Calcined ferrite, sintered ferrite magnet and its production method

What is claimed is: 1. A calcined ferrite comprising metal elements of Ca, La, Sr, Ba, Fe and Co, whose atomic ratios are represented by the general formula: Ca 1-x-y La x (Sr y′ Ba 1-y′ ) y Fe 2n-z Co z , wherein 1−x−y, x and y are values in a region defined by a coordinate a: (0.470, 0.297, 0.233), a coordinate b: (0.300, 0.392, 0.308), a coordinate c: (0.300, 0.300, 0.400), a coordinate d: (0.400, 0.200, 0.400) and a coordinate e: (0.470, 0.200, 0.330) in a ternary diagram of x, y, and 1−x−y; and y′ and z, and n representing a molar ratio are values meeting 0.5≦y′≦1, 0.2≦z<0.25, and 5.2<n<5.6. 2. A method for producing a sintered ferrite magnet comprising the steps of mixing raw material powders to a composition comprising metal elements of Ca, La, Sr, Ba, Fe and Co, whose atomic ratios are represented by the general formula: Ca 1-x-y La x (Sr y′ Ba 1-y′ ) y Fe 2n-z Co z , wherein 1−x−y, x and y are values in a region defined by a coordinate a: (0.470, 0.297, 0.233), a coordinate b: (0.300, 0.392, 0.308), a coordinate c: (0.300, 0.300, 0.400), a coordinate d: (0.400, 0.200, 0.400) and a coordinate e: (0.470, 0.200, 0.330) in a ternary diagram of x, y, and 1−x−y; and y′ and z, and n representing a molar ratio are values meeting 0.5≦y′≦1, 0.2≦z<0.25, and 5.2<n<5.6, thereby obtaining a raw material powder mixture; calcining said raw material powder mixture to obtain a calcined body; pulverizing said calcined body to obtain calcined powder; molding said calcined powder to obtain a green body; and sintering said green body to obtain a sintered body; 0.1% or more and less than 1.5% by mass of SiO 2 being added to 100% by mass of said raw material powder mixture, said calcined body or said calcined powder; and 0-2% by mass (as CaO) of CaCO 3 being added to 100% by mass of said calcined body or said calcined powder. 3. A method for producing a sintered ferrite magnet comprising the steps of mixing raw material powders to a composition comprising metal elements of Ca, La, Sr, Ba, Fe and Co, whose atomic ratios are represented by the general formula: Ca 1-x-y La x (Sr y′ Ba 1-y′ ) y Fe 2n-z Co z , wherein 1−x−y, x and y are values in a region defined by a coordinate a: (0.470, 0.297, 0.233), a coordinate b: (0.300, 0.392, 0.308), a coordinate c: (0.300, 0.300, 0.400), a coordinate d: (0.400, 0.200, 0.400) and a coordinate e: (0.470, 0.200, 0.330) in a ternary diagram of x, y, and 1−x−y; and y′ and z, and n representing a molar ratio are values meeting 0.5≦y′≦1, 0≦z<0.25, and 5.2<n<5.6, thereby obtaining a raw material powder mixture; calcining said raw material powder mixture to obtain a calcined body; pulverizing said calcined body to obtain a calcined powder; molding said calcined powder to obtain a green body; and sintering said green body to obtain a sintered body; a raw material powder of Co being added to said calcined body or said calcined powder, such that said z meets 0.2≦z<0.25 as a whole; 0.1% or more and less than 1.5% by mass of SiO 2 being added to 100% by mass of said raw material powder mixture, said calcined body or said calcined powder; and 0-2% by mass (as CaO) of CaCO 3 being added to 100% by mass of said calcined body or said calcined powder. 4. A sintered ferrite magnet produced by the method recited in claim 2 , which comprises metal elements of Ca, La, Sr, Ba, Fe and Co, whose atomic ratios are represented by the general formula: Ca 1-x-y La x (Sr y′ Ba 1-y′ ) y Fe 2n-z Co z , wherein 1−x−y, x and y are values in a region defined by a coordinate a: (0.470, 0.297, 0.233), a coordinate b: (0.300, 0.392, 0.308), a coordinate f: (0.221, 0.289, 0.490), a coordinate g: (0.221, 0.221, 0.558), a coordinate h: (0.295, 0.147, 0.558), a coordinate i: (0.346, 0.147, 0.507) and a coordinate e: (0.470, 0.200, 0.330) in a ternary diagram of x, y, and 1−x−y; and y′ and z, and n representing a molar ratio are values meeting 0.5≦y′≦1, 0.147≦z<0.25, and 3.88≦n<5.6, said sintered ferrite magnet having a residual magnetic flux density B r (mT) and an intrinsic coercivity H cJ (kA/m) at 23° C. meeting the relation of B r +H cJ /4≧535.5.