A rotor manufacturing apparatus 1 is provided, the rotor manufacturing apparatus 1 including: a first mold 2 and a second mold 3 respectively arranged on one end surface and another end surface in the axial direction of a cylindrical rotor core 40 in order to seal the magnet insertion hole 42 in the process of filling the gap between a permanent magnet 51 and a magnet insertion hole 42 with the resin material 52 and solidifying a resin material 52, in which each of the first mold 2 and the second mold 3 is provided with positioning protrusion parts 6a, 6b, 7a, and 7b that are protruded in the axial direction and are intended to position the permanent magnet 51 in a predetermined position with respect to the magnet insertion hole 42.

A method for manufacturing a laminated iron core includes preheating a laminated body in which a plurality of iron core pieces are laminated and which includes a resin filling hole, measuring a temperature of the laminated body after preheating the laminated body, determining whether or not the temperature measured is within a predetermined range, feeding the laminated body into a molding device in a case where it is determined that the temperature is within the predetermined range, and filling the resin filling hole of the laminated body with a resin material in the molding device.

Disclosed is a rotor for a compressible fluid pump, in particular a blood pump that can be introduced into a patient's body through a blood vessel; said rotor comprises one or more impeller elements, is compressible and expansible between an expanded state and a compressed state, is made at least in part of a fiber-reinforced plastic material, is provided for rotating about an axis of rotation, and is characterized in that in the expanded state of the rotor, a first percentage, i.e. more than 30%, in particular more than 50%, of the fibers runs substantially straight between the first end thereof lying closest to the axis of rotation and a second end lying further away from the axis of rotation. According to the invention, the rotor retains its shape very well even when subjected to repeated mechanical stress.

The invention relates to a rotor for a compressible fluid pump, in particular a blood pump that can be introduced through a blood vessel into a patient's body, wherein said rotor comprises one or more conveying elements (15), is compressible and expandable between a first compressed state and a second radially expanded state, is made at least partially from a plastic reinforced with reinforcing elements, in particular fibers (10, 11, 13, 18, 19, 55, 56, 62, 63) and is provided for rotation about an axis of rotation (14). According to the invention, the rotor is tensioned in the first, compressed state and free from external stresses in the second, expanded state. A third state exists, which the rotor (42) occupies in the operating state under load. The reinforcing elements, in particular fibers, extend in the rotor in the third state at least in sections in a stretched manner.

A method for manufacturing a rotor includes clamping a first die and a second die so as to hold a core between the first die and the second die in a state in which a magnet is accommodated in a magnet housing hole of the core, injecting thermoplastic into the magnet housing hole, and opening the first die and the second die and removing the core and the magnet from a space between the first die and the second die. The removing the core and the magnet includes removing the core and the magnet from the space between the first die and the second die when a temperature of the thermoplastic injected into the magnet housing hole is higher than or equal to a glass transition point and lower than a melting point.

A rotor includes a rotor core including multiple housing holes, multiple magnets accommodated in the housing holes, and multiple plastic portions. Each plastic portion is formed by plastic that fills corresponding one of the housing holes and fixes the corresponding magnet to the rotor core. Each plastic portion includes an end face exposed from an opening of the corresponding housing hole. A gate mark is formed in the end face. A quotient obtained by dividing an area of the end face of each plastic portion by an area of the gate mark is in a range of 24 to 150.

A method for producing a positively balanceable internal armature to be used in an electric motor, in particular a direct-current electric motor, which makes it possible that the structural group is configured such that a balancing of the internal armature can take place with little technical effort. A manufacturing apparatus which is arranged to execute the proposed method or which can be operated by the proposed method. Further, an internal armature to be used in an electric motor as well as to the electric motor itself. Further, a computer program product is proposed, having control commands which implement the proposed method or operate the proposed manufacturing apparatus.

A resin injection apparatus includes: a mold die and a receiving die configured to hold a core body in an axial direction of the core body, the core body having a resin formation region serving as a region where resin is to be formed by injection of molten resin; a plurality of plungers; and a pot group attached to the mold die, the pot group including a plurality of pots proximately located next to each other in a direction. Each of the plurality of pots has a through hole in which a corresponding plunger of the plungers is insertable. The plurality of pots have a first coefficient of thermal expansion that is lower than a second coefficient of thermal expansion of the mold die.

A resin filling method that includes the steps of filling in a filling step the filling clearance with the molten resin pressurized by the pressurizing unit, through the first flow path and the second flow path, with the laminated core being held between the flow path plate in contact with the upper mold and the lower mold; moving the upper mold and the pressurizing unit up with respect to the flow path plate to create a space between the upper mold and the flow path plate; removing residual resin in a resin removing step remaining in the second flow path in the flow path plate, with the flow path plate being located on the laminated core; and moving in a core removing step the flow path plate up from the laminated core and then removing the laminated core from the lower mold.

An apparatus includes a mold unit and a receive unit which clamp a laminated iron core body from both sides in a lamination direction, the laminated iron core body including a plurality of laminated iron core pieces and a resin hole pierced in the lamination direction, a plunger which extrudes a resin of an inside of a resin pool part formed in the mold unit, and a cull plate arranged between the laminated iron core body and the mold unit. The cull plate includes a close contact part with the resin on a side opposed to the plunger, the close contact part including a projection projected to a side of the plunger beyond a groove bottom of a runner formed in the cull plate, or a recess recessed to a side of the laminated iron core body beyond the groove bottom of the runner.