Cutting tool with a TiAlN coating having rake and relief surfaces with different residual stresses

What is claimed is: 1. A metal cutting insert comprising a substrate body and a chemical vapor deposition (CVD) coating over the substrate body, the substrate body is of cemented carbide, cermet, or ceramic; the substrate body comprises at least one rake face and at least one relief face that intersect to form a cutting edge, the CVD coating is formed on the substrate body by a chemical vapor deposition process and comprises one or more layers wherein at least one layer has a composition comprising aluminum, titanium and nitrogen having a cubic face centered lattice structure, represented by a formula (Al x Ti 1-x M y )C z N 1-z wherein a stoichiometry coefficient of aluminum is 0.30<x<0.95, wherein M is at least one element selected from the group consisting of Cl and Ar, with a stoichiometry coefficient of which is 0≤y<0.01, and wherein a stoichiometry coefficient of carbon is 0≤z<0.3; characterized in that: the chemical vapor deposition process results in coated surfaces of the substrate body having a tensile residual stress; and the (Al x Ti 1-x M y )C z N 1-z layer satisfies a relationship 10<|S 1 -S 2 |<500 MPa, wherein S 1 is the residual stress measured on the rake face, and S 2 is the residual stress measured on the relief face. 2. The metal cutting insert according to claim 1 , wherein y=0. 3. The metal cutting insert according to claim 1 , wherein z=0. 4. The metal cutting insert according to claim 1 , wherein the chemical vapor deposition process is without plasma activation. 5. The metal cutting insert according to claim 1 , wherein a thickness of the CVD coating is between 2 to 25 μm. 6. The metal cutting insert according to claim 1 , wherein |S 1 |<3100 MPa, and wherein |S 2 |<2800 MPa. 7. The metal cutting insert according to claim 6 , wherein z=0. 8. The metal cutting insert according to claim 6 , wherein the CVD coating further comprises one or more additional layers of carbides, nitrides, oxides, carbonitrides, oxynitrides, oxycarbides, oxycarbonitrides, borides, boronitrides, borocarbides, borocarbonitrides, boroxynitrides, boroxycarbides or boroxycarbonitrides of the elements of groups IVa to VIIa of the periodic system and/or aluminium, mixed metal phases and phase mixtures of the afore-mentioned compounds. 9. The metal cutting insert according to claim 8 , wherein at least one of the additional layers is selected from the group consisting of TiN and TiCN between the (Al x Ti 1-x M y )C z N 1-z layer and the substrate body, and wherein the substrate body is cemented carbide. 10. The metal cutting insert according to claim 9 , wherein none of the one or more additional layers are an alumina layer. 11. The metal cutting insert according to claim 9 , further characterized in that the (Al x Ti 1-x M y )C z N 1-z layer satisfies a relationship |HV 1 -HV 2 |<500, wherein HV 1 is the Vickers hardness measured on the rake face, and wherein HV 2 is the Vickers hardness measured on the relief face. 12. The metal cutting insert according to claim 11 , further characterized in that the (Al x Ti 1-x M y )C z N 1-z layer has a Vickers hardness HV 1 hardness measured on the rake face and HV 2 measured on the relief face, wherein 2300<HV 1 <4200, and wherein 2400≤HV 2 <4000. 13. The metal cutting insert according to claim 1 , wherein the CVD coating further comprises one or more additional layers of carbides, nitrides, oxides, carbonitrides, oxynitrides, oxycarbides, oxycarbonitrides, borides, boronitrides, borocarbides, borocarbonitrides, boroxynitrides, boroxycarbides or boroxycarbonitrides of the elements of groups IVa to VIIa of the periodic system and/or aluminum, mixed metal phases and phase mixtures of the afore-mentioned compounds. 14. The metal cutting insert according to claim 13 , wherein none of the one or more additional layers are an alumina layer. 15. The metal cutting insert according to claim 13 , wherein at least one of the additional layers is selected from the group consisting of TiN and TiCN between the (Al x Ti 1-x M y )C z N 1-z layer and the substrate body, and wherein the substrate body is cemented carbide. 16. The metal cutting insert according to claim 15 , wherein the CVD coating consists of a layer of TiN deposited onto the substrate body and the (Al x Ti 1-x M y )C z N 1-z layer. 17. The metal cutting insert according to claim 1 , further characterized in that the (Al x Ti 1-x M y )C z N 1-z layer satisfies a relationship |HV 1 -HV 2 |<500, wherein HV 1 is the Vickers hardness measured on the rake face, and wherein HV 2 is the Vickers hardness measured on the relief face. 18. The metal cutting insert according to claim 17 , further characterized in that the (Al x Ti 1-x M y )C z N 1-z layer has a Vickers hardness HV 1 hardness measured on the rake face and HV 2 measured on the relief face, wherein 2300<HV 1 <4200, and wherein 2400≤HV 2 <4000. 19. A method of production of the metal cutting insert according to claim 1 , in which: there is applied to a substrate body of cemented carbide, cermet or ceramic by means of CVD methods a CVD coating which is of a total thickness of 2 to 25 μm comprising at least one layer comprising aluminum, titanium and nitrogen having a cubic face centered lattice structure, represented by a formula (Al x Ti 1-x M y )C z N 1-z wherein a stoichiometry coefficient of aluminum is 0.30<x<0.95, wherein M is at least one element selected from the group consisting of Cl and Ar with a stoichiometry coefficient of which is 0≤y<0.01, and wherein a stoichiometry coefficient of carbon is 0≤z<0.3, the (Al x Ti 1-x M y )C z N 1-z layer having a thickness of 2 to 25 μm; and wherein after application of the CVD coating the substrate body is subjected to a blasting treatment, wherein the blasting pressure, the blasting duration, the blasting media, and/or the blasting angle of the blasting treatment are so selected that after the blasting treatment the (Al x Ti 1-x M y )C z N 1-z layer satisfies a relationship 10<|S 1 -S 2 |<500 MPa, wherein S 1 is the residual stress measured on the rake face, and wherein S 2 is the residual stress measured on the relief face. 20. A method of production of the metal cutting insert according to claim 19 , wherein after the blasting treatment the (Al x Ti 1-x M y )C z N 1-z layer further satisfies a relationship |HV 1 -HV 2 |<500, wherein HV 1 is the Vickers hardness measured on the rake face, and wherein HV 2 is the Vickers hardness measured on the relief face. 21. System for metal cutting, comprising an insert holder and at least one metal cutting insert according to claim 1 , wherein the at least one metal cutting insert is mounted on the insert holder. 22. The metal cutting insert according to claim 1 , wherein at least one of the at least one rake face and the at least one relief face has undergone a post coating mechanical treatment. 23. The metal cutting insert according to claim 1 , wherein at least one of the at least one rake face and the at least one relief face has tensile residual stress. 24. A metal cutting insert comprising: a substrate body and a chemical vapor deposition (CVD) coating over the substrate body, the substrate body is of cemented carbide, cermet, or ceramic; the substrate body comprises at least one rake face and at least one relief face that intersect to form a cutting edge, the CVD coating comprises one or more layers wherein at least one layer has a composition comprising aluminum, titanium and nitro