The present invention provides a hollow rotor structure for a direct-current motor and a winding structure of the same are provided for use in a direct-current motor. The hollow rotor structure includes a commutator, can output element, and a hollow rotor. The hollow rotor includes an iron core wound with a plurality of windings and is formed with an axial hole extending along the axial direction of the hollow rotor. Once mounted in a housing, the hollow rotor is spaced from a stator fixed in the housing and is separately connected to the commutator and the output element. When the commutator supplies a current to each winding, the hollow rotor generates the corresponding electromagnetic fields, which repel the magnets on the stator respectively. Thus, the hollow rotor generates a rotating force and outputs the rotating force through the output element.

The present invention provides a hollow rotor structure for a direct-current motor and a winding structure of the same are provided for use in a direct-current motor. The hollow rotor structure includes a commutator, can output element, and a hollow rotor. The hollow rotor includes an iron core wound with a plurality of windings and is formed with an axial hole extending along the axial direction of the hollow rotor. Once mounted in a housing, the hollow rotor is spaced from a stator fixed in the housing and is separately connected to the commutator and the output element. When the commutator supplies a current to each winding, the hollow rotor generates the corresponding electromagnetic fields, which repel the magnets on the stator respectively. Thus, the hollow rotor generates a rotating force and outputs the rotating force through the output element.

An armature includes an armature core, teeth, a commutator, concentrated winding wires, and distributed winding wires. Each of the teeth includes a first branch portion and a second branch portion. Each of segments in the commutator has a riser. A start end and a terminal end of the concentrated winding wire are pulled out separately in a direction getting closer to the commutator and in a direction away from the commutator. The conductor between the concentrated winding wires is hooked by the riser by which the conductor between the other concentrated winding wires is not hooked. A start end and a terminal end of the distributed winding wire are pulled out separately in a direction getting closer to the commutator and in a direction away from the commutator. The conductor between the distributed winding wires is hooked by the riser by which at least one of the conductor between the concentrated winding wires and the conductor between the other distributed winding wires is not hooked.

An armature includes an armature core, teeth, a commutator, concentrated winding wires, and distributed winding wires. Each of the teeth includes a first branch portion and a second branch portion. Each of segments in the commutator has a riser. A start end and a terminal end of the concentrated winding wire are pulled out separately in a direction getting closer to the commutator and in a direction away from the commutator. The conductor between the concentrated winding wires is hooked by the riser by which the conductor between the other concentrated winding wires is not hooked. A start end and a terminal end of the distributed winding wire are pulled out separately in a direction getting closer to the commutator and in a direction away from the commutator. The conductor between the distributed winding wires is hooked by the riser by which at least one of the conductor between the concentrated winding wires and the conductor between the other distributed winding wires is not hooked.

A brush-commutated direct-current motor comprises a stator which is fitted with a plurality of field poles, a rotor which can rotate in relation to the stator about a rotation axis and which has a plurality of pole teeth, a plurality of windings, wherein a plurality of windings are arranged on each pole tooth, a commutator which is arranged on the rotor and has a plurality of lamellas, wherein each winding is connected to one of the lamellas by means of a first winding arm and is connected to another of the lamellas by means of a second winding arm, and a plurality of short-circuiting links which each electrically connect two windings to one another and to this end are each arranged on at least two lamellas of the commutator. The plurality of windings of the plurality of pole teeth are formed by a plurality of wire turns.

A brush-commutated direct-current motor comprises a stator which is fitted with a plurality of field poles, a rotor which can rotate in relation to the stator about a rotation axis and which has a plurality of pole teeth, a plurality of windings, wherein a plurality of windings are arranged on each pole tooth, a commutator which is arranged on the rotor and has a plurality of lamellas, wherein each winding is connected to one of the lamellas by means of a first winding arm and is connected to another of the lamellas by means of a second winding arm, and a plurality of short-circuiting links which each electrically connect two windings to one another and to this end are each arranged on at least two lamellas of the commutator. The plurality of windings of the plurality of pole teeth are formed by a plurality of wire turns.

The present invention provides a DC motor structure with a hollow rotor and inner and outer stators includes a housing, a commutator, and an output element, in addition to the hollow rotor and the stators. The commutator and the output element are received at the front and rear ends of the housing respectively. The outer stator, the hollow rotor, and the inner stator are sequentially arranged in the housing in a direction toward the central axis of the housing. The hollow rotor between the stators is wound with plural windings and has a front end and a rear end respectively connected to the commutator and the output element. When each winding receives a current from the commutator, the hollow rotor generates a corresponding electromagnetic field such that the commutator and the output element rotate simultaneously with the hollow rotor to output directly through the output element the rotating force generated by the hollow rotor.

The present invention provides a DC motor structure with a hollow rotor and inner and outer stators includes a housing, a commutator, and an output element, in addition to the hollow rotor and the stators. The commutator and the output element are received at the front and rear ends of the housing respectively. The outer stator, the hollow rotor, and the inner stator are sequentially arranged in the housing in a direction toward the central axis of the housing. The hollow rotor between the stators is wound with plural windings and has a front end and a rear end respectively connected to the commutator and the output element. When each winding receives a current from the commutator, the hollow rotor generates a corresponding electromagnetic field such that the commutator and the output element rotate simultaneously with the hollow rotor to output directly through the output element the rotating force generated by the hollow rotor.

The present invention provides a hollow rotor structure for a direct-current motor and a winding structure of the same are provided for use in a direct-current motor. The hollow rotor structure includes a commutator, can output element, and a hollow rotor. The hollow rotor includes an iron core wound with a plurality of windings and is formed with an axial hole extending along the axial direction of the hollow rotor. Once mounted in a housing, the hollow rotor is spaced from a stator fixed in the housing and is separately connected to the commutator and the output element. When the commutator supplies a current to each winding, the hollow rotor generates the corresponding electromagnetic fields, which repel the magnets on the stator respectively. Thus, the hollow rotor generates a rotating force and outputs the rotating force through the output element.

The present invention provides a nested stator structure for a DC motor is applicable to a DC motor and includes an outer stator and an inner stator. The outer stator, mounted in the housing of the DC motor, includes outer magnets fixed to the inner wall of the housing along the circumferential direction of the housing. Each two adjacent outer magnets are spaced apart and have opposite polarities. The inner stator, mounted in the outer stator, has its front and rear ends fixed to the front and rear ends of the housing respectively, is provided with inner magnets along the circumferential direction of the housing, and is spaced from the outer stator by a rotation space, where a hollow rotor is received. When supplied with electricity, the hollow rotor generates electromagnetic fields repelling the inner and outer magnets and is hence rotated, driving an output element simultaneously to output a rotating force.