Rotary engine with rotor land

The invention claimed is: 1. A rotary internal combustion engine comprising: an outer body enclosing an internal cavity, the outer body rotationally receiving a shaft extending through the internal cavity; a rotor body received in the internal cavity and made at least in major part of a first material, the rotor body having first and second axially spaced apart end faces each extending in proximity of a respective inner surface of the internal cavity, and a peripheral face extending between the first and second end faces, the rotor body including a phasing gear on the first end face, the rotor body being engaged to an eccentric member of the shaft to rotate within the internal cavity in sealed engagement with walls defining the internal cavity, the rotor body including at least one land protruding axially from each of the first and second end faces and defining a contact surface extending at a fixed position with respect to the end faces, the contact surface frictionally engaging a portion of the inner surface of the internal cavity, at least the outer surface of the land including a second material; wherein the second material has a greater wear resistance than that of the first material with respect to frictional engagement with the portion of the inner surface of the internal cavity contacting the at least one land; wherein the at least one land of the second end face is defined as an insert retained in a complementary recess defined in the second end face, the insert made of the second material, the at least one land of the second end face being spaced radially outwardly from the eccentric member of the shaft. 2. The engine as defined in claim 1 , wherein the first material has a lower mass per volume than the second material. 3. The engine as defined in claim 1 , wherein the first material includes titanium. 4. The engine as defined in claim 1 , wherein the at least one land of the first end face is defined by the phasing gear engaged to the rotor body and made of the second material. 5. The engine as defined in claim 1 , wherein the first material includes titanium and the second material includes steel. 6. The engine as defined in claim 1 , wherein for at least one of the end faces, the at least one land includes the first material, and the outer surface thereof is defined by a surface coating of the second material applied on the first material. 7. The engine as defined in claim 6 , wherein the second material includes one or more of titanium nitride, diamond-like carbon, cobalt chrome, nanocrystalline cobalt-phosphorus, nickel, thallium and boron. 8. The engine as defined in claim 1 , wherein the at least one land for each of the end faces includes a plurality of spaced apart lands located radially outwardly of oil seal grooves defined in the end face. 9. The engine as defined in claim 1 , wherein the outer body has two axially spaced apart end walls and a peripheral wall extending between the end walls, with inner surfaces of the end walls and of the peripheral wall enclosing the internal cavity, and the peripheral face of the rotor body defines three circumferentially spaced apex portions remaining adjacent the inner surface of the peripheral wall during rotation of the rotor, the contact surface of each land frictionally engaging a portion of the inner surface of a corresponding one of the end walls. 10. The engine as defined in claim 1 , wherein the second material has a greater hardness than that of the first material. 11. The engine as defined in claim 1 , wherein the second material is the same material as that of the portion of the inner surface of the internal cavity contacting the at least one land. 12. A rotary internal combustion engine comprising: an outer body having two axially spaced apart end walls and a peripheral wall extending between the end walls, with inner surfaces of the end walls and of the peripheral wall enclosing an internal cavity, the outer body rotationally receiving a shaft extending through the internal cavity; a rotor body received in the internal cavity, the rotor body having first and second axially spaced apart end faces each extending in proximity of the inner surface of a respective one of the end walls, and a peripheral face extending between the first and second end faces and defining three circumferentially spaced apex portions, the rotor body including a phasing gear on the first end face, the rotor body being engaged to an eccentric member of the shaft to rotate within the internal cavity with each of the apex portions remaining adjacent the inner surface of the peripheral wall, the rotor body including at least one land protruding axially from each of the first and second end faces and defining a contact surface extending at a fixed position with respect to the end faces, the contact surface frictionally engaging a portion of the inner surface of a corresponding one of the end walls of the internal cavity; wherein at least the contact surface of the at least one land has a greater wear resistance than that of a first material forming at least a major part the rotor body with respect to frictional engagement with a material of the portion of the inner surface of the corresponding one of the end walls contacting the at least one land; wherein the at least one land of the second end face is defined as an insert retained in a complementary recess defined in the second end face, the at least one land of the second end face being spaced radially outwardly from the eccentric member of the shaft. 13. The engine as defined in claim 12 , wherein for at least one of the end faces, the at least one land includes the first material, and the contact surface thereof is defined by a layer having the greater wear resistance than that of the first material, the layer being obtained through a microstructure transformation of the first material. 14. The engine as defined in claim 12 , wherein the at least one land of the first end face is defined by the phasing gear engaged to the rotor body and made of a second material having the greater wear resistance than the first material. 15. The engine as defined in claim 12 , wherein for at least one of the end faces, the at least one land includes the first material, and the contact surface thereof is defined by a coating of a second material applied on the first material and having the greater wear resistance than that of the first material. 16. The engine as defined in claim 12 , wherein at least the contact surface of the at least one land is made of the same material as that of the inner surface of the corresponding one of the end walls contacting the at least one land. 17. A method of axially positioning a rotor of a rotary engine within an internal cavity of an outer body of the rotary engine, the rotor being engaged to an eccentric member of a shaft and having opposed first and second end faces with the first end face being connected to a phasing gear, the method comprising: forming at least a major part of a body of the rotor from a first material, forming at least one land protruding axially and rigidly from each of first and second end faces of the rotor with each of the at least one land having a contact surface having a greater wear resistance than that of the first material with respect to frictional engagement with a base material, including forming the at least one land protruding axially and rigidly from the second end face with an insert retained in a complementary recess defined in the second end face, and positioned to that the at least one land of the second end face is spaced radially ou