Piston ring

What is claimed is: 1. A piston ring having a CrN-type hard coating as thick as 10-60 μm formed on its outer peripheral sliding surface; said CrN-type hard coating comprising a CrN/CrCN laminate coating obtained by alternately laminating CrN layers and CrCN layers containing C dissolved in CrN; a laminate unit composed of said CrN layer and said CrCN layer being as thick as 30-100 nm; and said CrN-type hard coating having hardness Hv of 1000-1450, and residual compression stress of 1500 MPa or less; wherein an outermost surface of said outer peripheral sliding surface has a composite structure comprising a CrN phase and a CrCN phase containing C dissolved in CrN. 2. The piston ring according to claim 1 , wherein said CrN-type hard coating has a carbon concentration of 1-4% by mass. 3. The piston ring according to claim 1 , wherein said laminate unit in said CrN/CrCN laminate coating has a thickness in a range of 2-6 times the size of CrN crystallite, when determined from the X-ray diffraction data of said CrN-type hard coating. 4. The piston ring according to claim 1 , wherein a surface of said CrN-type hard coating has the maximum X-ray diffraction intensity in a CrN (200) plane. 5. A method for producing a piston ring having a CrN-type hard coating as thick as 10-60 μm formed on its outer peripheral sliding surface, comprising the steps of adjusting the surface roughness Rzjis82 of the outer peripheral surface of a piston ring base material to 0.5-3 μm; alternately forming CrN layers and CrCN layers containing C dissolved in CrN by arc ion plating to form a CrN/CrCN laminate coating having a laminate unit composed of said CrN layer and said CrCN layer being as thick as 30-100 nm; and then grinding said CrN/CrCN laminate coating to form an outermost surface of said outer peripheral sliding surface having a composite structure comprising a CrN phase and a CrCN phase containing C dissolved in CrN. 6. The method for producing a piston ring according to claim 5 , wherein said CrN layer is formed using a nitrogen gas as a process gas; and wherein said CrCN layer is formed using a nitrogen gas, a hydrocarbon gas and an argon gas as a process gas. 7. The method for producing a piston ring according to claim 6 , wherein the flow rate of said process gas is controlled. 8. The method for producing a piston ring according to claim 5 , wherein the process gas used in the formation of said CrN layer and the process gas used in the formation of said CrCN layer are switched, while keeping arc discharge on a metal Cr cathode.