Title of Invention	ASSEMBLING TYPE STATOR STRUCTURE OF MOTOR
Abstract	An assembling type stator structure of motor includes a main body of the stator having a plurality of scoop channels and a plurality of disassembled radial toothlets that are punched and stacked up by a plurality of silicon steel sheets. The configuration and size of the toothlets are such that they can be fitted into the matching scoop channels. The toothlets are connected to the main body of stator to assemble into an assembled stator by employing of the following four methods: single positioning #pin, double positioning pins, single )16' groove-and-tongue, as well as double groove-and tongue.

Title of Invention

ASSEMBLING TYPE STATOR STRUCTURE OF MOTOR

Abstract

An assembling type stator structure of motor includes a main body of the stator having a plurality of scoop channels and a plurality of disassembled radial toothlets that are punched and stacked up by a plurality of silicon steel sheets. The configuration and size of the toothlets are such that they can be fitted into the matching scoop channels. The toothlets are connected to the main body of stator to assemble into an assembled stator by employing of the following four methods: single positioning #pin, double positioning pins, single )16' groove-and-tongue, as well as double groove-and tongue.

Full Text	ASSEMBLING TYPE STATOR STRUCTURE OF MOTOR Field of the Invention The invention relates to an assembling type stator structure of motors, and more particularly, to an assembling type stator structure that provides the flexibility of being able to be assembled or disassembled in either axial or radial direction. Background of the Invention FIG. 1 is a schematic cross-sectional view of a stator structure of outer stator/inner rotor brushless motors of the prior art. The stator structure includes an outer stator 10, an inner rotor (not show), an main body of the outer stator 12, a tooth part 14, a plurality of bobbins 15, and a plurality of coils 17. FIG. 2 is a schematic cross-sectional view of another stator structure of the inner stator/outer rotor brushless motors of the prior art. The stator structure includes an inner stator 20, an outer rotor (not shown), an inner main body of the stator 22, a tooth part 24, a plurality of bobbins 25, and a plurality of coils 27. As shown in FIG. 1 and FIG. 2, wire winding, whether it is stacked winding or single tooth winding, of the stators 10 and 20 of the prior art of brushless motors has the disadvantage of being unable to effectively increase the occupying rate of winding. This is due to the restriction of the geometric shape of the stator. Especially, the custom-made winding machine for the stator 10 of an outer stator/inner rotor brushless motors of the prior art shown in FIG. 1 is very expensive because of its complicated actions of its mechanism. Hence, as shown in FIG. 3 and FIG. 4, there are improved outer stator/inner rotor and inner stator/outer rotor brushless motors provided of the prior art. FIG. 3 is a cross-sectional schematic view of the stator structure of outer stator/inner rotor brushless motors of the prior art. As shown in FIG. 3, the stator structure of outer stator/inner rotor brushless motors of the prior art includes an outer stator 30, a main body 32, a plurality of tooth parts 34, a plurality of dove-tail scoop channels 36, a plurality of bobbins 35, and a plurality of coils 37. FIG. 4 is a schematic cross-sectional view of the stator structure of the inner stator/outer rotor brushless motor of the prior art. As shown in FIG. 4, the stator structure of the inner stator/outer rotor brushless motor of the prior art includes an inner stator 40, an inner main body of the stator 42, a plurality of toothlets 44, a plurality of dove-tail scoop channel 46, a plurality of bobbins 45 and a plurality of coils 47. The assembly procedure of the brushless motors shown in FIG. 3 and FIG. 4 is done by disassembling the stator into the main body of the stator and a plurality of toothlets, then completing the winding on the bobbin and placing the toothlets therein first. Afterward, the toothlets and the main body of the stator are assembled by use of dove-tail scoop channel. FIG. 3-1 is a schematic view showing the assembling steps of the improved outer stator/inner rotor brushless motor of the prior art. Although the improved brushless motors shown in FIG. 3 and FIG. 4 have the advantages of reducing the winding cost, increasing the occupation rate of winding, and increasing the efficiency of the motor, the assembling work by use of dove-tail scoop channel for these improved brushless motors must be done and only be done in axial direction as shown in FIG. 3-1. Nevertheless, assembling in axial direction still has some degree of difficulty. Moreover, the assembling method by use of dove-tail scoop channel can cause serious stress concentration due to sharp angle at the comer of the dove-tail scoop channel which will make the dovetail scoop channel be subject to generate fracture. The assembling type of the outer stator motor of the prior art of US Patent 6,265,804 as shown in FIG. 11 has the disadvantage of being unable to increase the occupation rate of winding with single tooth winding although it has achieved the purpose of saving material. The assembling type outer stator motor of the prior art of US Patent 5,786,651 can achieve the purpose of saving material, increase the occupation rate of winding with single tooth winding, and eliminate the requirement of being assembled in axial direction. Nevertheless, it lacks of self-lock function, has to be fixed by the housing of the motor, has indirect heat dissipation only, and requires the outer stator components be winded together on the winding machine. FIG. 13 is a schematic cross-sectional view of a shunt outer stator brush motor of the prior art. The custom-made winding machine for single tooth winding is very expensive due to the requirement of complicated actions of mechanical operation. The foregoing statements are the disadvantages of the outer stator/inner rotor bmshless motor of the prior art. SUMMARY OF THE INVENTION In light of the disadvantages of the prior art, the invention provides an assembling type stator structure of motors that can increase the occupation rate of winding and reduce the winding cost by providing more convenient and flexible assembly methods in either axial direction or radial direction by use of positioning pins in comparison with the assembly of the prior art by use of dove-tail scoop channel which can only assemble in axial direction. In addition, all of the assembling methods provided by the invention have no comer in acute angle; therefore, there is no fracture problem due to stress concentration. Therefore, the object of the invention is to provide an assembling type stator structure of motors that is assembled by inserting and fitting a plurality of disassembled radial toothlets into a plurality of scoop channels of the main body of the stator. Another object of the invention is to provide an assembling type stator structure of motors that is assembled by connecting a plurality of disassembled radial toothlets to the main body of the stator by use of single positioning pin or double positioning pins. Another object of the invention is to provide an assembling type stator structure of motors that is assembled by connecting a plurality of disassembled radial toothlets to the main body of the stator by use of single groove-and-tongue or double groove-and-tongue. Another object of the invention is to provide an assembling type outer stator structure for shunt motors that is assembled by connecting the disassembled main body of the outer stator and the disassembled toothlets together by use of either single positioning pin, or double positioning pins, or single groove-and-tongue, or double groove-and-tongue. In order to accomplish the above-mentioned objects, the invention provides an assembling type stator structure of motors that includes a plurality of scoop channels and a plurality of disassembled radial toothlets. The disassembled radial toothlets are constructed by punching and stacking up a plurality of permeable silicon steel sheets. Each of the toothlets has configuration and size matching those of the scoop channels so that the toothlet can be inserted and tightly fitted into the scoop channel. Then, the assembling type stator can be assembled with one of the following four methods: single positioning pin, double positioning pin, single groove-and-tongue, and double groove-and-tongue. In order to understand fully the objectives, characteristics, and the efficacy of the invention in the preferred embodiment, a detailed illustration with accompanied drawing is described as follows: BRIEF DESCRIPTION OF THE DRAWING FIG. 1 is a schematic cross-sectional view of the stator structure of outer stator/inner rotor brushless motors of the prior art. FIG. 2 is a schematic cross-sectional view of the stator structure of the inner stator/outer rotor brushless motors of the prior art. FIG. 3 is a schematic cross-sectional view of the stator structure of outer stator/inner rotor brushless motors of the prior art that is connected by use of dove-tail scoop channel. FIG. 3-1 is a schematic isometric view showing the assembling steps for the improved outer stator/inner rotor brushless motors of the prior art that is connected by use of dove-tail scoop channel. FIG. 4 is a schematic cross-sectional view of the stator structure of the inner stator/outer rotor brushless motors of the prior art that is connected by use of dove-tail scoop channel. FIG. 5 is a schematic cross-sectional view of outer stator/inner rotor brushless motors of the invention that is assembled by use of single positioning pins. FIG. 5 A is a schematic cross-sectional view of outer stator/inner rotor brushless motors of the invention that is assembled by use of single positioning pins wherein the configuration of the rectangular dedendum of the disassembled radial toothlet is changed from linear shape to a circular arc recess. FIG. 5B is a schematic cross-sectional view of outer stator/inner rotor brushless motors of the invention that is assembled by use of single positioning pins wherein the shape of the rectangular dedendum of the disassembled radial toothlet is changed from linear shape to a V-shape notch. FIG. 5-1 is a schematic cross-sectional view of outer stator/inner rotor brushless motors of the invention that is assembled by use of double positioning pins. FIG. 5-1A is a schematic cross-sectional view of outer stator/inner rotor brushless motors of the invention that is assembled by use of double positioning pins wherein the shape of the inner stator/outer rotor brushless motor of the rectangular dedendum of the radial toothlet is changed from linear shape to a circular-arc-shape recess. FIG. 5-IB is a schematic cross-sectional view of outer stator/inner rotor bmshless motors of the invention that is assembled by use of double positioning pins wherein the shape of the inner stator/outer rotor bmshless motor of the rectangular dedendum of the radial toothlet is changed from linear shape to a V-shape recess. FIG. 5-2 is a schematic cross-sectional view of outer stator/inner rotor brushless motors of the invention that is assembled by use of single groove-and-tongue. FIG. 5-2A is a schematic cross-sectional view of outer stator/inner rotor bmshless motors of the invention that is assembled by use of single groove-and-tongue wherein the shape of the rectangular dedendum of the radial toothlet is changed from linear shape to a circular-arc-shape recess. FIG. 5-2B is a schematic cross-sectional view of outer stator/inner rotor bmshless motors of the invention that is assembled by use of single groove-and-tongue wherein the shape of the rectangular dedendum of the radial toothlet is changed from linear shape to a V-shape recess. FIG. 5-3 is a schematic cross-sectional view of outer stator/inner rotor bmshless motors of the invention that is assembled by use of double groove-and-tongue. FIG. 5-3A is a schematic cross-sectional view of outer stator/inner rotor brushless motors of the invention that is assembled by use of double groove-and-tongue wherein the shape of the rectangular dedendum of the radial toothlet is changed from linear shape to a circular-arc-shape recess. FIG. 5-3B is a schematic cross-sectional view of outer stator/inner rotor brushless motors of the invention that is assembled by use of double groove-and-tongue wherein the shape of the rectangular dedendum of the radial toothlet is changed from linear shape to a V-shape recess. FIG. 6A is a schematic cross-sectional view of the main body of the stator 52 of the outer stator/inner rotor brushless motors of the invention that is assembled by use of single positioning pins. FIG. 6AA is a schematic cross-sectional view of the main body of the stator 52 of the outer stator/inner rotor brushless motors of the invention that is assembled by use of single positioning pins wherein the contact surface to the dedendum of the radial toothlet is changed from linear shape to a circular-arc-shape recess. FIG. 6AB is a schematic cross-sectional view of outer stator/inner rotor brushless motors of the invention that is assembled by use of single positioning pins wherein the contact surface to the rectangular dedendum of the radial toothlet is changed from linear shape to a V-shape recess. FIG. 6A-1 is a schematic cross-sectional view of the main body 52 of the outer stator/inner rotor brushless motors of the invention that is assembled by use of double positioning pins. FIG. 6A-1A is a schematic cross-sectional view of the main body 52 of the outer stator/inner rotor brushless motors of the invention that is assembled by use of double positioning pins wherein the contact surface to the rectangular dedendum of the radial toothlet is changed from linear shape to a circular-arc-shape recess. FIG. 6A-1B is a schematic cross-sectional view of the main body 52 of the outer stator/inner rotor brushless motors of the invention that is assembled by use of double positioning pins wherein the contact surface to the rectangular dedendum of the radial toothlet is changed from linear shape to a V-shape recess. FIG. 6A-2 is a schematic cross-sectional view of the main body 52 of the outer stator/inner rotor brushless motors of the invention that is assembled by use of single groove-and-tongue. FIG, 6A-2A is a schematic cross-sectional view of the main body 52 of the outer stator/inner rotor brushless motors of the invention that is assembled by use of single groove-and-tongue wherein the contact surface to the rectangular dedendum of the radial toothlet is changed from linear shape to a circular-arc-shape recess. FIG. 6A-2B is a schematic cross-sectional view of the main body 52 of the outer stator/inner rotor brushless motors of the invention that is assembled by use of single groove-and-tongue wherein the contact surface to the rectangular dedendum of the radial toothlet is changed from linear shape to a V-shape recess. FIG. 6A-3 is a schematic cross-sectional view of the main body 52 of the outer stator/inner rotor brushless motors of the invention that is assembled by use of double groove-and-tongue. FIG. 6A-3 A is a schematic cross-sectional view of the main body 52 of the outer stator/inner rotor brushless motors of the invention that is assembled by use of double groove-and-tongue wherein the contact surface to the rectangular dedendum of the radial toothlet is changed from linear shape to a circular-arc-shape recess. FIG. 6A-3B is a schematic cross-sectional view of the main body 52 of the outer stator/inner rotor brushless motors of the invention that is assembled by use of double groove-and-tongue wherein the contact surface to the rectangular dedendum of the radial toothlet is changed from linear shape to a V-shape recess. FIG. 6B is a schematic cross-sectional view of a layout of a plurality of disassembled radial toothlets 54 of the invention applied in outer stator/inner rotor brushless motors assembled by use of single positioning pins. FIG. 6BA is a schematic cross-sectional view of the rectangular dedendum of a plurality of disassembled radial toothlets 54 of the invention applied in outer stator/inner rotor brushless motors assembled by use of single positioning pins wherein the contact surface to the main body of the stator is changed from linear shape to a circular-arc-shape recess. FIG. 6BB is a schematic cross-sectional view of the rectangular dedendum of a plurality of disassembled radial toothlets 54 of the invention applied in outer stator/inner rotor brushless motors assembled by use of single positioning pins wherein the contact surface to the main body of the stator is changed from linear shape to a V-shape recess. FIG. 6B-1 is a schematic cross-sectional view of a layout of a plurahty of disassembled radial toothlets 54 of the invention applied in outer stator/inner rotor brushless motors assembled by use of double positioning pins. FIG. 6B-1A is a schematic cross-sectional view of the rectangular dedendum of a plurality of disassembled radial toothlets 54 of the invention applied in outer stator/inner rotor brushless motors assembled by use of double positioning pins wherein the contact surface to the main body of the stator is changed from linear shape to a circular-arc-shape recess. FIG. 6B-1B is a schematic cross-sectional view of a plurality of disassembled radial toothlet 54 of the invention applied in outer stator/inner rotor brushless motors assembled by use of double positioning pins wherein the contact surface to the main body of the stator is changed from linear shape to a V-shape recess. FIG. 7 is an schematic isometric view of the invention showing the assembling steps for the outer stator/inner rotor brushless motors by use of single positioning pins. FIG. 7-2 is an schematic isometric view of the invention showing the assembling steps for the outer stator/inner rotor brushless motors by use of single groove-and-tongue. FIG. 8 is a schematic cross-sectional view of the inner stator/outer rotor brushless motors of the invention assembled by use of single positioning pins. FIG. 8 AA is a schematic cross-sectional view of the inner stator/outer rotor brushless motors of the invention assembled by use of single positioning pins wherein the shape of the inner stator/outer rotor brushless motor of the rectangular dedendum of the disassembled radial toothlet is changed from linear shape to a circular-arc-shape recess. FIG. 8BB is a schematic cross-sectional view of the inner stator/outer rotor brushless motors of the invention assembled by use of single positioning pins wherein the shape of the rectangular dedendum of the disassembled radial toothlet is changed from linear shape to a V-shape recess. FIG. 8-1 is a schematic cross-sectional view of the inner stator/outer rotor brushless motors of the invention assembled by use of double positioning pins. FIG. 8-1A is a schematic cross-sectional view of the inner stator/outer rotor brushless motors of the invention assembled by use of double positioning pins wherein the shape of the inner stator/outer rotor brushless motor of the rectangular dedendum of the radial toothlet is changed from linear shape to a circular-arc-shape recess. FIG. 8-IB is a schematic cross-sectional view of the inner stator/outer rotor brushless motors of the invention assembled by use of double positioning pins wherein the shape of the inner stator/outer rotor brushless motor of the rectangular dedendum of the radial toothlet is changed from linear shape to a V-shape recess. FIG, 8-2 is a schematic cross-sectional view of the inner stator/outer rotor brushless motors of the invention assembled by use of single groove-and-tongue. FIG. 8-2A is a schematic cross-sectional view of the inner stator/outer rotor brushless motors of the invention assembled by use of single groove-and-tongue wherein the shape of the inner stator/outer rotor bmshless motor of the rectangular dedendum of the radial toothlet is changed from linear shape to a circular-arc-shape recess. FIG. 8-2B is a schematic cross-sectional view of the irmer stator/outer rotor brushless motors of the invention assembled by use of single groove-and-tongue wherein the shape of the inner stator/outer rotor bmshless motor of the rectangular dedendum of the radial toothlet is changed from linear shape to a V-shape recess. FIG. 8-3 is a schematic cross-sectional view of the inner stator/outer rotor brushless motors of the invention assembled by use of double groove-and-tongue. FIG. 8-3 A is a schematic cross-sectional view of the inner stator/outer rotor brushless motors of the invention assembled by use of double groove-and-tongue wherein the shape of the inner stator/outer rotor brushless motor of the rectangular dedendum of the radial toothlet is changed from linear shape to a circular- arc-shape recess. FIG. 8-3B is a schematic cross-sectional view of the inner stator/outer rotor brushless motors of the invention assembled by use of double groove-and-tongue wherein the shape of the inner stator/outer rotor brushless motor of the rectangular dedendum of the radial toothlet is changed from linear shape to a V-shape recess. FIG. 8A is a schematic isometric view showing the assembling steps of the inner stator/outer rotor brushless motors of the invention assembled by use of single positioning pins. FIG, 8B is a schematic isometric view showing the assembling steps of the inner stator/outer rotor brushless motors assembled by use of single groove-and-tongue. FIG. 9A is a schematic cross-sectional view of the main body 82 of the inner stator/outer rotor brushless motors of the invention assembled by use of single positioning pins. FIG. 9AA is a schematic cross-sectional view of the main body 82 of the inner stator/outer rotor brushless motors of the invention assembled by use of single positioning pins wherein the contact surface to the rectangular dedendum of the radial toothlet is changed from linear shape to a circular-arc-shape recess. FIG. 9AB is a schematic cross-sectional view of the main body 82 of the inner stator of the inner stator/outer rotor brushless motors of the invention assembled by use of single positioning pins wherein the shape of the rectangular dedendum of the disassembled radial toothlet is changed from linear shape to a V-shape recess. FIG. 9A-1 is a schematic cross-sectional view of the inner main body of the stator 82 of the invention applied in inner stator/outer rotor brushless motors assembled by use of double positioning pins. FIG. 9A-1A is a schematic cross-sectional view of the main body 82 of the inner stator of the inner stator/outer rotor brushless motors of the invention assembled by use of single positioning pins wherein the shape of the rectangular dedendum of the disassembled radial toothlet is changed from linear shape to a circular-arc-shape recess. FIG. 9A-1B is a schematic cross-sectional view of the main body 82 of the inner stator of the inner stator/outer rotor brushless motors of the invention assembled by use of single positioning pins wherein the shape of the rectangular dedendum of the disassembled radial toothlet is changed from linear shape to a V-shape recess. FIG. 9A-2 is a schematic cross-sectional view of the main body 82 of the inner stator/outer rotor brushless motors of the invention assembled by use of single groove-and-tongue. FIG. 9A-2A is a schematic cross-sectional view of the main body 82 of the inner stator/outer rotor brushless motors of the invention assembled by use of single groove-and-tongue wherein the contact surface to the rectangular dedendum of the radial toothlet is changed from linear shape to a circular-arc-shape recess. FIG, 9A-2B is a schematic cross-sectional view of the main body 82 of the inner stator/outer rotor brushless motors of the invention assembled by use of single groove-and-tongue wherein the contact surface to the rectangular dedendum of the radial toothlet is changed from linear shape to a V-shape recess. FIG. 9A-3 is a schematic cross-sectional view of the main body 82 of the inner stator/outer rotor brushless motors of the invention assembled by use of double groove-and-tongue, FIG. 9A-3 A is a schematic cross-sectional view of the main body 82 of the inner stator/outer rotor brushless motors of the invention assembled by use of double groove-and-tongue wherein the contact surface to the rectangular dedendum of the radial toothlet is changed from linear shape to a circular-arc-shape recess. FIG. 9A-3B is a schematic cross-sectional view of the main body 82 of the inner stator/outer rotor brushless motors of the invention assembled by use of double groove-and-tongue wherein the contact surface to the rectangular dedendum of the radial toothlet is changed from linear shape to a V-shape recess, FIG. 9B is a schematic cross-sectional view of the main body 84 of the inner stator/outer rotor brushless motors of the invention assembled by use of single positioning pins. FIG. 9B A is a schematic cross-sectional view of the main body 84 of the inner stator/outer rotor brushless motors of the invention assembled by use of single positioning pins wherein the contact surface to the rectangular dedendum of the radial toothlet is changed from linear shape to a circular-arc-shape recess. FIG. 9BB is a schematic cross-sectional view of the main body 84 of the inner stator of the inner stator/outer rotor brushless motors of the invention assembled by use of single positioning pins wherein the shape of the rectangular dedendum of ■ the disassembled radial toothlet is changed from linear shape to a V-shape recess. FIG. 9B-1 is a schematic cross-sectional view of the main body 84 of the inner stator/outer rotor brushless motors of the invention assembled by use of double positioning pins. FIG. 9B-1A is a schematic cross-sectional view of the main body 84 of the inner stator of the inner stator/outer rotor brushless motors of the invention assembled by use of single positioning pins wherein the shape of the rectangular dedendum of the disassembled radial toothlet is changed from linear shape to a circular-arc-shape recess, FIG. 9B-1B is a schematic cross-sectional view of the main body 84 of the inner stator of the inner stator/outer rotor brushless motors of the invention assembled by use of single positioning pins wherein the shape of the rectangular dedendum of the disassembled radial toothlet is changed from linear shape to a V-shape recess. FIG. 10 is a schematic punching diagram of the main body 52 of the outer stator of the invention shown in FIG. 6A and FIG. 6A-2. FIG. 11 is a schematic cross-sectional view of the structure of the assembling type outer stator motor of the prior art of US Patent 6,265,804. FIG. 12 is a schematic cross-sectional view of the structure of the assembling type outer stator motor of the prior art of US Patent 5,786,651. FIG. 13 is a schematic cross-sectional view of the outer stator for outer stator brush shunt motor of the prior art. FIG. 14 is a schematic cross-sectional view of the assembling type dipole outer stator shunt brush motor of the invention, in which the main body of the stator is not disassembled, and the dedendum of the radial toothlet is connected to the main body of the stator by use of double positioning pins. FIG. 14-1 is a schematic cross-sectional view of the assembling type dipole outer stator shunt brush motor of the invention, in which the main body of the outer stator is assembled by use of single positioning pin, and the dedendum of the radial toothlet is connected to the main body of the stator by use of double positioning pins. FIG. 14-2 is a schematic cross-sectional view of the assembling type dipole outer stator shunt brush motor of the invention, in which the main body of the outer stator is assembled by use of single semi-circular groove-and-tongue, and the dedendum of the radial toothlet is connected to the main body of the stator by use of double positioning pins. FIG. 14-3 is a schematic cross-sectional view of the assembling type dipole outer stator shunt brush motor of the invention, in which the main body of the stator is not disassembled, and the dedendum of the radial toothlet is connected to the main body of the stator by use of double semi-circular groove-and-tongue. FIG. 14-4 is a schematic cross-sectional view of the assembling type dipole outer stator shunt brush motor of the invention, in which the main body of the outer stator is assembled by use of single positioning pin, and the dedendum of the radial toothlet is connected to the main body of the stator by use of double semicircular groove-and-tongue. FIG. 14-5 is a schematic cross-sectional view of the assembling type dipole outer stator shunt brush motor of the invention, in which the main body of the outer stator is assembled by use of single semi-circular groove-and-tongue, and the dedendum of the radial toothlet is connected to the main body of the stator by use of double semi-circular groove-and-tongue. FIG. 15 is a schematic cross-sectional view of the assembling type quadri-pole outer stator shunt brush motor of the invention, in which the main body of the stator is not disassembled, and the dedendum of the radial toothlet is connected to the main body of the stator by use of double positioning pins FIG. 15-1 is a schematic cross-sectional view of the assembling type quadri-pole outer stator shunt brush motor of the invention, in which the main body of the outer stator is assembled by use of single positioning pin, and the dedendum of the radial toothlet is connected to the main body of the stator by use of double positioning pins. FIG. 15-2 is a schematic cross-sectional view of the assembling type quadri-pole outer stator shunt brush motor of the invention, in which the main body of the outer stator is assembled by use of single semi-circular groove-and-tongue, and the dedendum of the radial toothlet is connected to the main body of the stator by use of double positioning pins. FIG. 15-3 is a schematic cross-sectional view of the assembling type quadri-pole outer stator shunt brush motor of the invention, in which the main body of the stator is not disassembled, and the dedendum of the radial toothlet is connected to the main body of the stator by use of double semi-circular groove-and-tongue. FIG, 15-4 is a schematic cross-sectional view of the assembling type quadri-pole outer stator shunt brush motor of the invention, in which the main body of the outer stator is assembled by use of single positioning pin, and the dedendum of the radial toothlet is connected to the main body of the stator by use of double semi-circular groove-and-tongue. FIG. 15-5 is a schematic cross-sectional view of the assembling type quadri-pole outer stator shunt brush motor of the invention, in which the main body of the outer stator is assembled by use of single semi-circular groove-and-tongue, and the dedendum of the radial toothlet is connected to the main body of the stator by use of double semi-circular groove-and-tongue. DETAILED DESCRIPTION OF THE EMBODIMENTS [Outer stator/inner rotor brushless motor] FIG. 5 is a schematic cross-sectional view of the invention appUed in outer stator/inner rotor brushless motors by use of single positioning pins. As shown in FIG. 5, the outer stator/inner rotor brushless motor of the invention includes an outer stator 50 and an inner rotor (not shown in FIG. 5). The outer stator 50 includes a main body of the outer stator 52, a plurality of toothlets 54, a plurality of positioning pins 72 (refer to FIG. 7), a plurality of bobbins 55, and a plurality of coils 57, FIG. 6A is a schematic cross-sectional view of the main body of the outer stator 52 of the invention applied in outer stator/inner rotor brushless motors. FIG. 6B is a sectional configuration view of a plurality of the disassembled radial toothlets applied in outer stator/inner rotor brushless motors. As shown in FIG. 6A and FIG. 6B, a number of a plurality of scoop channels 53 is evenly allocated on the intemal side of the main body of the outer stator 52 according the number of the toothlets of the stator for housing a plurality of toothlets 54 with the same number. A plurality of toothlets 54 thereof is disassembled according to the actually required number of the toothlets of the motor's outer stator 12 of the prior art shown in FIG. 1. As shown in FIG. 6B, each of a plurality of toothlets 54 includes a addendum 61 and a rectangular dedendum 63. The toothlet is constructed by punching and stacking up a plurality of permeable silicon steel sheets (refer to FIG. 7). The end surface 64 of the addendum 61 is a circular arc surface, and an applicable air gap (not shown in FIG. 7) is kept from its corresponding rotor (not shown in FIG. 7). The dedendum 63 of each toothlet 54 has the configuration and size matching those of the scoop channel 53 so that the toothlet can be inserted and tightly fitted into the scoop channel 53. Each of two comers of the rectangular dedendum 63 has a chamfer (□□) 65 to facilitate the insertion of the toothlet into the main body of the stator 52. The dedendum 63 of each disassembled radial toothlet 54 is inserted to the scoop channel 53 and both are connected together by use of a single positioning pin to construct the assembling type outer stator/inner rotor motor. As shown in FIG. 6A, one intemal side of each scoop channel 53 has a semi-circular recess 56; correspondingly, one side of the dedendum 63 of each disassembled radial toothlet 54 also has a corresponding semi-circular recess 66. The position of the semi-circular recess 66 is such that it will correspond to the semicircular recess 56 on the intemal side of the scoop channel 53 when the dedendum 63 of each toothlet 54 is inserted and tightly fitted into the scoop channel 53; as a result, an assembly hole 58 is formed between one side of the scoop channel 53 and the corresponding side of the dedendum 63 of the toothlet 54. On the other hand, a plurality of bobbins 55 made of insulate material is used to be slipped on a plurality of toothlets 54 for winding, FIG. 7 is a isometric diagram for the assembly procedure of the outer stator/inner rotor brushless motors. As shown in FIG. 7, the stator of the motor is assembled in the following four steps. Step 1: appropriately place the constructed main body of the stator 52 of the outer stator/inner rotor motor; Step 2: place a plurality of coils 57 that has completed winding on the bobbin 55 at an appropriate position inside the main body of the outer stator 52; Step 3: insert one single toothlet 54 after the other into the scoop channel 53 of the main body of the outer stator 52 in radial direction starting from the center of the axis outward as the pointed direction of arrow head 71; thereafter, knock the positioning pin 72 into the corresponding circular assembly hole 58 one by one in the direction pointed by arrow head 73; Step 4: lastly, complete the assembly of the stator of outer stator/inner rotor motor. Since the assembling is in radial direction, and there is a chamfer 65 is at each comer of each dedendum 63, the assembly procedure is easier and faster as comparing with the assembly procedure of the prior art shown in FIG. 3-lthat strictly requires the assembling be done in axial direction by use of dove-tail scoop channel. Moreover, the invention increases the occupation rate of winding in single toothlet winding, and one needs only to place the bobbin on the winding machine to wind simultaneously. A more important feature is that when it comes to assembling, every toothlet can be easily assembled one by one in radial direction starting from the center of the axis, then fixed with positioning pin, and because of the self-locking capability, no extra component is required for fixation. The assembly of the assembling type outer stator/inner rotor motors is accomplished with the following four connecting methods: single positioning pin, double positioning pin, single groove-and-tongue, and double groove-and-tongue. The connecting method for the stator structure by use of single positioning pin has been described previously As for the connecting method with double positioning pins for the stator structure, it can be referred to FIG. 5-1, FIG. 6A-1, and FIG. 6B-1 which are corresponding to FIG. 5, FIG. 6A, and FIG. 6B respectively. As shown in FIG. 5-1, FIG. 6A-1, and FIG. 6B-1, each of the two internal sides of scoop channel 53 on the main body of the outer stator 52 has a semi-circular recess 56 (refer to FIG. 6A-1); correspondingly, each of the two sides of the dedendum 63 of each disassembled radial toothlet 54 also has a semi-circular recess 66 (refer to FIG. 6B-1). The position of the two semi-circular recesses 66 are such that they will correspond to two semi-circular recesses 56 on the two internal sides of the scoop channel 53 when the dedendum 63 of each toothlet 54 is inserted and tightly fitted into the scoop channel 53. As a result, two assembly holes 58 (refer to FIG. 5-1) are formed between the two sides of the scoop channel 53 and their corresponding sides of the dedendum 63 of the toothlet 54. The assembly procedure is the same as the one shown in FIG. 7 except that it requires two positioning pins for the toothlet 54. The rest of the assembly procedure are the same as the single positioning pin method and shall not be repeated here. Corresponding to FIG. 5, FIG. 6A, and FIG. 7 respectively, FIG. 5-2, FIG. 6A-2, and FIG. 7-2 show the connecting method of the stator structure by use of single groove-and-tongue. As shown in. FIG.5-2 and FIG.6A-2, one internal side of each scoop channel 53 on the main body of the outer stator 52 (refer to FIG. 6A-2) has a semicircular protuberance 62; correspondingly, one side of each dedendum 63 of the disassembled radial toothlet 54 (refer to FIG. 5-2) has a semi-circular recess 66. The position of the protuberance and the concave are such that when the dedendum 63 of each toothlet 54 is inserted and tightly fitted into each scoop channel 53, the semicircular recess 66 on the toothlet 54 and the semi-circular protuberance 62 inside the scoop channel 53 are engaged each other. FIG. 7-2 is a isometric view of the invention applied in outer stator/inner rotor brushless motors that is assembled by use of single groove-and-tongue wherein the assembling procedure is described below with reference to FIG. 7-2. Step 1: appropriately place a plurality of coils 57 that has completed winding on the bobbin 55. Step 2: insert one single toothlet 54 after the other into the bobbin 55 in radial direction starting from the center of the axis outward in the direction pointed by arrow head 71. Step 3: fit the coil 57 with inserted toothlets 54 into the scoop channel 53 inside the main body of the outer stator 52 of the outer stator 50 in axial direction in the direction indicated by arrow head 77, so that the semi-circular recess 66 on the toothlet 54 and the semi-circular protuberance 62 inside the scoop channel 53 are engaged each other. Step 4: complete the assembly of the stator of outer stator/inner rotor motor as the last step. This design is more applicable for motors of lower stacking ratio of silicon steel sheets because as when it comes to assembling the outer stator 50, each toothlet 54 must be inserted into the bobbin 55 that has completed winding and then be inserted into the main body of the outer stator 52 in axial direction together. Otherwise, wire connection can be complicated if the toothlet 54 is inserted into the main body of the outer stator 52 one by one. Corresponding to FIG. 5-2 and 6A-2, respectively are FIG. 5-3 and FIG. 6A-3 that show the connecting method of the stator structure by use of double groove-and-tongue. As shown in FIG. 5-3 and FIG. 6A-3, each of the two intemal sides of each scoop channel 53 on the main body of the outer stator 52 (refer to FIG. 6A-3) has a semicircular protuberance 62; correspondingly, each of the two sides of the dedendum 63 of each disassembled radial toothlets 54 (refer to FIG. 5-3) has a semi-circular recess 66. The position of the protuberance 62 and the recess 66 are such that when the dedendum 63 of each toothlet 54 is inserted and tightly fitted into each scoop channel 53, the two semi-circular recesses 66 on the toothlet 54 and the two semi-circular protuberances 62 inside the scoop channel 53 are engaged each other. The assembling procedure for the assembly of the motor stator is the same as that shown in FIG. 7-2, thereby, shall not be repeated here. In comparison with the connecting method by use of dove-tail scoop channel for assembly of the prior art shown in FIG. 3-1, the invention's connecting methods, as described in the previous sections, by use of single groove-and-tongue or double groove-and-tongue eliminate the fracture problem due the stress concentration because there are no comers with acute angle in the semi-circular recesses 66 on the toothlet 54 and the semi-circular protuberance 62 inside the scoop channel 53 when they are engaged each other. The outer stator 50 for various outer stator/inner rotor motors is assembled with a plurality of disassembled radial toothlets 54 and an main body of the outer stator 52 by use of the following four connecting methods: single positioning pin, double positioning pin, single groove-and-tongue, and double groove-and-tongue. Nevertheless, the contact surface 541 of the bottom of the rectangular toothlet root of the outer stator's disassembled radial toothlets to the stator main body can be linear shape, V-shape, circular arc shape or any other shape that does not prevent each toothlet from being pushed and tightly fitted into the main body of the stator in radial direction. In other words, the shape of the contact surface 541 can be changed according the requirement of the design. For example, a V-shape or circular-arc-shape recess or protuberance (or stick out) can be added to the rectangular dedendum of the outer stator's disassembled radial toothlet to increase the stability of fixation to the main body of the stator. The connecting method of its assembly is the same as the four connecting methods described in the previous sections, which are: single positioning pin, double positioning pins, single groove-and-tongue, and double groove-and-tongue. FIG. 5 A is a modified diagram of FIG. 5 for single positioning pin connecting method showing that the change of shape, from linear shape to a circular-arc-shape recess, has been made to the bottom 541 of the rectangular dedendum of the radial toothlet. FIG. 6AA is a modified diagram of FIG. 6A for single positioning pin connecting method showing that the change of shape, from linear shape to a circular-arc-shape recess, has been made to the contact surface 531 of the main body of the stator to the bottom of the radial toothless rectangular dedendum. FIG. 6BA is a modified diagram of 6B for single positioning pin connecting method showing that the change of shape, from linear shape to a circular-arc-shape recess, has been made to the contact surface 631 of the bottom of the radial toothless rectangular dedendum to the main body of the stator. FIG. 5-1 A, FIG, 5-2A, and FIG. 5-3A are the assembly diagrams of the assembling type outer stator/inner rotor motor when a circular-arc-shape recess is added to the bottom 541 of the rectangular dedendum of the outer stator's radial toothlet. Basically, all of the assembly methods are completely the same as the assembly of the invention's outer stator/inner rotor motor if the circular-arc-shape recess is not added to the rectangular dedendum of the outer stator's radial toothlet. FIG 6A-lA, FIG. 6A-2A, and FIG. 6A-3A are the diagrams that shows the contact surface 531 of the main body of the stator to the bottom of the radial toothlet's rectangular dedendum changing from linear shape to a circular-arc-shape recess. FIG. 6B-1A and FIG. 6B-2A are the diagrams that shows the contact surface 631 of the bottom of the radial toothless rectangular dedendum to the main body of the stator changing from linear shape to a circular-arc-shape recess. FIG. 5B is a modified diagram of FIG. 5 that shows the change of the bottom 541 of the radial toothless rectangular dedendum from linear shape to a V-shape recess for single positioning pin connecting method. FIG. 6AB is a modified diagram of FIG. 6A that shows the change of the contact surface 531 of the main body of the stator to the bottom of the radial toothless rectangular dedendum from linear shape to a V-shape recess for single positioning pin connecting method. FIG. 6BB is a modified diagram of FIG. 6B that shows the changes of the contact surface 631 of the bottom of the radial toothless rectangular dedendum to the main body of the stator from linear shape to a V-shape recess for single positioning pin connecting method. FIG. 5-lB, FIG. 5-2B, and FIG. 5-3B are the assembly diagrams of the assembling type outer stator/inner rotor motor when a V"Shape recess is added to the bottom 541 of the rectangular dedendum of the outer stator*s radial toothlet. All of the assembly methods are completely the same as the assembly of the invention's outer stator/inner rotor motor if the V-shape recess is not added to the rectangular dedendum of the outer stator's radial toothlet. FIG. 6A-1B, FIG. 6A-2B, and FIG, 6A-3B are the diagrams that shows the change of the contact surface 531 of the main body of the stator to the bottom of the radial toothless rectangular dedendum from linear shape to a V-shape recess. FIG. 6B-1B and FIG. 6B-2B are diagrams that show the change of the contact surface 631 of the bottom of the radial toothlet's rectangular dedendum to the main body of the stator from linear shape to a V-shape recess. As for the contact surfaces of the rectangular dedendum of the outer stator's toothlet and the main body of the stator, no matter whether it is a V-shape or circular arc shape protuberance, or any other shaped protuberance that does not prevent each radial toothlet from being pushed and tightly fitted into the main body of the stator in radial direction, the principle is similar to the previous description of adding V-shape or circular-arc-shape recess, and shall not be repeated here. FIG. 10 is the diagram that depicts the punching operation of the invention's main body of the outer stator 52 shown in FIG. 6A and the main body of the outer stator 52 shown in FIG. 6A-2. There is only one difference in hole-punching operation between the main body of the outer stator 52 (used for the assembling by use of single positioning pins) in FIG. 6A and the main body of the outer stator 52 (used for the assembling by use of single groove-and-tongue) in FIG. 6A-2. Therefore, the design in sequential punching mold can be plan together. Moreover, since one needs only to determine the enabling or disabling of this punching operation during the punching process to obtain two components with different design, the developing cost of the mold can be greatly reduced. [Inner stator/outer rotor brushless motor] FIG. 8 is a schematic cross-sectional view of the invention applied in inner stator/outer rotor brushless motor. As shown in FIG. 8, the inner stator/outer rotor brushless motor of the invention includes an inner stator 80 and an outer rotor (not shown in FIG. 8). The inner stator 80 includes an inner main body of the stator 82, a plurality of toothlets 84, a plurality of positioning pins 98 (refer to FIG. 8A), a plurality of bobbins 85, and a plurality of coils 87. FIG. 9A is a schematic cross-sectional view of the inner main body of the stator 82 of the inner stator/outer rotor motors of the invention, FIG. 9B is a sectional configuration diagram of a plurality of disassembled radial toothlets of the inner stator/outer rotor motors of the invention. As shown in FIG. 9A and FIG. 9B, a plurality of scoop channels 83 are evenly allocated on the internal side of the inner main body of the stator 82 according to the number of the teeth of the stator for housing a plurality of toothlets 84 with the same number. A plurality of toothlets 84 thereof is disassembled according to the exactly required number of toothlets. As shown in FIG. 9B, each of a plurality of toothlets 84 includes a addendum 91 and a rectangular dedendum 93. The toothlet 94 is constructed by punching and stacking up a plurality of permeable silicon steel sheets (refer to FIG. 8A). The top end 92 of the addendum 91 is a circular arc surface and a applicable air gap (not shown in FIG. 8A) is kept from its corresponding outer rotor (not shown in FIG. 8A). The dedendum 93 of each toothlet 84 matches the configuration and size of the scoop channel 83 so that the toothlet can be inserted and tightly fitted into the scoop channel 83. Each of two comers of the rectangular dedendum 93 has a chamfer 95 to facilitate the insertion of the toothlet into the main body of the stator 82. The assembling type inner stator/outer rotor motor is assembled by inserting the dedendum 93 of each disassembled radial toothlet 84 into each scoop channel 83 by use of single positioning pins. As shown in FIG. 9A, one intemal side of each scoop channel 83 has a semi-circular recess 86; correspondingly, one side of the dedendum 93 of each disassembled radial toothlet 84 also has a semi-circular recess 96. The position of the semi-circular recess 96 is such that it will correspond to the semi-circular recess 86 in one intemal side of the scoop channel 83 when the dedendum 93 of each toothlet 84 is inserted and tightly fitted into the scoop channel 83. As a result, an assembly hole 88 (refer to FIG. 8) is formed between one side of the scoop channel 83 and the corresponding side of the dedendum 93 of the toothlet 84. On the other hand, a plurality of bobbins 85 made of insulate material is used to be slipped on a plurality of toothlets 84 for winding. The assembly procedure of the invention applied in inner stator/outer rotor motors is similar to that of the outer stator/inner rotor motors shown in FIG. 7. FIG. 8A is a isometric assembly diagram of the invention applied in inner stator/outer rotor brushless motors. As shown in FIG. 8, the assembling procedure for the stator of the motor is described in the following four steps. Step 1: appropriately place the constructed main body of the stator 82 for the inner stator/outer rotor motors. Step 2: place a plurality of coils 87 that has completed winding on the bobbin 85 at an appropriate position inside the inner main body of the stator 82. Step 3: insert one single toothlet 84 after the other into the scoop channel 83 of the inner main body of the stator 82 inward into the center of the axis while knocking the positioning pin 98 (refer to FIG. 8A) into the matching assembly hole 88 one by one. Step 4: complete the assembly of the stator of inner stator/inner rotor motor as the last step. Because of assembling in radial direction, a chamfer 95 is made at each comer of each dedendum 93. Therefore, the assembly is easier and faster comparing with the assembly process of the prior art shown in FIG. 3-1, which requires the assembly be done in axial direction by use of dove-tail scoop channel. The assembly of the assembling type inner stator/outer rotor motor is accomplished with the following four connecting methods: single positioning pin, double positioning pin, single groove-and-tongue, and double groove-and-tongue. The connecting method for the stator structure by use of single positioning pin has been described in previous section. As for the connecting method for the stator structure by use of double positioning pins, refer to FIG. 8-1, FIG. 9A-1, and FIG. 9B-1 that are relative to FIG. 8, FIG. 9A, and FIG. 9B, respectively. As shown in FIG. 8-1, FIG. 9A-1, and FIG. 9B-1, each of the two internal sides of each scoop channel 83 on the inner main body of the stator 82 has a semi-circular recess 86 (refer to FIG. 9A-1); correspondingly, each of the two sides of the dedendum 93 of the disassembled radial toothlet 84 also has a semi-circular recess 96 (refer to FIG. 9B-1). The position of the two semi-circular recesses 96 are such that they will correspond to the two semi-circular recesses 86 on the two internal sides of the scoop channel 83 when the dedendum 93 of each toothlet 84 is inserted and tightly fitted into the scoop channel 83. As a result, two assembly holes 88 (refer to FIG. 8-1) are formed between each of two sides of the scoop channel 83 and their corresponding sides of the dedendum 93 of the toothlet 84. The assembly procedure is the same as that shown in FIG. 8A except that it requires two positioning pins for each toothlet 84. Refer to FIG. 8-2 and FIG. 9A-2 that are relative to FIG. 8 and FIG. 9A for the assembly by use of single groove-and-tongue. As shown in FIG. 8-2 and FIG. 9A-2, each internal side of each scoop channel 83 on the inner main body of the stator 82 (refer to FIG. 9A-2) has a semi-circular protuberance 92, correspondingly, each side of the dedendum 93 of each disassembled radial toothlet 84 (refer to FIG. 8-2) has a semi-circular recess 96. The positions of the semi-circular protuberance 92 and the semi-circular recess 96 are such that when the dedendum 93 of each toothlet 84 is inserted and tightly fitted into each scoop channel 83, the semi-circular recess 96 on the toothlet 84 and the semi-circular protuberance 92 inside the scoop channel 83 are engaged each other. The connecting method of the assembly is similar to that shown in FIG. 7-2, which is a isometric diagram for the assembly of outer stator/inner rotor motor assembled by use of single groove-and-tongue. FIG. 8B is a isometric diagram of the invention applied in inner stator/outer rotor brushless motors by use of single groove-and-tongue wherein the assembling procedure of the motor stator is described in the following four steps. Step 1: appropriately place a plurality of coils 87 that has completed winding on the bobbin 85. Step 2: insert one single toothlet 84 after the other into the bobbin 85 inward into the center of the axis. Step 3: Step 3: fit the coil 87 with inserted toothlets 84 into the scoop channel 83 inside the inner main body of the stator 82 of the inner stator 80 in axial direction, so that the semi-circular recess 96 on the toothlet 84 and the semicircular protuberance 92 inside the scoop channel 83 are engaged each other. Step 4: complete the assembly of the stator of the inner stator/outer rotor motor as the last step. This design is more applicable for the motors of lower stacking ratio of silicon steel sheets because when assembling the inner stator 80, each toothlet 84 must be inserted into the bobbin 85 that has completed winding and then be inserted into the inner main body of the stator 82 in axial direction together. Otherwise, wire connection can be complicated if the toothlet 84 is inserted into the inner main body of the stator 82 one by one. Refer to FIG. 8-3 and FIG. 9A-3 that are relative to FIG. 8-2 and 9A-2, respectively, for the connecting method of the stator stmcture by use of double groove-and-tongue. As shown in FIG. 8-3 and FIG. 9A-3, each of the two internal sides of each scoop channel 83 on the inner main body of the stator 82 (refer to FIG. 9A-3) has a semicircular protuberance 92; correspondingly, each of the two sides of each dedendum 93 of the disassembled radial toothlets 84 (refer to FIG. 8-3) has a semi-circular recess 96. The position of the protuberance 92 and the recess 96 are such that when the dedendum 93 of each toothlet 84 is inserted and tightly fitted into each scoop channel 83, the two semi-circular recesses 96 on the toothlet 84 and the two semi-circular protuberance 92 inside the scoop channel 83 are engaged each other. The assembling procedure for the assembly of the motor stator is the same as that of the assembly by use of single groove-and-tongue shown in FIG. 8B, and shall not be repeated here. In comparison with the connecting method by use of dove-tail scoop channel for assembly of the prior art shown in FIG. 3-1, the connecting methods of the invention, described in the previous sections, by use of single groove-and-tongue or double groove-and-tongue eliminate the fracture problem due the stress concentration because there is no comer of acute angle in the semi-circular recesses 96 on the toothlet 84 and the semi-circular protuberance 92 inside the scoop channel 83 when they are engaged each other. Similarly, the contact surface 841 of the rectangular toothlet root bottom of the inner stator's disassembled radial toothlets to the stator main body can be linear shape, V-shape, circular arc shape, or any other shape that does not prevent each toothlet from being pushed and tightly fitted into the main body of the stator in radial direction. In other words, the shape of the contact surface 841 can be changed according the requirement of the design. For example, a V-shape or circular-arc-shape recess or protuberance (or stick out) can be added to the rectangular dedendum of the inner stator's disassembled radial toothlet to increase the stability of fixation to the main body of the stator. The connecting method of its assembly is the same as the four connecting methods described in the previous section, which are: single positioning pin, double positioning pins, single groove-and-tongue, and double groove-and-tongue. FIG. 8AA is a modified diagram of FIG. 8 for single positioning pin connecting method showing that the change of shape, from linear shape to a circular-arc-shape recess, has been made to the bottom 841 of the rectangular dedendum of the radial toothlet. FIG. 9AA is a modified diagram of FIG. 9A for single positioning pin connecting method showing that the change of shape, from linear shape to a circular-arc-shape recess, has been made to the contact surface 831 of the main body of the stator to the bottom of the radial toothlet's rectangular dedendum. FIG. 9BA is a modified diagram of 9B for single positioning pin connecting method showing that the change of shape, from linear shape to a circular-arc-shape recess, has been made to the contact surface 941 of the bottom of the radial toothlet's rectangular dedendum to the main body of the stator. FIG. 8-1 A, FIG. 8-2A, and FIG. 8-3A are the assembly diagrams of the assembling type inner stator/outer rotor motor when a circular-arc-shape recess is added to the bottom 841 of the rectangular dedendum of the inner stator's radial toothlet. Basically, all of the assembly methods are completely the same as the assembly of the inner stator/outer rotor motor of the invention if the circular-arc-shape recess is not added to the rectangular dedendum of the inner stator's radial toothlet. FIG 9A-lA, FIG. 9A-2A, and FIG. 9A-3A are the diagrams that shows the contact surface 831 of the main body of the stator to the bottom of the radial toothlet's rectangular dedendum changing from linear shape to a circular-arc-shape recess. FIG. 9B-1A is the diagrams that shows the contact surface 941 of the bottom of the radial toothlet's rectangular dedendum to the main body of the stator changing from linear shape to a circular-arc-shape recess. FIG. 8BB is a modified diagram of FIG. 8 that shows the change of the bottom 541 of the rectangular dedendum of the radial toothlet from linear shape to a V-shape recess for single positioning pin connecting method. FIG. 9AB is a modified diagram of FIG. 9A that shows the change of the contact surface 831 of the main body of the stator to the bottom of the radial toothlet's rectangular dedendum from linear shape to a V-shape recess for single positioning pin connecting method. FIG. 9BB is a modified diagram of FIG. 9B that shows the changes of the contact surface 941 of the bottom of the radial toothlet's rectangular dedendum to the main body of the stator from linear shape to a V-shape recess for single positioning pin connecting method. FIG. 8-lB, FIG. 8-2B, and FIG. 8-3B are the assembly diagrams of the assembling type inner stator/outer rotor motor when a V-shape recess is added to the bottom 841 of the rectangular dedendum of the inner stator's radial toothlet. All of the assembly methods are completely the same as the assembly of the inner stator/outer rotor motor of the invention if the V-shape recess is not added to the rectangular dedendum of the stator's radial toothlet. FIG. 9A-1B, FIG. 9A-2B, and FIG. 9A-3B are the diagrams that shows the change of the contact surface 831 of the main body of the stator to the rectangular dedendum of the radial toothlet from linear shape to a V-shape recess. FIG. 9B-1B is the diagram that shows the change of the contact surface 941 of the rectangular dedendum of the radial toothlet to the main body of the stator from linear shape to a V-shape recess. As for the contact surfaces of the rectangular dedendum of the inner stator's toothlet and the main body of the stator, whether it is a V-shape or circular arc shape protuberance, or any other shaped protuberance that does not prevent each radial toothlet from being pushed and tightly fitted into the main body of the stator in radial direction, the principle is similar to the previously description of adding V-shape or circular-arc-shape recess, and shall not be repeated here. [Shunt Brush Motor] When the assembling type stator structure of the invention is applied in shunt motors, the assembling type stator structure includes an main body of the outer stator 101, or a plurality of disassembled small outer stators' main bodies 105. Each of the small main body of the outer stator has a plurality of scoop channels. The assembly of the main body of the outer stator can be done by use of one of the following four connecting methods: single positioning pin, double positioning pins, single groove-and-tongue, and double positioning groove-and-tongue. A plurality of disassembled radial toothlets 102, include a addendum and a dedendum, the disassembled radial toothlets are constructed by punching and stacking up a plurality of permeable silicon steel sheets. Each of the toothlets has configuration and size matching those of the scoop channels so that the toothlet can be inserted and tightly fitted into the scoop channel. Each of the two comers of the dedendum has a chamfer to facilitate insertion into the main body of the stator. The assembly of the assembling type stator can be done by connecting the disassembled radial toothlets to the main body of the stator with one of the following four methods: single positioning pin, double positioning pins, single groove-and-tongue, and double groove-and-tongue. Moreover, the assembling type stator of the shunt motor includes a plurality of positioning pins 102 for positioning and a plurality of bobbins 104 made of insulate material for fitting a plurality of toothlet for winding. The primary effectiveness of the assembling type stator structure for shunt motors is its low manufacturing cost when applied in single tooth winding because the operation mechanism required for the winding machine is simple and the production is very fast. There can be a large number of co-assembly sets because every small main body of the outer stator and the disassembled radial toothlet can be co-assembled to each other to construct an assembling type stator structure with one of the following connecting methods: single positioning pin, double positioning pins, single groove and tongue, and double groove-and-tongue. FIG. 14, FIG. 14-1, FIG. 14-2, FIG. 14-3, FIG. 14-4, and FIG. 14-5 are the cross-sectional views of various assembling methods of the assembling type stator structure applied in the outer stator of shunt bi-pole outer stator brush motors. FIG. 15, FIG. 15-1, FIG. 15-2, FIG. 15-3, FIG. 15-4, and FIG. 15-5 are the cross-sectional views of various assembling methods of the assembling type stator structure applied in quadri-pole outer stator shunt brush motor of the invention. Other assembling methods are possible and shall not be necessary to give all possible descriptions. While the invention has been described by way of example and in terms of the preferred embodiment, it is to be understood that the invention is not restrictioned to the disclosed embodiments. To the contrary, it is intended to cover various modifications and similar arrangements as would be apparent to those skilled in the art. Therefore, the scope of the appended claims should be accorded the broadest interpretation so as to encompass all such modifications and similar arrangements. WHAT IS CLAIMED IS: 1. An assembling type stator structure of motors comprising: a main body of the stator having a plurality of scoop channels and at least one side of each scoop channel has a semi-circular recess; a plurality of positioning pins for positioning; a plurality of disassembled radial toothlets having an addendum and a dedendum and the disassembled radial toothlets are constructed by punching and stacking up a plurality of permeable silicon steel sheets, the top end of the addendum is a circular arc surface and a applicable air gap is kept from its corresponding rotor, the dedendum of each toothlet matches the configuration and size of the scoop channel of the main body of the stator to be inserted and tightly fitted into the scoop channel, at least one side of the dedendum has a semi-circular recess and each of the two comers of the dedendum has a chamfer to facilitate insertion into the main body of the stator; the dedendum of each disassembled radial toothlet is inserted into each scoop channel to assemble the assembling type stator by use of single positioning pinsDand a plurality of bobbins made of insulate material for bushing a plurality of toothlets for winding. 2. An assembling type stator structure of motors as claimed in claim 1, wherein the stator structure is applicable to outer stator/inner rotor motors. 3. An assembling type stator structure of motors as claimed in claim 1, wherein the stator structure is applicable to inner stator/outer rotor motors. 4. An assembling type stator structure of motors as claimed in claim 1, wherein the stator structure is applicable to shunt motors. 5. An assembling type stator stmcture of motors as claimed in claim 1, in which the dedendum of each disassembled radial toothlet is inserted into each scoop channel to assemble the assembling type stator by use of double positioning pins instead of single positioning pins. 6. An assembling type stator stmcture of motors as claimed in claim 1, in which the dedendum of each disassembled radial toothlet is inserted into each scoop channel to assemble the assembling type stator of the motor by use of single semi-circular groove-and-tpngue instead of the single positioning pins. 7. An assembling type stator stmcture of motors as claimed in claim 1, in which the dedendum of each disassembled radial toothlet is inserted into each scoop channel to assemble the assembling type stator by use of double semi-circular groove-and-tongue instead of the single positioning pin connecting method. 8. An assembling type stator stmcture of motors as claimed in claim 1, wherein the contact surface of the dedendum of the disassembled +radial toothlet of the stator to the main body of the stator can be a linear shape, a V-shape, a circular arc shape, or any other shape that does not prevent each toothlet from being inserted and tightly fitted into the main body of the stator. 9. A stator stmcture of shunt motor comprising: a plurality of disassembled small main body of the outer stator, each of them having a plurality of scoop channels that can be assembled by one of the following connecting methods: single positioning pin, double positioning pins, single groove-and-tongue, and double groove-and-tongue; a plurality of disassembled radial toothlets having a addendum and a dedendum made by punching and stacking up a plurality of permeable silicon steel sheets wherein the end surface of the addendum is a circular arc surface and a applicable air gap is kept from its corresponding rotor, the dedendum of each toothlet matches the configuration and size of the scoop channel of the main body of the stator to be inserted and tightly fitted into the scoop channel, and there is a chamfer at each of the two comers of the dedendum to facilitate the insertion to the main body of the stator, moreover, at least one side of the dedendum has a semi-circular recess, what is more, the dedendum of each disassembled radial toothlet is inserted into each scoop channel and connected to the main body of the stator to assemble the assembling type stator by use of either single positioning pin, double positioning pins, single groove-and-tongue, or double groove-and-tongue connecting methods; a plurality of positioning pins for positioning; and a plurality of bobbins made of insulated material for slipping on a plurality of toothlets for winding. 10. An assembling type stator structure of motors substantially as herein described with reference to the accompanying drawings and examples.

Full Text

ASSEMBLING TYPE STATOR STRUCTURE OF MOTOR Field of the Invention
The invention relates to an assembling type stator structure of motors, and more particularly, to an assembling type stator structure that provides the flexibility of being able to be assembled or disassembled in either axial or radial direction.
Background of the Invention
FIG. 1 is a schematic cross-sectional view of a stator structure of outer stator/inner rotor brushless motors of the prior art. The stator structure includes an outer stator 10, an inner rotor (not show), an main body of the outer stator 12, a tooth part 14, a plurality of bobbins 15, and a plurality of coils 17. FIG. 2 is a schematic cross-sectional view of another stator structure of the inner stator/outer rotor brushless motors of the prior art. The stator structure includes an inner stator 20, an outer rotor (not shown), an inner main body of the stator 22, a tooth part 24, a plurality of bobbins 25, and a plurality of coils 27. As shown in FIG. 1 and FIG. 2, wire winding, whether it is stacked winding or single tooth winding, of the stators 10 and 20 of the prior art of brushless motors has the disadvantage of being unable to effectively increase the occupying rate of winding. This is due to the restriction of the geometric shape of the stator. Especially, the custom-made winding machine for the stator 10 of an outer stator/inner rotor brushless motors of the prior art shown in FIG. 1 is very expensive because of its complicated actions of its mechanism.

Hence, as shown in FIG. 3 and FIG. 4, there are improved outer stator/inner rotor and inner stator/outer rotor brushless motors provided of the prior art. FIG. 3 is a cross-sectional schematic view of the stator structure of outer stator/inner rotor brushless motors of the prior art. As shown in FIG. 3, the stator structure of outer stator/inner rotor brushless motors of the prior art includes an outer stator 30, a main body 32, a plurality of tooth parts 34, a plurality of dove-tail scoop channels 36, a plurality of bobbins 35, and a plurality of coils 37. FIG. 4 is a schematic cross-sectional view of the stator structure of the inner stator/outer rotor brushless motor of the prior art. As shown in FIG. 4, the stator structure of the inner stator/outer rotor brushless motor of the prior art includes an inner stator 40, an inner main body of the stator 42, a plurality of toothlets 44, a plurality of dove-tail scoop channel 46, a plurality of bobbins 45 and a plurality of coils 47. The assembly procedure of the brushless motors shown in FIG. 3 and FIG. 4 is done by disassembling the stator into the main body of the stator and a plurality of toothlets, then completing the winding on the bobbin and placing the toothlets therein first. Afterward, the toothlets and the main body of the stator are assembled by use of dove-tail scoop channel. FIG. 3-1 is a schematic view showing the assembling steps of the improved outer stator/inner rotor brushless motor of the prior art. Although the improved brushless motors shown in FIG. 3 and FIG. 4 have the advantages of reducing the winding cost, increasing the occupation rate of winding, and increasing the efficiency of the motor, the assembling work by use of dove-tail scoop channel for these improved brushless motors must be

done and only be done in axial direction as shown in FIG. 3-1. Nevertheless, assembling in axial direction still has some degree of difficulty. Moreover, the assembling method by use of dove-tail scoop channel can cause serious stress concentration due to sharp angle at the comer of the dove-tail scoop channel which will make the dovetail scoop channel be subject to generate fracture.
The assembling type of the outer stator motor of the prior art of US Patent 6,265,804 as shown in FIG. 11 has the disadvantage of being unable to increase the occupation rate of winding with single tooth winding although it has achieved the purpose of saving material.
The assembling type outer stator motor of the prior art of US Patent 5,786,651 can achieve the purpose of saving material, increase the occupation rate of winding with single tooth winding, and eliminate the requirement of being assembled in axial direction. Nevertheless, it lacks of self-lock function, has to be fixed by the housing of the motor, has indirect heat dissipation only, and requires the outer stator components be winded together on the winding machine.
FIG. 13 is a schematic cross-sectional view of a shunt outer stator brush motor of the prior art. The custom-made winding machine for single tooth winding is very expensive due to the requirement of complicated actions of mechanical operation.
The foregoing statements are the disadvantages of the outer stator/inner rotor bmshless motor of the prior art.
SUMMARY OF THE INVENTION

In light of the disadvantages of the prior art, the invention provides an assembling type stator structure of motors that can increase the occupation rate of winding and reduce the winding cost by providing more convenient and flexible assembly methods in either axial direction or radial direction by use of positioning pins in comparison with the assembly of the prior art by use of dove-tail scoop channel which can only assemble in axial direction. In addition, all of the assembling methods provided by the invention have no comer in acute angle; therefore, there is no fracture problem due to stress concentration.
Therefore, the object of the invention is to provide an assembling type stator structure of motors that is assembled by inserting and fitting a plurality of disassembled radial toothlets into a plurality of scoop channels of the main body of the stator.
Another object of the invention is to provide an assembling type stator structure of motors that is assembled by connecting a plurality of disassembled radial toothlets to the main body of the stator by use of single positioning pin or double positioning pins.
Another object of the invention is to provide an assembling type stator structure of motors that is assembled by connecting a plurality of disassembled radial toothlets to the main body of the stator by use of single groove-and-tongue or double groove-and-tongue.
Another object of the invention is to provide an assembling type outer stator structure for shunt motors that is assembled by connecting

the disassembled main body of the outer stator and the disassembled toothlets together by use of either single positioning pin, or double positioning pins, or single groove-and-tongue, or double groove-and-tongue.
In order to accomplish the above-mentioned objects, the invention provides an assembling type stator structure of motors that includes a plurality of scoop channels and a plurality of disassembled radial toothlets. The disassembled radial toothlets are constructed by punching and stacking up a plurality of permeable silicon steel sheets. Each of the toothlets has configuration and size matching those of the scoop channels so that the toothlet can be inserted and tightly fitted into the scoop channel. Then, the assembling type stator can be assembled with one of the following four methods: single positioning pin, double positioning pin, single groove-and-tongue, and double groove-and-tongue.
In order to understand fully the objectives, characteristics, and the efficacy of the invention in the preferred embodiment, a detailed illustration with accompanied drawing is described as follows:
BRIEF DESCRIPTION OF THE DRAWING
FIG. 1 is a schematic cross-sectional view of the stator structure of
outer stator/inner rotor brushless motors of the prior art. FIG. 2 is a schematic cross-sectional view of the stator structure of the
inner stator/outer rotor brushless motors of the prior art. FIG. 3 is a schematic cross-sectional view of the stator structure of

outer stator/inner rotor brushless motors of the prior art that is
connected by use of dove-tail scoop channel. FIG. 3-1 is a schematic isometric view showing the assembling steps
for the improved outer stator/inner rotor brushless motors of the
prior art that is connected by use of dove-tail scoop channel. FIG. 4 is a schematic cross-sectional view of the stator structure of the
inner stator/outer rotor brushless motors of the prior art that is
connected by use of dove-tail scoop channel. FIG. 5 is a schematic cross-sectional view of outer stator/inner rotor
brushless motors of the invention that is assembled by use of
single positioning pins. FIG. 5 A is a schematic cross-sectional view of outer stator/inner rotor
brushless motors of the invention that is assembled by use of
single positioning pins wherein the configuration of the
rectangular dedendum of the disassembled radial toothlet is
changed from linear shape to a circular arc recess. FIG. 5B is a schematic cross-sectional view of outer stator/inner rotor
brushless motors of the invention that is assembled by use of
single positioning pins wherein the shape of the rectangular
dedendum of the disassembled radial toothlet is changed from
linear shape to a V-shape notch. FIG. 5-1 is a schematic cross-sectional view of outer stator/inner rotor
brushless motors of the invention that is assembled by use of
double positioning pins. FIG. 5-1A is a schematic cross-sectional view of outer stator/inner
rotor brushless motors of the invention that is assembled by use

of double positioning pins wherein the shape of the inner stator/outer rotor brushless motor of the rectangular dedendum of the radial toothlet is changed from linear shape to a circular-arc-shape recess. FIG. 5-IB is a schematic cross-sectional view of outer stator/inner rotor bmshless motors of the invention that is assembled by use of double positioning pins wherein the shape of the inner stator/outer rotor bmshless motor of the rectangular dedendum of the radial toothlet is changed from linear shape to a V-shape recess.
FIG. 5-2 is a schematic cross-sectional view of outer stator/inner rotor brushless motors of the invention that is assembled by use of single groove-and-tongue.
FIG. 5-2A is a schematic cross-sectional view of outer stator/inner rotor bmshless motors of the invention that is assembled by use of single groove-and-tongue wherein the shape of the rectangular dedendum of the radial toothlet is changed from linear shape to a circular-arc-shape recess.
FIG. 5-2B is a schematic cross-sectional view of outer stator/inner rotor bmshless motors of the invention that is assembled by use of single groove-and-tongue wherein the shape of the rectangular dedendum of the radial toothlet is changed from linear shape to a V-shape recess.
FIG. 5-3 is a schematic cross-sectional view of outer stator/inner rotor bmshless motors of the invention that is assembled by use of

double groove-and-tongue.
FIG. 5-3A is a schematic cross-sectional view of outer stator/inner rotor brushless motors of the invention that is assembled by use of double groove-and-tongue wherein the shape of the rectangular dedendum of the radial toothlet is changed from linear shape to a circular-arc-shape recess.
FIG. 5-3B is a schematic cross-sectional view of outer stator/inner rotor brushless motors of the invention that is assembled by use of double groove-and-tongue wherein the shape of the rectangular dedendum of the radial toothlet is changed from linear shape to a V-shape recess.
FIG. 6A is a schematic cross-sectional view of the main body of the stator 52 of the outer stator/inner rotor brushless motors of the invention that is assembled by use of single positioning pins.
FIG. 6AA is a schematic cross-sectional view of the main body of the stator 52 of the outer stator/inner rotor brushless motors of the invention that is assembled by use of single positioning pins wherein the contact surface to the dedendum of the radial toothlet is changed from linear shape to a circular-arc-shape recess.
FIG. 6AB is a schematic cross-sectional view of outer stator/inner rotor brushless motors of the invention that is assembled by use of single positioning pins wherein the contact surface to the rectangular dedendum of the radial toothlet is changed from linear shape to a V-shape recess.
FIG. 6A-1 is a schematic cross-sectional view of the main body 52 of

the outer stator/inner rotor brushless motors of the invention that is assembled by use of double positioning pins.
FIG. 6A-1A is a schematic cross-sectional view of the main body 52 of the outer stator/inner rotor brushless motors of the invention that is assembled by use of double positioning pins wherein the contact surface to the rectangular dedendum of the radial toothlet is changed from linear shape to a circular-arc-shape recess.
FIG. 6A-1B is a schematic cross-sectional view of the main body 52 of the outer stator/inner rotor brushless motors of the invention that is assembled by use of double positioning pins wherein the contact surface to the rectangular dedendum of the radial toothlet is changed from linear shape to a V-shape recess.
FIG. 6A-2 is a schematic cross-sectional view of the main body 52 of the outer stator/inner rotor brushless motors of the invention that is assembled by use of single groove-and-tongue.
FIG, 6A-2A is a schematic cross-sectional view of the main body 52 of the outer stator/inner rotor brushless motors of the invention that is assembled by use of single groove-and-tongue wherein the contact surface to the rectangular dedendum of the radial toothlet is changed from linear shape to a circular-arc-shape recess.
FIG. 6A-2B is a schematic cross-sectional view of the main body 52 of the outer stator/inner rotor brushless motors of the invention that is assembled by use of single groove-and-tongue wherein the contact surface to the rectangular dedendum of the radial

toothlet is changed from linear shape to a V-shape recess.
FIG. 6A-3 is a schematic cross-sectional view of the main body 52 of the outer stator/inner rotor brushless motors of the invention that is assembled by use of double groove-and-tongue.
FIG. 6A-3 A is a schematic cross-sectional view of the main body 52 of the outer stator/inner rotor brushless motors of the invention that is assembled by use of double groove-and-tongue wherein the contact surface to the rectangular dedendum of the radial toothlet is changed from linear shape to a circular-arc-shape recess.
FIG. 6A-3B is a schematic cross-sectional view of the main body 52 of the outer stator/inner rotor brushless motors of the invention that is assembled by use of double groove-and-tongue wherein the contact surface to the rectangular dedendum of the radial toothlet is changed from linear shape to a V-shape recess.
FIG. 6B is a schematic cross-sectional view of a layout of a plurality of disassembled radial toothlets 54 of the invention applied in outer stator/inner rotor brushless motors assembled by use of single positioning pins.
FIG. 6BA is a schematic cross-sectional view of the rectangular dedendum of a plurality of disassembled radial toothlets 54 of the invention applied in outer stator/inner rotor brushless motors assembled by use of single positioning pins wherein the contact surface to the main body of the stator is changed from linear shape to a circular-arc-shape recess.
FIG. 6BB is a schematic cross-sectional view of the rectangular

dedendum of a plurality of disassembled radial toothlets 54 of the invention applied in outer stator/inner rotor brushless motors assembled by use of single positioning pins wherein the contact surface to the main body of the stator is changed from linear shape to a V-shape recess.
FIG. 6B-1 is a schematic cross-sectional view of a layout of a plurahty of disassembled radial toothlets 54 of the invention applied in outer stator/inner rotor brushless motors assembled by use of double positioning pins.
FIG. 6B-1A is a schematic cross-sectional view of the rectangular dedendum of a plurality of disassembled radial toothlets 54 of the invention applied in outer stator/inner rotor brushless motors assembled by use of double positioning pins wherein the contact surface to the main body of the stator is changed from linear shape to a circular-arc-shape recess.
FIG. 6B-1B is a schematic cross-sectional view of a plurality of disassembled radial toothlet 54 of the invention applied in outer stator/inner rotor brushless motors assembled by use of double positioning pins wherein the contact surface to the main body of the stator is changed from linear shape to a V-shape recess.
FIG. 7 is an schematic isometric view of the invention showing the assembling steps for the outer stator/inner rotor brushless motors by use of single positioning pins.
FIG. 7-2 is an schematic isometric view of the invention showing the assembling steps for the outer stator/inner rotor brushless motors by use of single groove-and-tongue.

FIG. 8 is a schematic cross-sectional view of the inner stator/outer rotor brushless motors of the invention assembled by use of single positioning pins.
FIG. 8 AA is a schematic cross-sectional view of the inner stator/outer rotor brushless motors of the invention assembled by use of single positioning pins wherein the shape of the inner stator/outer rotor brushless motor of the rectangular dedendum of the disassembled radial toothlet is changed from linear shape to a circular-arc-shape recess.
FIG. 8BB is a schematic cross-sectional view of the inner stator/outer rotor brushless motors of the invention assembled by use of single positioning pins wherein the shape of the rectangular dedendum of the disassembled radial toothlet is changed from linear shape to a V-shape recess.
FIG. 8-1 is a schematic cross-sectional view of the inner stator/outer rotor brushless motors of the invention assembled by use of double positioning pins.
FIG. 8-1A is a schematic cross-sectional view of the inner stator/outer rotor brushless motors of the invention assembled by use of double positioning pins wherein the shape of the inner stator/outer rotor brushless motor of the rectangular dedendum of the radial toothlet is changed from linear shape to a circular-arc-shape recess.
FIG. 8-IB is a schematic cross-sectional view of the inner stator/outer rotor brushless motors of the invention assembled by use of double positioning pins wherein the shape of the inner

stator/outer rotor brushless motor of the rectangular dedendum of the radial toothlet is changed from linear shape to a V-shape recess.
FIG, 8-2 is a schematic cross-sectional view of the inner stator/outer rotor brushless motors of the invention assembled by use of single groove-and-tongue.
FIG. 8-2A is a schematic cross-sectional view of the inner stator/outer rotor brushless motors of the invention assembled by use of single groove-and-tongue wherein the shape of the inner stator/outer rotor bmshless motor of the rectangular dedendum of the radial toothlet is changed from linear shape to a circular-arc-shape recess.
FIG. 8-2B is a schematic cross-sectional view of the irmer stator/outer rotor brushless motors of the invention assembled by use of single groove-and-tongue wherein the shape of the inner stator/outer rotor bmshless motor of the rectangular dedendum of the radial toothlet is changed from linear shape to a V-shape recess.
FIG. 8-3 is a schematic cross-sectional view of the inner stator/outer rotor brushless motors of the invention assembled by use of double groove-and-tongue.
FIG. 8-3 A is a schematic cross-sectional view of the inner stator/outer rotor brushless motors of the invention assembled by use of double groove-and-tongue wherein the shape of the inner stator/outer rotor brushless motor of the rectangular dedendum of the radial toothlet is changed from linear shape to a circular-

arc-shape recess.
FIG. 8-3B is a schematic cross-sectional view of the inner stator/outer rotor brushless motors of the invention assembled by use of double groove-and-tongue wherein the shape of the inner stator/outer rotor brushless motor of the rectangular dedendum of the radial toothlet is changed from linear shape to a V-shape recess.
FIG. 8A is a schematic isometric view showing the assembling steps of the inner stator/outer rotor brushless motors of the invention assembled by use of single positioning pins.
FIG, 8B is a schematic isometric view showing the assembling steps of the inner stator/outer rotor brushless motors assembled by use of single groove-and-tongue.
FIG. 9A is a schematic cross-sectional view of the main body 82 of the inner stator/outer rotor brushless motors of the invention assembled by use of single positioning pins.
FIG. 9AA is a schematic cross-sectional view of the main body 82 of the inner stator/outer rotor brushless motors of the invention assembled by use of single positioning pins wherein the contact surface to the rectangular dedendum of the radial toothlet is changed from linear shape to a circular-arc-shape recess.
FIG. 9AB is a schematic cross-sectional view of the main body 82 of the inner stator of the inner stator/outer rotor brushless motors of the invention assembled by use of single positioning pins wherein the shape of the rectangular dedendum of the disassembled radial toothlet is changed from linear shape to a

V-shape recess.
FIG. 9A-1 is a schematic cross-sectional view of the inner main body of the stator 82 of the invention applied in inner stator/outer rotor brushless motors assembled by use of double positioning pins.
FIG. 9A-1A is a schematic cross-sectional view of the main body 82 of the inner stator of the inner stator/outer rotor brushless motors of the invention assembled by use of single positioning pins wherein the shape of the rectangular dedendum of the disassembled radial toothlet is changed from linear shape to a circular-arc-shape recess.
FIG. 9A-1B is a schematic cross-sectional view of the main body 82 of the inner stator of the inner stator/outer rotor brushless motors of the invention assembled by use of single positioning pins wherein the shape of the rectangular dedendum of the disassembled radial toothlet is changed from linear shape to a V-shape recess.
FIG. 9A-2 is a schematic cross-sectional view of the main body 82 of the inner stator/outer rotor brushless motors of the invention assembled by use of single groove-and-tongue.
FIG. 9A-2A is a schematic cross-sectional view of the main body 82 of the inner stator/outer rotor brushless motors of the invention assembled by use of single groove-and-tongue wherein the contact surface to the rectangular dedendum of the radial toothlet is changed from linear shape to a circular-arc-shape recess.

FIG, 9A-2B is a schematic cross-sectional view of the main body 82 of the inner stator/outer rotor brushless motors of the invention assembled by use of single groove-and-tongue wherein the contact surface to the rectangular dedendum of the radial toothlet is changed from linear shape to a V-shape recess.
FIG. 9A-3 is a schematic cross-sectional view of the main body 82 of the inner stator/outer rotor brushless motors of the invention assembled by use of double groove-and-tongue,
FIG. 9A-3 A is a schematic cross-sectional view of the main body 82 of the inner stator/outer rotor brushless motors of the invention assembled by use of double groove-and-tongue wherein the contact surface to the rectangular dedendum of the radial toothlet is changed from linear shape to a circular-arc-shape recess.
FIG. 9A-3B is a schematic cross-sectional view of the main body 82 of the inner stator/outer rotor brushless motors of the invention assembled by use of double groove-and-tongue wherein the contact surface to the rectangular dedendum of the radial toothlet is changed from linear shape to a V-shape recess,
FIG. 9B is a schematic cross-sectional view of the main body 84 of the inner stator/outer rotor brushless motors of the invention assembled by use of single positioning pins.
FIG. 9B A is a schematic cross-sectional view of the main body 84 of the inner stator/outer rotor brushless motors of the invention assembled by use of single positioning pins wherein the contact surface to the rectangular dedendum of the radial toothlet is

changed from linear shape to a circular-arc-shape recess.
FIG. 9BB is a schematic cross-sectional view of the main body 84 of the inner stator of the inner stator/outer rotor brushless motors of the invention assembled by use of single positioning pins wherein the shape of the rectangular dedendum of ■ the disassembled radial toothlet is changed from linear shape to a V-shape recess.
FIG. 9B-1 is a schematic cross-sectional view of the main body 84 of the inner stator/outer rotor brushless motors of the invention assembled by use of double positioning pins.
FIG. 9B-1A is a schematic cross-sectional view of the main body 84 of the inner stator of the inner stator/outer rotor brushless motors of the invention assembled by use of single positioning pins wherein the shape of the rectangular dedendum of the disassembled radial toothlet is changed from linear shape to a circular-arc-shape recess,
FIG. 9B-1B is a schematic cross-sectional view of the main body 84 of the inner stator of the inner stator/outer rotor brushless motors of the invention assembled by use of single positioning pins wherein the shape of the rectangular dedendum of the disassembled radial toothlet is changed from linear shape to a V-shape recess.
FIG. 10 is a schematic punching diagram of the main body 52 of the outer stator of the invention shown in FIG. 6A and FIG. 6A-2.
FIG. 11 is a schematic cross-sectional view of the structure of the assembling type outer stator motor of the prior art of US Patent

6,265,804.
FIG. 12 is a schematic cross-sectional view of the structure of the assembling type outer stator motor of the prior art of US Patent 5,786,651.
FIG. 13 is a schematic cross-sectional view of the outer stator for outer stator brush shunt motor of the prior art.
FIG. 14 is a schematic cross-sectional view of the assembling type dipole outer stator shunt brush motor of the invention, in which the main body of the stator is not disassembled, and the dedendum of the radial toothlet is connected to the main body of the stator by use of double positioning pins.
FIG. 14-1 is a schematic cross-sectional view of the assembling type dipole outer stator shunt brush motor of the invention, in which the main body of the outer stator is assembled by use of single positioning pin, and the dedendum of the radial toothlet is connected to the main body of the stator by use of double positioning pins.
FIG. 14-2 is a schematic cross-sectional view of the assembling type dipole outer stator shunt brush motor of the invention, in which the main body of the outer stator is assembled by use of single semi-circular groove-and-tongue, and the dedendum of the radial toothlet is connected to the main body of the stator by use of double positioning pins.
FIG. 14-3 is a schematic cross-sectional view of the assembling type dipole outer stator shunt brush motor of the invention, in which the main body of the stator is not disassembled, and the

dedendum of the radial toothlet is connected to the main body of the stator by use of double semi-circular groove-and-tongue.
FIG. 14-4 is a schematic cross-sectional view of the assembling type dipole outer stator shunt brush motor of the invention, in which the main body of the outer stator is assembled by use of single positioning pin, and the dedendum of the radial toothlet is connected to the main body of the stator by use of double semicircular groove-and-tongue.
FIG. 14-5 is a schematic cross-sectional view of the assembling type dipole outer stator shunt brush motor of the invention, in which the main body of the outer stator is assembled by use of single semi-circular groove-and-tongue, and the dedendum of the radial toothlet is connected to the main body of the stator by use of double semi-circular groove-and-tongue.
FIG. 15 is a schematic cross-sectional view of the assembling type quadri-pole outer stator shunt brush motor of the invention, in which the main body of the stator is not disassembled, and the dedendum of the radial toothlet is connected to the main body
of the stator by use of double positioning pins
FIG. 15-1 is a schematic cross-sectional view of the assembling type quadri-pole outer stator shunt brush motor of the invention, in which the main body of the outer stator is assembled by use of single positioning pin, and the dedendum of the radial toothlet is connected to the main body of the stator by use of double positioning pins.
FIG. 15-2 is a schematic cross-sectional view of the assembling type

quadri-pole outer stator shunt brush motor of the invention, in which the main body of the outer stator is assembled by use of single semi-circular groove-and-tongue, and the dedendum of the radial toothlet is connected to the main body of the stator by use of double positioning pins.
FIG. 15-3 is a schematic cross-sectional view of the assembling type quadri-pole outer stator shunt brush motor of the invention, in which the main body of the stator is not disassembled, and the dedendum of the radial toothlet is connected to the main body of the stator by use of double semi-circular groove-and-tongue.
FIG, 15-4 is a schematic cross-sectional view of the assembling type quadri-pole outer stator shunt brush motor of the invention, in which the main body of the outer stator is assembled by use of single positioning pin, and the dedendum of the radial toothlet is connected to the main body of the stator by use of double semi-circular groove-and-tongue.
FIG. 15-5 is a schematic cross-sectional view of the assembling type quadri-pole outer stator shunt brush motor of the invention, in which the main body of the outer stator is assembled by use of single semi-circular groove-and-tongue, and the dedendum of the radial toothlet is connected to the main body of the stator by use of double semi-circular groove-and-tongue.
DETAILED DESCRIPTION OF THE EMBODIMENTS
[Outer stator/inner rotor brushless motor]

FIG. 5 is a schematic cross-sectional view of the invention appUed in outer stator/inner rotor brushless motors by use of single positioning pins. As shown in FIG. 5, the outer stator/inner rotor brushless motor of the invention includes an outer stator 50 and an inner rotor (not shown in FIG. 5). The outer stator 50 includes a main body of the outer stator 52, a plurality of toothlets 54, a plurality of positioning pins 72 (refer to FIG. 7), a plurality of bobbins 55, and a plurality of coils 57, FIG. 6A is a schematic cross-sectional view of the main body of the outer stator 52 of the invention applied in outer stator/inner rotor brushless motors. FIG. 6B is a sectional configuration view of a plurality of the disassembled radial toothlets applied in outer stator/inner rotor brushless motors. As shown in FIG. 6A and FIG. 6B, a number of a plurality of scoop channels 53 is evenly allocated on the intemal side of the main body of the outer stator 52 according the number of the toothlets of the stator for housing a plurality of toothlets 54 with the same number. A plurality of toothlets 54 thereof is disassembled according to the actually required number of the toothlets of the motor's outer stator 12 of the prior art shown in FIG. 1. As shown in FIG. 6B, each of a plurality of toothlets 54 includes a addendum 61 and a rectangular dedendum 63. The toothlet is constructed by punching and stacking up a plurality of permeable silicon steel sheets (refer to FIG. 7). The end surface 64 of the addendum 61 is a circular arc surface, and an applicable air gap (not shown in FIG. 7) is kept from its corresponding rotor (not shown in FIG. 7). The dedendum 63 of each toothlet 54 has the configuration and size matching those of the scoop channel 53 so that the toothlet

can be inserted and tightly fitted into the scoop channel 53. Each of
two comers of the rectangular dedendum 63 has a chamfer (□□) 65 to
facilitate the insertion of the toothlet into the main body of the stator 52.
The dedendum 63 of each disassembled radial toothlet 54 is inserted to the scoop channel 53 and both are connected together by use of a single positioning pin to construct the assembling type outer stator/inner rotor motor. As shown in FIG. 6A, one intemal side of each scoop channel 53 has a semi-circular recess 56; correspondingly, one side of the dedendum 63 of each disassembled radial toothlet 54 also has a corresponding semi-circular recess 66. The position of the semi-circular recess 66 is such that it will correspond to the semicircular recess 56 on the intemal side of the scoop channel 53 when the dedendum 63 of each toothlet 54 is inserted and tightly fitted into the scoop channel 53; as a result, an assembly hole 58 is formed between one side of the scoop channel 53 and the corresponding side of the dedendum 63 of the toothlet 54. On the other hand, a plurality of bobbins 55 made of insulate material is used to be slipped on a plurality of toothlets 54 for winding,
FIG. 7 is a isometric diagram for the assembly procedure of the outer stator/inner rotor brushless motors. As shown in FIG. 7, the stator of the motor is assembled in the following four steps. Step 1: appropriately place the constructed main body of the stator 52 of the outer stator/inner rotor motor; Step 2: place a plurality of coils 57 that has completed winding on the bobbin 55 at an appropriate position inside the main body of the outer stator 52; Step 3: insert one single

toothlet 54 after the other into the scoop channel 53 of the main body of the outer stator 52 in radial direction starting from the center of the axis outward as the pointed direction of arrow head 71; thereafter, knock the positioning pin 72 into the corresponding circular assembly hole 58 one by one in the direction pointed by arrow head 73; Step 4: lastly, complete the assembly of the stator of outer stator/inner rotor motor. Since the assembling is in radial direction, and there is a chamfer 65 is at each comer of each dedendum 63, the assembly procedure is easier and faster as comparing with the assembly procedure of the prior art shown in FIG. 3-lthat strictly requires the assembling be done in axial direction by use of dove-tail scoop channel. Moreover, the invention increases the occupation rate of winding in single toothlet winding, and one needs only to place the bobbin on the winding machine to wind simultaneously. A more important feature is that when it comes to assembling, every toothlet can be easily assembled one by one in radial direction starting from the center of the axis, then fixed with positioning pin, and because of the self-locking capability, no extra component is required for fixation.
The assembly of the assembling type outer stator/inner rotor motors is accomplished with the following four connecting methods: single positioning pin, double positioning pin, single groove-and-tongue, and double groove-and-tongue.
The connecting method for the stator structure by use of single positioning pin has been described previously As for the connecting method with double positioning pins for the stator structure, it can be

referred to FIG. 5-1, FIG. 6A-1, and FIG. 6B-1 which are corresponding to FIG. 5, FIG. 6A, and FIG. 6B respectively. As shown in FIG. 5-1, FIG. 6A-1, and FIG. 6B-1, each of the two internal sides of scoop channel 53 on the main body of the outer stator 52 has a semi-circular recess 56 (refer to FIG. 6A-1); correspondingly, each of the two sides of the dedendum 63 of each disassembled radial toothlet 54 also has a semi-circular recess 66 (refer to FIG. 6B-1). The position of the two semi-circular recesses 66 are such that they will correspond to two semi-circular recesses 56 on the two internal sides of the scoop channel 53 when the dedendum 63 of each toothlet 54 is inserted and tightly fitted into the scoop channel 53. As a result, two assembly holes 58 (refer to FIG. 5-1) are formed between the two sides of the scoop channel 53 and their corresponding sides of the dedendum 63 of the toothlet 54. The assembly procedure is the same as the one shown in FIG. 7 except that it requires two positioning pins for the toothlet 54. The rest of the assembly procedure are the same as the single positioning pin method and shall not be repeated here.
Corresponding to FIG. 5, FIG. 6A, and FIG. 7 respectively, FIG. 5-2, FIG. 6A-2, and FIG. 7-2 show the connecting method of the stator structure by use of single groove-and-tongue. As shown in. FIG.5-2 and FIG.6A-2, one internal side of each scoop channel 53 on the main body of the outer stator 52 (refer to FIG. 6A-2) has a semicircular protuberance 62; correspondingly, one side of each dedendum 63 of the disassembled radial toothlet 54 (refer to FIG. 5-2) has a

semi-circular recess 66. The position of the protuberance and the concave are such that when the dedendum 63 of each toothlet 54 is inserted and tightly fitted into each scoop channel 53, the semicircular recess 66 on the toothlet 54 and the semi-circular protuberance 62 inside the scoop channel 53 are engaged each other. FIG. 7-2 is a isometric view of the invention applied in outer stator/inner rotor brushless motors that is assembled by use of single groove-and-tongue wherein the assembling procedure is described below with reference to FIG. 7-2. Step 1: appropriately place a plurality of coils 57 that has completed winding on the bobbin 55. Step 2: insert one single toothlet 54 after the other into the bobbin 55 in radial direction starting from the center of the axis outward in the direction pointed by arrow head 71. Step 3: fit the coil 57 with inserted toothlets 54 into the scoop channel 53 inside the main body of the outer stator 52 of the outer stator 50 in axial direction in the direction indicated by arrow head 77, so that the semi-circular recess 66 on the toothlet 54 and the semi-circular protuberance 62 inside the scoop channel 53 are engaged each other. Step 4: complete the assembly of the stator of outer stator/inner rotor motor as the last step. This design is more applicable for motors of lower stacking ratio of silicon steel sheets because as when it comes to assembling the outer stator 50, each toothlet 54 must be inserted into the bobbin 55 that has completed winding and then be inserted into the main body of the outer stator 52 in axial direction together. Otherwise, wire connection can be complicated if the toothlet 54 is inserted into the main body of the outer stator 52 one by one.

Corresponding to FIG. 5-2 and 6A-2, respectively are FIG. 5-3 and FIG. 6A-3 that show the connecting method of the stator structure by use of double groove-and-tongue. As shown in FIG. 5-3 and FIG. 6A-3, each of the two intemal sides of each scoop channel 53 on the main body of the outer stator 52 (refer to FIG. 6A-3) has a semicircular protuberance 62; correspondingly, each of the two sides of the dedendum 63 of each disassembled radial toothlets 54 (refer to FIG. 5-3) has a semi-circular recess 66. The position of the protuberance 62 and the recess 66 are such that when the dedendum 63 of each toothlet 54 is inserted and tightly fitted into each scoop channel 53, the two semi-circular recesses 66 on the toothlet 54 and the two semi-circular protuberances 62 inside the scoop channel 53 are engaged each other. The assembling procedure for the assembly of the motor stator is the same as that shown in FIG. 7-2, thereby, shall not be repeated here.
In comparison with the connecting method by use of dove-tail scoop channel for assembly of the prior art shown in FIG. 3-1, the invention's connecting methods, as described in the previous sections, by use of single groove-and-tongue or double groove-and-tongue eliminate the fracture problem due the stress concentration because there are no comers with acute angle in the semi-circular recesses 66 on the toothlet 54 and the semi-circular protuberance 62 inside the scoop channel 53 when they are engaged each other.
The outer stator 50 for various outer stator/inner rotor motors is assembled with a plurality of disassembled radial toothlets 54 and an main body of the outer stator 52 by use of the following four connecting methods: single positioning pin, double positioning pin,

single groove-and-tongue, and double groove-and-tongue. Nevertheless, the contact surface 541 of the bottom of the rectangular toothlet root of the outer stator's disassembled radial toothlets to the stator main body can be linear shape, V-shape, circular arc shape or any other shape that does not prevent each toothlet from being pushed and tightly fitted into the main body of the stator in radial direction. In other words, the shape of the contact surface 541 can be changed according the requirement of the design. For example, a V-shape or circular-arc-shape recess or protuberance (or stick out) can be added to the rectangular dedendum of the outer stator's disassembled radial toothlet to increase the stability of fixation to the main body of the stator. The connecting method of its assembly is the same as the four connecting methods described in the previous sections, which are: single positioning pin, double positioning pins, single groove-and-tongue, and double groove-and-tongue.
FIG. 5 A is a modified diagram of FIG. 5 for single positioning pin connecting method showing that the change of shape, from linear shape to a circular-arc-shape recess, has been made to the bottom 541 of the rectangular dedendum of the radial toothlet. FIG. 6AA is a modified diagram of FIG. 6A for single positioning pin connecting method showing that the change of shape, from linear shape to a circular-arc-shape recess, has been made to the contact surface 531 of the main body of the stator to the bottom of the radial toothless rectangular dedendum. FIG. 6BA is a modified diagram of 6B for single positioning pin connecting method showing that the change of shape, from linear shape to a circular-arc-shape recess, has been made

to the contact surface 631 of the bottom of the radial toothless rectangular dedendum to the main body of the stator. FIG. 5-1 A, FIG, 5-2A, and FIG. 5-3A are the assembly diagrams of the assembling type outer stator/inner rotor motor when a circular-arc-shape recess is added to the bottom 541 of the rectangular dedendum of the outer stator's radial toothlet. Basically, all of the assembly methods are completely the same as the assembly of the invention's outer stator/inner rotor motor if the circular-arc-shape recess is not added to the rectangular dedendum of the outer stator's radial toothlet. FIG 6A-lA, FIG. 6A-2A, and FIG. 6A-3A are the diagrams that shows the contact surface 531 of the main body of the stator to the bottom of the radial toothlet's rectangular dedendum changing from linear shape to a circular-arc-shape recess. FIG. 6B-1A and FIG. 6B-2A are the diagrams that shows the contact surface 631 of the bottom of the radial toothless rectangular dedendum to the main body of the stator changing from linear shape to a circular-arc-shape recess.
FIG. 5B is a modified diagram of FIG. 5 that shows the change of the bottom 541 of the radial toothless rectangular dedendum from linear shape to a V-shape recess for single positioning pin connecting method. FIG. 6AB is a modified diagram of FIG. 6A that shows the change of the contact surface 531 of the main body of the stator to the bottom of the radial toothless rectangular dedendum from linear shape to a V-shape recess for single positioning pin connecting method. FIG. 6BB is a modified diagram of FIG. 6B that shows the changes of the contact surface 631 of the bottom of the radial toothless rectangular dedendum to the main body of the stator from

linear shape to a V-shape recess for single positioning pin connecting method. FIG. 5-lB, FIG. 5-2B, and FIG. 5-3B are the assembly diagrams of the assembling type outer stator/inner rotor motor when a V"Shape recess is added to the bottom 541 of the rectangular dedendum of the outer stator*s radial toothlet. All of the assembly methods are completely the same as the assembly of the invention's outer stator/inner rotor motor if the V-shape recess is not added to the rectangular dedendum of the outer stator's radial toothlet. FIG. 6A-1B, FIG. 6A-2B, and FIG, 6A-3B are the diagrams that shows the change of the contact surface 531 of the main body of the stator to the bottom of the radial toothless rectangular dedendum from linear shape to a V-shape recess. FIG. 6B-1B and FIG. 6B-2B are diagrams that show the change of the contact surface 631 of the bottom of the radial toothlet's rectangular dedendum to the main body of the stator from linear shape to a V-shape recess.
As for the contact surfaces of the rectangular dedendum of the outer stator's toothlet and the main body of the stator, no matter whether it is a V-shape or circular arc shape protuberance, or any other shaped protuberance that does not prevent each radial toothlet from being pushed and tightly fitted into the main body of the stator in radial direction, the principle is similar to the previous description of adding V-shape or circular-arc-shape recess, and shall not be repeated here.
FIG. 10 is the diagram that depicts the punching operation of the invention's main body of the outer stator 52 shown in FIG. 6A and the main body of the outer stator 52 shown in FIG. 6A-2. There is only

one difference in hole-punching operation between the main body of the outer stator 52 (used for the assembling by use of single positioning pins) in FIG. 6A and the main body of the outer stator 52 (used for the assembling by use of single groove-and-tongue) in FIG. 6A-2. Therefore, the design in sequential punching mold can be plan together. Moreover, since one needs only to determine the enabling or disabling of this punching operation during the punching process to obtain two components with different design, the developing cost of the mold can be greatly reduced.
[Inner stator/outer rotor brushless motor]
FIG. 8 is a schematic cross-sectional view of the invention applied in inner stator/outer rotor brushless motor. As shown in FIG. 8, the inner stator/outer rotor brushless motor of the invention includes an inner stator 80 and an outer rotor (not shown in FIG. 8). The inner stator 80 includes an inner main body of the stator 82, a plurality of toothlets 84, a plurality of positioning pins 98 (refer to FIG. 8A), a plurality of bobbins 85, and a plurality of coils 87. FIG. 9A is a schematic cross-sectional view of the inner main body of the stator 82 of the inner stator/outer rotor motors of the invention, FIG. 9B is a sectional configuration diagram of a plurality of disassembled radial toothlets of the inner stator/outer rotor motors of the invention. As shown in FIG. 9A and FIG. 9B, a plurality of scoop channels 83 are evenly allocated on the internal side of the inner main body of the stator 82 according to the number of the teeth of the stator for housing a plurality of toothlets 84 with the same number. A plurality of

toothlets 84 thereof is disassembled according to the exactly required number of toothlets. As shown in FIG. 9B, each of a plurality of toothlets 84 includes a addendum 91 and a rectangular dedendum 93. The toothlet 94 is constructed by punching and stacking up a plurality of permeable silicon steel sheets (refer to FIG. 8A). The top end 92 of the addendum 91 is a circular arc surface and a applicable air gap (not shown in FIG. 8A) is kept from its corresponding outer rotor (not shown in FIG. 8A). The dedendum 93 of each toothlet 84 matches the configuration and size of the scoop channel 83 so that the toothlet can be inserted and tightly fitted into the scoop channel 83. Each of two comers of the rectangular dedendum 93 has a chamfer 95 to facilitate the insertion of the toothlet into the main body of the stator 82.
The assembling type inner stator/outer rotor motor is assembled by inserting the dedendum 93 of each disassembled radial toothlet 84 into each scoop channel 83 by use of single positioning pins. As shown in FIG. 9A, one intemal side of each scoop channel 83 has a semi-circular recess 86; correspondingly, one side of the dedendum 93 of each disassembled radial toothlet 84 also has a semi-circular recess 96. The position of the semi-circular recess 96 is such that it will correspond to the semi-circular recess 86 in one intemal side of the scoop channel 83 when the dedendum 93 of each toothlet 84 is inserted and tightly fitted into the scoop channel 83. As a result, an assembly hole 88 (refer to FIG. 8) is formed between one side of the scoop channel 83 and the corresponding side of the dedendum 93 of the toothlet 84. On the other hand, a plurality of bobbins 85 made of insulate material is used to be slipped on a plurality of toothlets 84 for

winding.
The assembly procedure of the invention applied in inner stator/outer rotor motors is similar to that of the outer stator/inner rotor motors shown in FIG. 7. FIG. 8A is a isometric assembly diagram of the invention applied in inner stator/outer rotor brushless motors. As shown in FIG. 8, the assembling procedure for the stator of the motor is described in the following four steps. Step 1: appropriately place the constructed main body of the stator 82 for the inner stator/outer rotor motors. Step 2: place a plurality of coils 87 that has completed winding on the bobbin 85 at an appropriate position inside the inner main body of the stator 82. Step 3: insert one single toothlet 84 after the other into the scoop channel 83 of the inner main body of the stator 82 inward into the center of the axis while knocking the positioning pin 98 (refer to FIG. 8A) into the matching assembly hole 88 one by one. Step 4: complete the assembly of the stator of inner stator/inner rotor motor as the last step. Because of assembling in radial direction, a chamfer 95 is made at each comer of each dedendum 93. Therefore, the assembly is easier and faster comparing with the assembly process of the prior art shown in FIG. 3-1, which requires the assembly be done in axial direction by use of dove-tail scoop channel.
The assembly of the assembling type inner stator/outer rotor motor is accomplished with the following four connecting methods: single positioning pin, double positioning pin, single groove-and-tongue, and double groove-and-tongue.
The connecting method for the stator structure by use of single

positioning pin has been described in previous section. As for the connecting method for the stator structure by use of double positioning pins, refer to FIG. 8-1, FIG. 9A-1, and FIG. 9B-1 that are relative to FIG. 8, FIG. 9A, and FIG. 9B, respectively. As shown in FIG. 8-1, FIG. 9A-1, and FIG. 9B-1, each of the two internal sides of each scoop channel 83 on the inner main body of the stator 82 has a semi-circular recess 86 (refer to FIG. 9A-1); correspondingly, each of the two sides of the dedendum 93 of the disassembled radial toothlet 84 also has a semi-circular recess 96 (refer to FIG. 9B-1). The position of the two semi-circular recesses 96 are such that they will correspond to the two semi-circular recesses 86 on the two internal sides of the scoop channel 83 when the dedendum 93 of each toothlet 84 is inserted and tightly fitted into the scoop channel 83. As a result, two assembly holes 88 (refer to FIG. 8-1) are formed between each of two sides of the scoop channel 83 and their corresponding sides of the dedendum 93 of the toothlet 84. The assembly procedure is the same as that shown in FIG. 8A except that it requires two positioning pins for each toothlet 84.
Refer to FIG. 8-2 and FIG. 9A-2 that are relative to FIG. 8 and FIG. 9A for the assembly by use of single groove-and-tongue. As shown in FIG. 8-2 and FIG. 9A-2, each internal side of each scoop channel 83 on the inner main body of the stator 82 (refer to FIG. 9A-2) has a semi-circular protuberance 92, correspondingly, each side of the dedendum 93 of each disassembled radial toothlet 84 (refer to FIG. 8-2) has a semi-circular recess 96. The positions of the semi-circular protuberance 92 and the semi-circular recess 96 are such that when the

dedendum 93 of each toothlet 84 is inserted and tightly fitted into each scoop channel 83, the semi-circular recess 96 on the toothlet 84 and the semi-circular protuberance 92 inside the scoop channel 83 are engaged each other. The connecting method of the assembly is similar to that shown in FIG. 7-2, which is a isometric diagram for the assembly of outer stator/inner rotor motor assembled by use of single groove-and-tongue. FIG. 8B is a isometric diagram of the invention applied in inner stator/outer rotor brushless motors by use of single groove-and-tongue wherein the assembling procedure of the motor stator is described in the following four steps. Step 1: appropriately place a plurality of coils 87 that has completed winding on the bobbin 85. Step 2: insert one single toothlet 84 after the other into the bobbin 85 inward into the center of the axis. Step 3: Step 3: fit the coil 87 with inserted toothlets 84 into the scoop channel 83 inside the inner main body of the stator 82 of the inner stator 80 in axial direction, so that the semi-circular recess 96 on the toothlet 84 and the semicircular protuberance 92 inside the scoop channel 83 are engaged each other. Step 4: complete the assembly of the stator of the inner stator/outer rotor motor as the last step. This design is more applicable for the motors of lower stacking ratio of silicon steel sheets because when assembling the inner stator 80, each toothlet 84 must be inserted into the bobbin 85 that has completed winding and then be inserted into the inner main body of the stator 82 in axial direction together. Otherwise, wire connection can be complicated if the toothlet 84 is inserted into the inner main body of the stator 82 one by one.
Refer to FIG. 8-3 and FIG. 9A-3 that are relative to FIG. 8-2 and

9A-2, respectively, for the connecting method of the stator stmcture by use of double groove-and-tongue. As shown in FIG. 8-3 and FIG. 9A-3, each of the two internal sides of each scoop channel 83 on the inner main body of the stator 82 (refer to FIG. 9A-3) has a semicircular protuberance 92; correspondingly, each of the two sides of each dedendum 93 of the disassembled radial toothlets 84 (refer to FIG. 8-3) has a semi-circular recess 96. The position of the protuberance 92 and the recess 96 are such that when the dedendum 93 of each toothlet 84 is inserted and tightly fitted into each scoop channel 83, the two semi-circular recesses 96 on the toothlet 84 and the two semi-circular protuberance 92 inside the scoop channel 83 are engaged each other. The assembling procedure for the assembly of the motor stator is the same as that of the assembly by use of single groove-and-tongue shown in FIG. 8B, and shall not be repeated here.
In comparison with the connecting method by use of dove-tail scoop channel for assembly of the prior art shown in FIG. 3-1, the connecting methods of the invention, described in the previous sections, by use of single groove-and-tongue or double groove-and-tongue eliminate the fracture problem due the stress concentration because there is no comer of acute angle in the semi-circular recesses 96 on the toothlet 84 and the semi-circular protuberance 92 inside the scoop channel 83 when they are engaged each other. Similarly, the contact surface 841 of the rectangular toothlet root bottom of the inner stator's disassembled radial toothlets to the stator main body can be linear shape, V-shape, circular arc shape, or any other shape that does not prevent each toothlet from being pushed and tightly fitted into the

main body of the stator in radial direction. In other words, the shape of the contact surface 841 can be changed according the requirement of the design. For example, a V-shape or circular-arc-shape recess or protuberance (or stick out) can be added to the rectangular dedendum of the inner stator's disassembled radial toothlet to increase the stability of fixation to the main body of the stator. The connecting method of its assembly is the same as the four connecting methods described in the previous section, which are: single positioning pin, double positioning pins, single groove-and-tongue, and double groove-and-tongue.
FIG. 8AA is a modified diagram of FIG. 8 for single positioning pin connecting method showing that the change of shape, from linear shape to a circular-arc-shape recess, has been made to the bottom 841 of the rectangular dedendum of the radial toothlet. FIG. 9AA is a modified diagram of FIG. 9A for single positioning pin connecting method showing that the change of shape, from linear shape to a circular-arc-shape recess, has been made to the contact surface 831 of the main body of the stator to the bottom of the radial toothlet's rectangular dedendum. FIG. 9BA is a modified diagram of 9B for single positioning pin connecting method showing that the change of shape, from linear shape to a circular-arc-shape recess, has been made to the contact surface 941 of the bottom of the radial toothlet's rectangular dedendum to the main body of the stator. FIG. 8-1 A, FIG. 8-2A, and FIG. 8-3A are the assembly diagrams of the assembling type inner stator/outer rotor motor when a circular-arc-shape recess is added to the bottom 841 of the rectangular dedendum of the inner

stator's radial toothlet. Basically, all of the assembly methods are completely the same as the assembly of the inner stator/outer rotor motor of the invention if the circular-arc-shape recess is not added to the rectangular dedendum of the inner stator's radial toothlet. FIG 9A-lA, FIG. 9A-2A, and FIG. 9A-3A are the diagrams that shows the contact surface 831 of the main body of the stator to the bottom of the radial toothlet's rectangular dedendum changing from linear shape to a circular-arc-shape recess. FIG. 9B-1A is the diagrams that shows the contact surface 941 of the bottom of the radial toothlet's rectangular dedendum to the main body of the stator changing from linear shape to a circular-arc-shape recess.
FIG. 8BB is a modified diagram of FIG. 8 that shows the change of the bottom 541 of the rectangular dedendum of the radial toothlet from linear shape to a V-shape recess for single positioning pin connecting method. FIG. 9AB is a modified diagram of FIG. 9A that shows the change of the contact surface 831 of the main body of the stator to the bottom of the radial toothlet's rectangular dedendum from linear shape to a V-shape recess for single positioning pin connecting method. FIG. 9BB is a modified diagram of FIG. 9B that shows the changes of the contact surface 941 of the bottom of the radial toothlet's rectangular dedendum to the main body of the stator from linear shape to a V-shape recess for single positioning pin connecting method. FIG. 8-lB, FIG. 8-2B, and FIG. 8-3B are the assembly diagrams of the assembling type inner stator/outer rotor motor when a V-shape recess is added to the bottom 841 of the rectangular dedendum of the inner stator's radial toothlet. All of the assembly

methods are completely the same as the assembly of the inner stator/outer rotor motor of the invention if the V-shape recess is not added to the rectangular dedendum of the stator's radial toothlet. FIG. 9A-1B, FIG. 9A-2B, and FIG. 9A-3B are the diagrams that shows the change of the contact surface 831 of the main body of the stator to the rectangular dedendum of the radial toothlet from linear shape to a V-shape recess. FIG. 9B-1B is the diagram that shows the change of the contact surface 941 of the rectangular dedendum of the radial toothlet to the main body of the stator from linear shape to a V-shape recess.
As for the contact surfaces of the rectangular dedendum of the inner stator's toothlet and the main body of the stator, whether it is a V-shape or circular arc shape protuberance, or any other shaped protuberance that does not prevent each radial toothlet from being pushed and tightly fitted into the main body of the stator in radial direction, the principle is similar to the previously description of adding V-shape or circular-arc-shape recess, and shall not be repeated here.
[Shunt Brush Motor]
When the assembling type stator structure of the invention is applied in shunt motors, the assembling type stator structure includes an main body of the outer stator 101, or a plurality of disassembled small outer stators' main bodies 105. Each of the small main body of the outer stator has a plurality of scoop channels. The assembly of the main body of the outer stator can be done by use of one of the following four connecting methods: single positioning pin, double

positioning pins, single groove-and-tongue, and double positioning groove-and-tongue.
A plurality of disassembled radial toothlets 102, include a addendum and a dedendum, the disassembled radial toothlets are constructed by punching and stacking up a plurality of permeable silicon steel sheets. Each of the toothlets has configuration and size matching those of the scoop channels so that the toothlet can be inserted and tightly fitted into the scoop channel. Each of the two comers of the dedendum has a chamfer to facilitate insertion into the main body of the stator. The assembly of the assembling type stator can be done by connecting the disassembled radial toothlets to the main body of the stator with one of the following four methods: single positioning pin, double positioning pins, single groove-and-tongue, and double groove-and-tongue. Moreover, the assembling type stator of the shunt motor includes a plurality of positioning pins 102 for positioning and a plurality of bobbins 104 made of insulate material for fitting a plurality of toothlet for winding.
The primary effectiveness of the assembling type stator structure for shunt motors is its low manufacturing cost when applied in single tooth winding because the operation mechanism required for the winding machine is simple and the production is very fast.
There can be a large number of co-assembly sets because every small main body of the outer stator and the disassembled radial toothlet can be co-assembled to each other to construct an assembling type stator structure with one of the following connecting methods: single positioning pin, double positioning pins, single groove and

tongue, and double groove-and-tongue. FIG. 14, FIG. 14-1, FIG. 14-2, FIG. 14-3, FIG. 14-4, and FIG. 14-5 are the cross-sectional views of various assembling methods of the assembling type stator structure applied in the outer stator of shunt bi-pole outer stator brush motors.
FIG. 15, FIG. 15-1, FIG. 15-2, FIG. 15-3, FIG. 15-4, and FIG. 15-5 are the cross-sectional views of various assembling methods of the assembling type stator structure applied in quadri-pole outer stator shunt brush motor of the invention. Other assembling methods are possible and shall not be necessary to give all possible descriptions.
While the invention has been described by way of example and in terms of the preferred embodiment, it is to be understood that the invention is not restrictioned to the disclosed embodiments. To the contrary, it is intended to cover various modifications and similar arrangements as would be apparent to those skilled in the art. Therefore, the scope of the appended claims should be accorded the broadest interpretation so as to encompass all such modifications and similar arrangements.

WHAT IS CLAIMED IS:
1. An assembling type stator structure of motors comprising:
a main body of the stator having a plurality of scoop channels and at least one side of each scoop channel has a semi-circular recess;
a plurality of positioning pins for positioning;
a plurality of disassembled radial toothlets having an addendum and a dedendum and the disassembled radial toothlets are constructed by punching and stacking up a plurality of permeable silicon steel sheets, the top end of the addendum is a circular arc surface and a applicable air gap is kept from its corresponding rotor, the dedendum of each toothlet matches the configuration and size of the scoop channel of the main body of the stator to be inserted and tightly fitted into the scoop channel, at least one side of the dedendum has a semi-circular recess and each of the two comers of the dedendum has a chamfer to facilitate insertion into the main body of the stator; the dedendum of each disassembled radial toothlet is inserted into each scoop channel to assemble the assembling type stator by use of single positioning pinsDand
a plurality of bobbins made of insulate material for bushing a plurality of toothlets for winding.
2. An assembling type stator structure of motors as claimed in claim 1, wherein the stator structure is applicable to outer stator/inner rotor motors.
3. An assembling type stator structure of motors as claimed in claim 1, wherein the stator structure is applicable to inner stator/outer rotor

motors.
4. An assembling type stator structure of motors as claimed in claim 1, wherein the stator structure is applicable to shunt motors.
5. An assembling type stator stmcture of motors as claimed in claim 1, in which the dedendum of each disassembled radial toothlet is inserted into each scoop channel to assemble the assembling type stator by use of double positioning pins instead of single positioning pins.
6. An assembling type stator stmcture of motors as claimed in claim 1, in which the dedendum of each disassembled radial toothlet is inserted into each scoop channel to assemble the assembling type stator of the motor by use of single semi-circular groove-and-tpngue instead of the single positioning pins.
7. An assembling type stator stmcture of motors as claimed in claim 1, in which the dedendum of each disassembled radial toothlet is inserted into each scoop channel to assemble the assembling type stator by use of double semi-circular groove-and-tongue instead of the single positioning pin connecting method.
8. An assembling type stator stmcture of motors as claimed in claim 1, wherein the contact surface of the dedendum of the disassembled +radial toothlet of the stator to the main body of the stator can be a linear shape, a V-shape, a circular arc shape, or any other shape that does not prevent each toothlet from being inserted and tightly fitted into the main body of the stator.
9. A stator stmcture of shunt motor comprising:
a plurality of disassembled small main body of the outer stator, each

of them having a plurality of scoop channels that can be assembled by one of the following connecting methods: single positioning pin, double positioning pins, single groove-and-tongue, and double groove-and-tongue;
a plurality of disassembled radial toothlets having a addendum and a dedendum made by punching and stacking up a plurality of permeable silicon steel sheets wherein the end surface of the addendum is a circular arc surface and a applicable air gap is kept from its corresponding rotor, the dedendum of each toothlet matches the configuration and size of the scoop channel of the main body of the stator to be inserted and tightly fitted into the scoop channel, and there is a chamfer at each of the two comers of the dedendum to facilitate the insertion to the main body of the stator, moreover, at least one side of the dedendum has a semi-circular recess, what is more, the dedendum of each disassembled radial toothlet is inserted into each scoop channel and connected to the main body of the stator to assemble the assembling type stator by use of either single positioning pin, double positioning pins, single groove-and-tongue, or double groove-and-tongue connecting methods;
a plurality of positioning pins for positioning; and
a plurality of bobbins made of insulated material for slipping on a plurality of toothlets for winding.

10. An assembling type stator structure of motors substantially as herein described with reference to the accompanying drawings and examples.

Documents:

243-che-2004-abstract.pdf

243-che-2004-claims duplicate.pdf

243-che-2004-claims original.pdf

243-che-2004-correspondnece-others.pdf

243-che-2004-correspondnece-po.pdf

243-che-2004-description(complete) duplicate.pdf

243-che-2004-description(complete) original.pdf

243-che-2004-drawings.pdf

243-che-2004-form 1.pdf

243-che-2004-form 19.pdf

243-che-2004-form 26.pdf

243-che-2004-form 3.pdf

243-che-2004-form 5.pdf

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Patent Number

201917

Indian Patent Application Number

243/CHE/2004

PG Journal Number

05/2007

Publication Date

02-Feb-2007

Grant Date

16-Oct-2006

Date of Filing

18-Mar-2004

Name of Patentee

M/S. UNIQUE PRODUCT & DESIGN CO., LTD

Applicant Address

5, MING DONG ROAD, YUNG KANG CITY, TAINAN HSIEN, TAIWAN

Inventors:

#	Inventor's Name	Inventor's Address
1	LIAO, GORDON	5, MING DONG ROAD, YUNG KANG CITY, TAINAN HSIEN, TAIWAN

PCT International Classification Number

H02 K 15/03

PCT International Application Number

N/A

PCT International Filing date

PCT Conventions:

#	PCT Application Number	Date of Convention	Priority Country
1			NA