Aluminum-copper-lithium alloy with improved impact resistance

The invention claimed is: 1. An extruded product of an aluminum alloy consisting of: from 4.2 weight % to 4.8 weight % of Cu, from 0.9 weight % to 1.1 weight % of Li, from 0.15 weight % to 0.25 weight % of Ag, from 0.2 weight % to 0.6 weight % of Mg, from 0.07 weight % to 0.15 weight % of Zr, from 0.2 weight % to 0.6 weight % of Mn, from 0.01 weight % to 0.15 weight % of Ti, and a quantity of Zn less than 0.1 weight %, a quantity of Fe and Si each less than or equal to 0.1 weight %, inevitable impurities wherein each of the inevitable impurities has a content less than or equal to 0.05 weight % and the inevitable impurities in total has a content less than or equal to 0.15 weight %, and the remainder being aluminum; wherein (1) for a thickness of from 5 mm to 16 mm, the extruded product at mid-thickness has an average tensile yield stress Rp0.2 in an L-direction of at least 630 MPa, an average tensile yield stress Rp0.2 in an LT-direction of at least 625 MPa, and an EA factor, EA, of at least equal to 14,000, and/or (2) for a thickness from 17 mm to 30 mm, the extruded product at mid-thickness has an average tensile yield stress Rp0.2 in an L-direction of at least 655 MPa, an average tensile yield stress Rp0.2 in an LT-direction of at least 600 MPa, and an EA factor, EA, of at least equal to 9,500; wherein the EA factor, EA, in (1) and (2) above, is calculated via the following formulaic expression, EA =( R m ( L )+ R p 0.2( L ))/2* E % ( L )+( R m ( LT )+ R p 0.2( LT ))/2* E % ( LT ) wherein R m (L) represents an ultimate tensile strength in an L-direction, R m (L) represents an ultimate tensile strength in an LT-direction, R p 0.2(L) represents an average tensile yield stress in an L-direction, R p 0.2(LT) represents an average tensile yield stress in an LT-direction, E % (L) represents an elongation at break in an L-direction, and E % (LT) represents an elongation at break in an LT-direction. 2. The extruded product according to claim 1 , wherein the Cu is from 4.3 weight % to 4.7 weight %. 3. The extruded product according to claim 1 , wherein the Cu is from 4.35 weight % to 4.55 weight %. 4. The extruded product according to claim 1 , wherein the Cu is from 4.5 weight % to 4.7 weight %. 5. The extruded product according to claim 1 , wherein the Li is from 0.95 weight % to 1.05 weight %. 6. The extruded product according to claim 1 , wherein the Mg is from 0.30 weight % to 0.50 weight % and/or the Zr is from 0.10 weight % to 0.13 weight %. 7. The extruded product according to claim 1 , wherein the Mn is from 0.3 weight % to 0.5 weight %. 8. The extruded product according to claim 1 , wherein a recrystallization rate from ¼ to ½ thickness of an elementary rectangle is not more than 30%. 9. The extruded product according to claim 1 , wherein a recrystallization rate from ¼ to ½ thickness of an elementary rectangle is not more than 10%. 10. The extruded product according to claim 1 , wherein (1) for a thickness of from 5 mm to 16 mm, the extruded product at mid-thickness has an average tensile yield stress Rp0.2 in an L-direction of at least 635 MPa, an average tensile yield stress Rp0.2 in an LT-direction of at least 630 MPa, and an EA factor, EA, of at least equal to 14,500, and/or (2) for a thickness from 17 mm to 30 mm, the extruded product at mid-thickness has an average tensile yield stress Rp0.2 in an L-direction of at least 660 MPa, an average tensile yield stress Rp0.2 in an LT-direction of at least 605 MPa, and an EA factor, EA, of at least equal to 9,800. 11. The extruded product according to claim 1 , wherein (1) for a thickness of from 5 mm to 16 mm, the extruded product has a toughness, K 1C L−T), of at least 24 MPa√{square root over (m)}, or (2) for a thickness from 17 mm to 30 mm, the extruded product has a toughness, K 1C (L−T), of at least 21 MPa√{square root over (m)}. 12. The extruded product according to claim 1 , wherein (1) for a thickness of from 5 mm to 16 mm, the extruded product has a toughness, K 1C (L−T), of at least 25 MPa√{square root over (m)}, or (2) for a thickness from 17 mm to 30 mm, the extruded product has a toughness, K 1C (L−T), of at least 22 MPa√{square root over (m)}. 13. The extruded product according to claim 1 , wherein the product has a resistance of at least 30 days during a stress corrosion test as per standards ASTM G44 and ASTM G49 on test specimens taken in the LT-direction for a stress of 450 MPa. 14. The extruded product according to claim 1 , wherein the extruded product is capable of being used for aeronautic construction as a fuselage stiffener or stringer, circumferential frame, wing stiffener, floor profile or beam or seat track. 15. An aeronautic construction product comprising the extruded product of claim 1 , wherein said aeronautic construction product optionally comprises a fuselage stiffener, stringer, circumferential frame, wing stiffener, floor profile, beam and/or seat track. 16. A process for manufacturing an extruded product according to claim 1 , comprising: (a) casting a rough alloy form with a composition of the aluminum alloy of claim 1 , (b) homogenizing said rough alloy form at a temperature of 490° C. to 520° C. for 8 to 48 hours, (c) hot working by extrusion at an initial hot working temperature of 420° C. to 480° C., (d) undergoing solution heat treatment at a temperature of 500° C. to 520° C. for 15 minutes to 8 hours, (e) quenching, (f) undergoing controlled stretching with a permanent set from 2 weight % to 4 weight %, (g) optionally, straightening, (h) aging by heating at a temperature of 100° C. to 170° C. for 5 to 100 hours to result in the extruded product of claim 1 .