Lead-free piezoelectric ceramic composition, method for producing same, piezoelectric element using lead-free piezoelectric ceramic composition, ultrasonic processing machine, ultrasonic drive device, and sensing device

The invention claimed is: 1. A lead-free piezoelectric ceramic composition mainly comprising: a first crystal phase in which a plurality of crystal grains formed of an alkali niobate/tantalate perovskite oxide having piezoelectric characteristics is bound to each other in a deposited state; a second crystal phase formed of a compound containing titanium (Ti) and filling spaces between the plurality of crystal grains of the first crystal phase; and at least one metal element selected from copper (Cu), iron (Fe), and zinc (Zn), which is contained by being localized more in the second crystal phase than in the first crystal phase; wherein the lead-free piezoelectric ceramic composition is produced by mixing a mother phase calcined product and a subphase calcined product, and calcining the mixed mother phase calcined product and the subphase calcined product. 2. The lead-free piezoelectric ceramic composition according to claim 1 , wherein the second crystal phase is contained in a content of 2 to 10 mol %. 3. The lead-free piezoelectric ceramic composition according to claim 1 , further comprising metal element cobalt (Co), which is contained by being localized more in the second crystal phase than in the first crystal phase. 4. The lead-free piezoelectric ceramic composition according to claim 1 , further comprising at least one metal element selected from zirconium (Zr) and calcium (Ca), which is contained by being localized more in the first crystal phase than in the second crystal phase. 5. The lead-free piezoelectric ceramic composition according to claim 1 , wherein the compound forming the second crystal phase is an A-Ti—B—O composite compound (wherein the element A is an alkali metal, the element B is at least one of niobium (Nb) and tantalum (Ta), and each of the contents of the element A, the element B, and titanium (Ti) is not zero). 6. The lead-free piezoelectric ceramic composition according to claim 5 , wherein the element A is potassium (K). 7. The lead-free piezoelectric ceramic composition according to claim 5 , wherein the element B is niobium (Nb). 8. The lead-free piezoelectric ceramic composition according to claim 1 , wherein the compound forming the second crystal phase has a lower melting point than the alkali niobate/tantalate perovskite oxide forming the first crystal phase. 9. The lead-free piezoelectric ceramic composition according to claim 1 , produced by mixing, molding, and firing a crystal powder formed of an alkali niobate/tantalate perovskite oxide having piezoelectric characteristics and a crystal powder formed of a compound that contains titanium (Ti). 10. A piezoelectric element comprising: a piezoceramic formed from the lead-free piezoelectric ceramic composition according to claim 1 ; and an electrode mounted on the piezoceramic. 11. An ultrasonic processing machine comprising the piezoelectric element of claim 10 . 12. An ultrasonic drive device comprising the piezoelectric element of claim 10 . 13. A sensing device comprising the piezoelectric element of claim 10 . 14. A method for producing a lead-free piezoelectric ceramic composition, the method comprising: calcining to obtain a mother phase calcined product formed of an alkali perovskite oxide containing at least one of niobium and tantalum having piezoelectric characteristics; calcining to obtain a subphase calcined product being formed of a compound that contains titanium (Ti); mixing the mother phase calcined product and the subphase calcined product; calcining the mixed mother phase calcined product and the subphase calcined product at a first temperature after the mixing; producing a molded product by mixing and molding the calcined mixed mother phase calcined product and the subphase calcined product at the first temperature; and producing a lead-free piezoelectric ceramic composition, in which a first crystal phase is formed by binding a plurality of crystal grains of the first crystal powder in a deposited state and a second crystal phase is formed by melting the second crystal powder to fill spaces between the plurality of crystal grains of the first crystal phase, by firing the molded product at a second temperature higher than the first temperature.