A method for manufacturing a high-strength steel wooden golf head solves the difficulty in reducing the thickness of the striking faceplate of a conventional wooden golf head. The method includes placing a shell mold having a crucible portion and a cavity portion in communication with the crucible portion on a rotary table, placing a metal ingot in the crucible portion, followed by melting the metal ingot into molten metal in a vacuum environment, rotating the rotary table to cause molten metal to flow into the cavity portion under a centrifugal force, gradually slowing down the rotary table after the molten metal cools and solidifies, destroying the shell mold to obtain a casting including a cast product portion, and separating the cast product portion from the casting to obtain a casting product of the wooden golf head having a tensile strength of 240-350 ksi and a minimum thickness of 1.4-1.8 mm not including a groove depth of the striking faceplate.

A method for manufacturing a high-strength steel wooden golf head solves the difficulty in reducing the thickness of the striking faceplate of a conventional wooden golf head. The method includes placing a shell mold having a crucible portion and a cavity portion in communication with the crucible portion on a rotary table, placing a metal ingot in the crucible portion, followed by melting the metal ingot into molten metal in a vacuum environment, rotating the rotary table to cause molten metal to flow into the cavity portion under a centrifugal force, gradually slowing down the rotary table after the molten metal cools and solidifies, destroying the shell mold to obtain a casting including a cast product portion, and separating the cast product portion from the casting to obtain a casting product of the wooden golf head having a tensile strength of 240-350 ksi and a minimum thickness of 1.4-1.8 mm not including a groove depth of the striking faceplate.

A method for manufacturing a low-density steel wooden golf head solves the difficulty in reducing the thickness of a conventional wooden golf head. The method includes placing a shell mold having a crucible portion and a cavity portion in communication with the crucible portion on a rotary table, placing a metal ingot into the crucible portion, followed by melting the metal ingot in molten metal in a vacuum environment, rotating the rotary table to cause the molten metal to flow into the cavity portion under a centrifugal force, gradually slowing down the rotary table after the molten metal cools and solidifies, destroying the shell mold to obtain a casting including a cast product portion, and separating the cast product portion from the casting to obtain a casting product of a wooden golf head having a density of 6.5-7.6 g/cm.sup.3 and a minimum thickness of 0.4-0.6 mm.

A method for manufacturing a low-density steel wooden golf head solves the difficulty in reducing the thickness of a conventional wooden golf head. The method includes placing a shell mold having a crucible portion and a cavity portion in communication with the crucible portion on a rotary table, placing a metal ingot into the crucible portion, followed by melting the metal ingot in molten metal in a vacuum environment, rotating the rotary table to cause the molten metal to flow into the cavity portion under a centrifugal force, gradually slowing down the rotary table after the molten metal cools and solidifies, destroying the shell mold to obtain a casting including a cast product portion, and separating the cast product portion from the casting to obtain a casting product of a wooden golf head having a density of 6.5-7.6 g/cm.sup.3 and a minimum thickness of 0.4-0.6 mm.

A method includes placing a shell mold with a crucible portion and a casting portion in communication with the crucible portion on a rotary table, with the heterogeneous material including an embedded portion inlaying in the casting portion of the shell mold and a non-embedded portion locating in a cavity of the casting portion, placing a metal ingot into the crucible portion, followed by melting the metal ingot into molten metal in a vacuum environment, rotating the rotary table, causing the molten metal to flow into the cavity, destroying the shell mold after the molten metal solidifies to obtain a casting including a cast product portion separated from the casting to obtain a cast product of a golf club head, and removing the embedded portion of the heterogeneous material protruding from an outer periphery of the cast product of the golf club head.

A method includes placing a shell mold with a crucible portion and a casting portion in communication with the crucible portion on a rotary table, with the heterogeneous material including an embedded portion inlaying in the casting portion of the shell mold and a non-embedded portion locating in a cavity of the casting portion, placing a metal ingot into the crucible portion, followed by melting the metal ingot into molten metal in a vacuum environment, rotating the rotary table, causing the molten metal to flow into the cavity, destroying the shell mold after the molten metal solidifies to obtain a casting including a cast product portion separated from the casting to obtain a cast product of a golf club head, and removing the embedded portion of the heterogeneous material protruding from an outer periphery of the cast product of the golf club head.