Ceramic honeycomb filter and its production method

What is claimed is: 1. A method for producing a ceramic honeycomb filter comprising the steps of preparing a cordierite-forming material containing talc, silica, an alumina source and kaolin; classifying the cordierite-forming material by passing the cordierite-forming material through a sieve having opening diameters of 250 μm or less to form a classified cordierite-forming material; blending the classified cordierite-forming material and a pore-forming material to prepare a moldable material; extruding said moldable material to form a honeycomb-shaped molding; and plugging the predetermined flow paths of said honeycomb-shaped molding to form said ceramic honeycomb filter; said silica having a median diameter of 15-58 μm, said talc having a median diameter of 10-25 μm and a morphology index of 0.77-0.84, said kaolin having a median diameter of 1.5-7.5 μm and a cleavage index of 0.9-0.95, said cleavage index being a value expressed by I (002) /[I (200) +I (020) +I (002) ], wherein I (200) , I (020) and I (002) are the peak intensities of (200), (020) and (002) planes measured by X-ray diffraction, said alumina source having a median diameter of 1.5-6 μm, and said pore-forming material comprising pore-forming material particles having a median diameter of 30-70 μm. 2. A method for producing a ceramic honeycomb filter comprising the steps of preparing a cordierite-forming material containing talc, silica, an alumina source and kaolin; classifying the cordierite-forming material by passing the cordierite-forming material through a sieve having opening diameters of 250 μm or less to form a classified cordierite-forming material; blending the classified cordierite-forming material and a pore-forming material to prepare a moldable material; extruding said moldable material to form a honeycomb-shaped molding; and plugging the predetermined flow paths of said honeycomb-shaped molding to form said ceramic honeycomb filter; said silica having a median diameter of 15-58 μm, said talc having a median diameter of 10-25 μm and a morphology index of 0.77-0.84, said kaolin having a median diameter of 1.5-7.5 μm and a cleavage index of 0.9-0.95, said cleavage index being a value expressed by I (002) /[I (200) +I (020) +I (002) ], wherein I (200) , I (020) and I (002) are the peak intensities of (200), (020) and (002) planes measured by X-ray diffraction, said alumina source having a median diameter of 1.5-6 μm, and said pore-forming material comprising pore-forming material particles having a median diameter of 30-70 μm, wherein in a curve showing the relation between a particle diameter of said pore-forming material particles and a cumulative volume of said pore-forming material particles, a particle diameter d 90 of said pore-forming material particles at a cumulative volume corresponding to 90% of a total volume of the pore-forming material particles is 50-90 μm. 3. The method for producing a ceramic honeycomb filter according to claim 1 , wherein said alumina source has a median diameter of 2-5 μm. 4. The method for producing a ceramic honeycomb filter according to claim 1 , wherein said silica has a median diameter of 35-55 μm. 5. The method for producing a ceramic honeycomb filter according to claim 2 , wherein said alumina source has a median diameter of 2-5 μm. 6. The method for producing a ceramic honeycomb filter according to claim 2 , wherein said silica has a median diameter of 35-55 μm. 7. The method for producing a ceramic honeycomb filter according to claim 3 , wherein said silica has a median diameter of 35-55 μm. 8. The method for producing a ceramic honeycomb filter according to claim 5 , wherein said silica has a median diameter of 35-55 μm. 9. A method for producing a ceramic honeycomb filter comprising the steps of preparing a cordierite-forming material containing talc, silica, an alumina source and kaolin; classifying the cordierite-forming material by passing the cordierite-forming material through a sieve having opening diameters of 250 μm or less to form a classified cordierite-forming material; blending the classified cordierite-forming material and a pore-forming material to prepare a moldable material; extruding said moldable material to form a honeycomb-shaped molding; and plugging the predetermined flow paths of said honeycomb-shaped molding to form said ceramic honeycomb filter; said silica having a median diameter of 15-58 μm, said talc having a median diameter of 10-25 μm and a morphology index of 0.77-0.84, said kaolin having a median diameter of 1.5-7.5 μm and a cleavage index of 0.9-0.95, said cleavage index being a value expressed by I (002) /[I (200) +I (020) +I (002) ], wherein I (200) , I (020) and I (002) are the peak intensities of (200), (020) and (002) planes measured by-X ray diffraction, said alumina source having a median diameter of 1.5-6 μm, and said pore-forming material comprising pore-forming material particles having a median diameter of 30-70 μm, wherein in a curve having the relation between a particle diameter of said pore-forming material particles and a cumulative volume of said pore-forming material particles, a particle diameter d90 of said pore-forming material particles at a cumulative volume corresponding to 90% of a total volume of the pore-forming material particles is 60-80 μm. 10. The method for producing a ceramic honeycomb filter according to claim 9 , wherein said alumina source has a median diameter of 2-5 μm. 11. The method for producing a ceramic honeycomb filter according to claim 9 , wherein said silica has a median diameter of 35-55 μm. 12. The method for producing a ceramic honeycomb filter according to claim 10 , wherein said silica has a median diameter of 35-55 μm.