga pascals to 25 giga pascals. 13. The stacked composite material of claim 1 , which has a compressive strength between 180 mega pascals to 300 mega pascals and compressive strain between 12 giga pascals to 15 giga pascals. 14. The stacked composite material of claim 1 that is prepared by applying a nanocomposite layer comprising multi walled carbon nanotubes randomly dispersed in an epoxy matrix onto a substrate; overlaying a glass fiber layer on top of the nanocomposite layer, wherein the glass fiber layer comprises glass fibers which are unidirectional; rolling a roller over the glass fiber layer in a direction parallel to a longitudinal axis of the glass fibers thus impregnating and wetting the glass fibers with the carbon nanotubes randomly dispersed into an epoxy matrix; repeating the applying, overlaying, and rolling, wherein each glass fiber layer is sandwiched between two nanocomposite layers and each glass fiber layer is oriented in a unidirectional orientation or a quasi-isotropic orientation relative to an adjacent and noncontiguous glass fiber layer; and applying and covering with a plate and curing to form the stacked composite material. 15. The stacked composite material of claim 14 that comprises at least 17 total layers of the glass fiber layer and the nanocomposite layer stacked concentrically in an alternating sequence and the nanocomposite layer forms a first layer and a last layer of the stacked composite material. 16. The stacked composite material of claim 15 , wherein adjacent and noncontiguous glass fiber layers are oriented in a quasi-isotropic orientation with respect to the unidirectional glass fibers present within each glass fiber layer, and wherein the glass fiber layers have an orientation angle sequence of approximately 0°, approximately 45°, approximately 135°, or approximately 90° within the stacked composite material. 17. The stacked composite material of claim 16 , wherein the orientation angle sequence is a palindromic sequence organized by an orientation angle of each glass fiber layer. 18. The stacked composite material of claim 1 , wherein the curing comprises applying pressure to the plate for 8 hours to 60 hours then releasing the pressure and holding for 1 day to 35 days under ambient temperature. 19. The stacked composite material of claim 18 , wherein the pressure applied to the plate is between 50 kgf/m 2 and 300 kgf/m 2 and the pressure is applied uniformly to the plate. 20. The stacked composite material of claim 1 , that has a higher elastic modulus, higher ultimate tensile load, and higher compressive strength than an otherwise identical stacked composite material not containing the dispersed carbon nanotubes.