Oxygen solid solution titanium material sintered compact and method for producing same

The invention claimed is: 1. A method for producing an oxygen solid solution titanium material sintered compact, comprising: a step of mixing a combination of materials, the combination of materials consisting of: at least one of (1) an uncoated titanium component powder made of a titanium component having an α-phase, or (2) an oil coated titanium component powder made of the titanium component and an oil; and oxide particles of a metal other than titanium; a step of applying a compression force to shape a mixed powder obtained through said mixing; and a step of heating and sintering a compressed shaped compact, which is obtained through said compression shaping, in an environment that does not contain oxygen, wherein said sintering step comprises: decomposing said metal oxide into metal atoms and oxygen atoms; dissolving the oxygen atoms, which have been dissociated from said metal oxide, as a solute of solid solution into a crystal lattice of the titanium component; and allowing the metal atoms, which have been dissociated from said metal oxide, to remain in a matrix of the titanium component, and wherein an average particle size of said metal oxide particles is 1 μm to 10 μm, an amount of said metal oxide particles is within a range of 0.1% to 7% in terms of mass with respect to the total mixed powder, and a lower limit of a heating and sintering temperature of said environment in the step of heating and sintering the compressed shaped compact is 700° C., and an upper limit of the heating and sintering temperature is a lower one of a temperature equal to or lower than a boiling point of the metal constituting said metal oxide and a temperature equal to or lower than a melting point of said titanium component. 2. The method for producing an oxygen solid solution titanium material sintered compact according to claim 1 , wherein said oxide particles are oxide particles of a metal selected from the group consisting of Si, Ta, Cu, Nb, Co, Fe, Mn, V, Sn, Cr, Al, Be, Zr, and Mg. 3. The method for producing an oxygen solid solution titanium material sintered compact according to claim 1 , wherein the metal atoms dissociated from said metal oxide are dissolved as a solute of solid solution into the crystal lattice of said titanium component by a treatment of said heating and sintering. 4. The method for producing an oxygen solid solution titanium material sintered compact according to claim 1 , wherein the metal atoms dissociated from said metal oxide react with said titanium component by a treatment of said heating and sintering to form a compound to be dispersed in said matrix. 5. The method for producing an oxygen solid solution titanium material sintered compact according to claim 1 , wherein the metal atoms dissociated from said metal oxide are deposited in the matrix of said titanium component by a treatment of said heating and sintering. 6. The method for producing an oxygen solid solution titanium material sintered compact according to claim 1 , wherein said compression shaping step and said sintering step are simultaneously carried out. 7. The method for producing an oxygen solid solution titanium material sintered compact according to claim 1 , further comprising a step of performing a heat treatment for homogenizing a structure of the sintered compact after said sintering step. 8. The method for producing an oxygen solid solution titanium material sintered compact according to claim 1 , further comprising a step of performing plastic forming of the sintered compact obtained after said heating and sintering. 9. A method for producing an oxygen solid solution titanium material sintered compact, comprising: a step of mixing a combination of materials, the combination of materials consisting of: an oil coated titanium component powder made of a titanium component having an α-phase and an oil; and oxide particles of a metal other than titanium, wherein the oxide particles of the metal are dispersed and adhere onto the surface of titanium component powder particles; a step of applying a compression force to shape a mixed powder obtained through said mixing; and a step of heating and sintering a compressed shaped compact, which is obtained through said compression shaping, in an environment that does not contain oxygen, wherein said sintering step comprises: decomposing said metal oxide into metal atoms and oxygen atoms; dissolving the oxygen atoms, which have been dissociated from said metal oxide, as a solute of solid solution into a crystal lattice of the titanium component; and allowing the metal atoms, which have been dissociated from said metal oxide, to remain in a matrix of the titanium component, and wherein an average particle size of said metal oxide particles is 1 μm to 10 μm, an amount of said metal oxide particles is within a range of 0.1% to 7% in terms of mass with respect to the total mixed powder, and a lower limit of a heating and sintering temperature of said environment in the step of heating and sintering the compressed shaped compact is 700° C., and an upper limit of the heating and sintering temperature is a lower one of a temperature equal to or lower than a boiling point of the metal constituting said metal oxide and a temperature equal to or lower than a melting point of said titanium component.