In a molded body manufacturing method, after a raw material is put into a cavity of a mold, at least a part of the mold is irradiated with electromagnetic waves, or at least part of the mold is placed in an alternating electric field, to mold a molded body. The mold has a heating body, which absorbs the electromagnetic waves to generate heat or is placed in the alternating electric field to generate heat, outside the cavity. In at least part of a space between the heating body and the cavity, a transmission amount suppressing body that suppresses the amount of transmission of the electromagnetic waves or the alternating electric field into the cavity is provided, or at least part of the cavity is composed of the transmission amount suppressing body. When the heating body generates heat, the heat is transmitted to the raw material to perform molding.

In a molded body manufacturing method, after a raw material is put into a cavity of a mold, at least a part of the mold is irradiated with electromagnetic waves, or at least part of the mold is placed in an alternating electric field, to mold a molded body. The mold has a heating body, which absorbs the electromagnetic waves to generate heat or is placed in the alternating electric field to generate heat, outside the cavity. In at least part of a space between the heating body and the cavity, a transmission amount suppressing body that suppresses the amount of transmission of the electromagnetic waves or the alternating electric field into the cavity is provided, or at least part of the cavity is composed of the transmission amount suppressing body. When the heating body generates heat, the heat is transmitted to the raw material to perform molding.

There is disclosed a self-heating tool (10) for manufacturing a composite component, comprising: a support structure (24); a mandrel (26) onto which composite material can be applied; a heater (58) for heating the mandrel (26) during a curing operation; and a plurality of extendible support members (28) extending between the support structure (24) and the mandrel (26) to support the mandrel (26). Each extendible support member (28) is configured to change in length in response to thermal expansion of the mandrel (28) during a curing operation. A method of manufacturing a composite component using a self-heating tool is also disclosed.

There is disclosed a self-heating tool (10) for manufacturing a composite component, comprising: a support structure (24); a mandrel (26) onto which composite material can be applied; a heater (58) for heating the mandrel (26) during a curing operation; and a plurality of extendible support members (28) extending between the support structure (24) and the mandrel (26) to support the mandrel (26). Each extendible support member (28) is configured to change in length in response to thermal expansion of the mandrel (28) during a curing operation. A method of manufacturing a composite component using a self-heating tool is also disclosed.

A method include: providing a cylindrical mold made of metal, a shaped structure having a cylindrical shape, a rotation mechanism configured to rotatably support the cylindrical mold, and an electromagnetic induction coil configured to heat the cylindrical mold through electromagnetic induction; setting the shaped structure inside the cylindrical mold; and molding a cylindrical belt slab by heating the cylindrical mold by the electromagnetic induction coil, while the cylindrical mold is rotated by the rotation mechanism and the shaped structure is pressurized from inside and pressed against the cylindrical mold.

A method include: providing a cylindrical mold made of metal, a shaped structure having a cylindrical shape, a rotation mechanism configured to rotatably support the cylindrical mold, and an electromagnetic induction coil configured to heat the cylindrical mold through electromagnetic induction; setting the shaped structure inside the cylindrical mold; and molding a cylindrical belt slab by heating the cylindrical mold by the electromagnetic induction coil, while the cylindrical mold is rotated by the rotation mechanism and the shaped structure is pressurized from inside and pressed against the cylindrical mold.

The present invention relates to a tool, a tool system and a method for the production of particle foam parts, in particular for the manufacture of shoe soles. The shoe sole may be manufactured by welding foam particles using electromagnetic waves. The tool may comprise two mold halves forming a mold cavity corresponding to the shape of the shoe sole. The tool may be arranged between two capacitor plates. The mold cavity may be filled with the foam particles. The tool may then be closed and subjected to electromagnetic waves, in particular radio waves or microwaves, introduced into the mold cavity via the capacitor plates. The foam particles heated by the electromagnetic waves and at least partially fuse or bake together.

A method include: providing a cylindrical mold made of metal, a shaped structure having a cylindrical shape, a rotation mechanism configured to rotatably support the cylindrical mold, and an electromagnetic induction coil configured to heat the cylindrical mold through electromagnetic induction; setting the shaped structure inside the cylindrical mold; and molding a cylindrical belt slab by heating the cylindrical mold by the electromagnetic induction coil, while the cylindrical mold is rotated by the rotation mechanism and the shaped structure is pressurized from inside and pressed against the cylindrical mold.

A method include: providing a cylindrical mold made of metal, a shaped structure having a cylindrical shape, a rotation mechanism configured to rotatably support the cylindrical mold, and an electromagnetic induction coil configured to heat the cylindrical mold through electromagnetic induction; setting the shaped structure inside the cylindrical mold; and molding a cylindrical belt slab by heating the cylindrical mold by the electromagnetic induction coil, while the cylindrical mold is rotated by the rotation mechanism and the shaped structure is pressurized from inside and pressed against the cylindrical mold.

A soap recycling assembly for recycling soap pieces into soap bars includes a housing that defines an internal space. A power module and a heater are coupled to the housing and are positioned in the internal space. The heater is selectively operationally couplable to the power module. A first recess is positioned in a top of the housing. A plurality of legs is pivotally coupled to a bottom of the housing. The legs are positioned to reversibly pivot from a stowed configuration to a deployed configuration, wherein the legs are positioned substantially perpendicular to the bottom. The first recess is configured to insert soap pieces. The power module is positioned to couple to the heater to heat the soap pieces to a melt. The power module is positioned to decouple from the heater wherein the melt solidifies to a bar of soap.