Method for manufacturing piston for internal combustion engine, and piston for internal combustion engine

The invention claimed is: 1. A method for manufacturing a piston for internal combustion engine, the method for manufacturing a piston for internal combustion engine comprising: a concave part-forming step for forming a concave part in a crown surface of the piston, the crown surface defining a combustion chamber; a material-filling step for filling the concave part with a mixed powder or a compacted body of the mixed powder, the mixed powder being obtained by mixing a powder of a filler material smaller than a base material of the piston in thermal conductivity and a powder of a bonding material which may become an alloy or an intermetallic compound when blending with the base material; and a friction bonding step of bringing a rotary implement into contact with a region of the concave part involving the mixed powder or the compacted body of the mixed powder and then softening the mixed powder or the compacted body of the mixed powder by frictional heat, thereby bonding the mixed powder or the compacted body of the mixed powder to the concave part in a solid phase to form a low thermal conductive part. 2. A method for manufacturing a piston for internal combustion engine, as claimed in claim 1 , wherein in the friction bonding step the frictional heat is generated by pressing the rotary implement against the base material while covering the whole range of the concave part with an end surface of the rotary implement. 3. A method for manufacturing a piston for internal combustion engine, as claimed in claim 2 , wherein the concave part formed in the crown surface is located at a position where fuel injected from a fuel injection valve impinges. 4. A method for manufacturing a piston for internal combustion engine, as claimed in claim 2 , wherein the end surface of the rotary implement is shaped into a circular flat surface. 5. A method for manufacturing a piston for internal combustion engine, as claimed in claim 1 , wherein the filler material contains at least one of zirconia, cordierite, mullite, silicon, silica, mica, talc silicate glass, acrylic glass, organic glass, silica aerogel, hollow ceramic beads, hollow glass beads and hollow metal balls, organic silicon compound, ceramic fiber, titanium alloy, low-alloy steel and cast iron. 6. A method for manufacturing a piston for internal combustion engine, as claimed in claim 1 , wherein the compacted body of the mixed powder is a green compact obtained by compacting the mixed powder. 7. A method for manufacturing a piston for internal combustion engine, as claimed in claim 1 , wherein a rib is previously formed at the periphery of the concave part and that in the friction bonding step the frictional heat is generated by pressing the rotary implement against the base material while covering the whole range of the concave part including the rib with an end surface of the rotary implement. 8. A method for manufacturing a piston for internal combustion engine, as claimed in claim 1 , further comprising a step of vacuuming air from the concave part, prior to a treatment for the friction bonding step. 9. A method for manufacturing a piston for internal combustion engine, as claimed in claim 1 , wherein heat treatment is performed after a treatment for the friction bonding step. 10. A method for manufacturing a piston for internal combustion engine, as claimed in claim 9 , wherein the heat treatment is a solution aging treatment or artificial aging treatment. 11. A method for manufacturing a piston for internal combustion engine, the method for manufacturing a piston for internal combustion engine comprising: a concave part-forming step for forming a concave part in a crown surface of the piston, the crown surface defining a combustion chamber; a lower layer-filling step for filling the concave part with a mixed powder or a compacted body of the mixed powder, the mixed powder being obtained by mixing a powder of a filler material smaller than a base material of the piston in thermal conductivity and a powder of a bonding material which may become an alloy or an intermetallic compound when blending with the base material; an upper layer-filling step where a high thermal conductive material having a thermal conductivity higher than that of the mixed powder or the compacted body of the mixed powder that is to become a lower layer which high thermal conductive material may become an alloy or an intermetallic compound when blending with the base material or a powder of the high thermal conductive material or a compacted body of the powder is loaded on the lower layer; and a friction bonding step of bringing a rotary implement into contact with a region of the concave part involving the high thermal conductive material or the powder of the high thermal conductive material or the compacted body of the powder that is to become an upper layer and then softening the high thermal conductive material or the powder of the high thermal conductive material or the compacted body of the powder by frictional heat, thereby bonding the high thermal conductive material or the powder of the high thermal conductive material or the compacted body of the powder to the concave part in a solid phase to form a high thermal conductive part. 12. A method for manufacturing a piston for internal combustion engine, the method for manufacturing a piston for internal combustion engine comprising: a concave part-forming step for forming a concave part in a crown surface of the piston, the crown surface defining a combustion chamber; a first material-filling step where a powder of a filler material smaller than a base material of the piston in thermal conductivity or a compacted body of the powder, and a powder of a bonding material which may become an alloy or an intermetallic compound when blending with the base material or a compacted body of the powder are charged into the concave part; a primary friction bonding step of bringing a rotary implement into contact with a region of the concave part involving the powder or compact body of the both materials and then softening the powder or compact body of the both materials by frictional heat, thereby bonding the powder or compact body of the both materials to the concave part in a solid phase to form a low thermal conductive part; a second material-filling step where a high thermal conductive material which is higher than the low thermal conductive part in thermal conductivity and may become an alloy or an intermetallic compound when blending with the base material, or a powder of the high thermal conductive material or a compacted body of the powder is loaded on the low thermal conductive part; and a secondary friction bonding step of bringing a rotary implement into contact with the high thermal conductive material or the powder of the high thermal conductive material or the compacted body of the powder and then softening the high thermal conductive material or the powder of the high thermal conductive material or the compacted body of the powder by frictional heat, thereby bonding the high thermal conductive material or the powder of the high thermal conductive material or the compacted body of the powder to the base material and the low thermal conductive part in a solid phase to form a high thermal conductive part. 13. A method for manufacturing a piston for internal combustion engine, as claimed in claim 12 , wherein: in the primary friction bonding step, the frictional heat is generated by pressing the rotary implement against the base material while covering the whole range of the concave part with an end surface of the rotary implement; in the secondary friction bonding step, the frictional he