RU2006113194A - OUTDOOR MOTOR STATOR AND METHOD OF ITS PRODUCTION - Google Patents

Claims (35)

1. The stator of the motor with an external rotor containing a spiral core obtained by stacking and spiraling a steel plate, including teeth and a base element; an upper insulator having a shape corresponding to the shape of the spiral core, and covering the upper part of the spiral core; a lower insulator having a shape corresponding to the shape of the spiral core, and covering the lower part of the spiral core during mutual assembly with the upper insulator, and the lower insulator is made of electrically insulating material; connecting means made on a steel plate forming a spiral core (HC) in such a way as to prevent the deployment of the steel plate in the opposite direction to the folding direction of the steel plate when the steel plate is wrapped and coiled in a spiral, and also to prevent a shift relative to each other of the individual layers in the package of the steel plate; and a cutout formed in the base element of a steel plate forming a spiral core (HC) in order to reduce stress during core rolling. 2. The stator according to claim 1, in which the connecting means includes a connecting protrusion extending from the upper or lower surface of the steel plate, and a connecting recess made on the lower or upper surface of the steel plate. 3. The stator according to claim 1, in which the connecting means is made on the teeth of a steel plate. 4. The stator according to claim 1, in which the upper and lower insulators are combined in the upper and lower insulators, and contains a connecting element protruding from the inside of the spiral core (HC) towards the center of the stator. 5. The stator according to claim 4, in which the connecting element contains a connecting hole that allows you to attach the stator to the fastening side of the tank using the connecting means. 6. The stator according to claim 4, in which the connecting hole is formed by the convexity of the connecting element, and the bulge protrudes in the direction of the closed surface. 7. The stator according to claim 1, in which there is a support rib extending in a circumferential direction to the inner radial part of the closed surfaces of the upper and lower insulators in contact with the top and bottom of the spiral core (HC), respectively, designed to support the inner side of the core . 8. The stator according to claim 1, in which at least one supporting rib is made for the connecting part of the upper and lower insulators for connecting the bulge forming the connecting hole with the supporting rib, thereby distributing the connecting force concentrated on the bulge, and increasing rigidity of the connecting part. 9. The stator according to claim 1, in which on both side walls of the T-shaped teeth of the lower and upper insulators are made steps along which the lower and upper insulators are interconnected. 10. The stator according to claim 9, in which the steps are made on both side walls of the T-shaped teeth, and if one side of the T-shaped teeth of the lower and upper insulators is made in the shape of "¬", the other side is made in the form of "L". 11. The stator according to claim 1, in which both end sides of the side walls, made perpendicular to each other on both side walls of the T-shaped teeth of the lower and upper insulators, have a complementary shape, forming a step in one plane. 12. The stator according to claim 1, in which the protruding locking surface is made on the outer side of both end faces of the T-shaped teeth of the lower and upper insulators and is designed to fix the shoe of the core of the spiral core. 13. The stator according to claim 1, in which around the connecting hole made in the connecting part of the upper insulator, the position-determining protrusion is made, the position-determining protrusion has an additional shape to the position-determining recess or hole made on the fixed side of the tank mount. 14. The stator according to claim 1, in which a cylindrical sleeve is made inside the connecting hole. 15. The stator of claim 14, wherein the cylindrical sleeve is a spring pin having resilience due to a longitudinally cut portion of the outer circumferential surface. 16. The stator according to 14, in which the cylindrical sleeve, which does not have a cut-off part, has a hollow shape for installation with force in the connecting hole. 17. The stator according to claim 1, in which the spiral core is riveted with a rivet passing through a through hole made in the base. 18. The stator according to claim 1, in which the initial clotting point and the final clotting point of the spiral core are welded to predetermined parts of the base. 19. The stator according to claim 1, in which "a" is the length of the T-shaped teeth extending from the outer surface of the spiral core is equal to or greater than "b" is the distance between the inner surface of the spiral core and the center point of the connecting hole made in the connecting part , i.e. "ab". 20. The stator according to claim 1, in which the recess for the insertion of the core has a semi-cylindrical or oval shape. 21. The stator according to claim 20, in which the recess for the tab has a symmetrical design relative to its Central part, and the Central part of the recess for the tab is deeper than both sides of the recess for the tab. 22. The stator according to claim 20 or 21, in which the recess for the tab is made at the base of the spiral core and is located between the T-shaped teeth of the spiral core and the T-shaped teeth. 23. The stator according to claim 1, in which the end of the T-shaped teeth is given a C-shape to reduce vibration and noise arising from the moment of the spiral core. 24. The stator according to claim 23, in which the edge part of the T-shaped teeth of the spiral core is C-shaped by beveling the corner parts at the ends of each side. 25. The stator according to paragraph 24, in which the mowing is performed in a straight line or along a curved line. 26. The stator according to claim 1, in which the core of the steel plate is formed by punching two lines on the conductive sheet, and an incision is formed on the base part facing the T-shaped teeth, the shape of which is identical to the edge part of the T-shaped teeth. 27. The stator according to claim 26, wherein an ejector groove is formed on the tooth of the core from the steel plate to facilitate the process of separating the core from the steel plate. 28. A motor stator with an outer rotor of a washing machine with a drum, comprising a spiral core with a multilayer structure obtained by packaging a steel plate having a base in the form of a tape and T-shaped teeth protruding from the base when rolling the steel plate into a spiral, starting from the lower layer to the upper layer; a top insulator of electrical insulating material covering the upper side of the spiral core in a form complementary to the shape of the spiral core; and a lower insulator of electrically insulating material covering the lower side of the spiral core during assembly with the upper insulator in a form complementary to the shape of the spiral core; moreover, the steel plate forming the spiral core includes a groove having a shape complementary to the spiral core on the upper or lower surface of the steel plate in order to prevent the steel plate from expanding in a direction opposite to the direction of the spiral when applying steel plates by rolling the steel plates in the spiral direction , and to prevent loosening of the package of steel plates, and the mounting section having protrusions facing the mounting groove and pressed into the upper or lower steel plate surface, and the base of the spiral core includes an incision to reduce stresses in the coagulation of the core. 29. A motor stator with an external rotor, comprising an annular spiral core with a multilayer structure, obtained by packaging a steel plate having a base in the form of a tape and T-shaped teeth protruding from the base when rolling the steel plate into a spiral, starting from the lower layer to the upper layer; an upper insulator of electrical insulating material covering the upper side of the spiral core in a form complementary to the shape of the spiral core; and a lower insulator of electrically insulating material having a shape complementary to the shape of the spiral core in order to cover the lower side of the spiral core during assembly with the upper insulator, the spiral core comprising an installation pin on the upper and lower surfaces of each of the T-shaped teeth of the steel plate of the core and a hole complementary to the installation pin, designed to prevent the core from expanding from the steel plate in the direction opposite to the direction of rotation of the spiral, as well as the shift of the lower or upper layer of the core from the steel plate when packaging the core from a steel plate when rolling the core from a steel plate into a spiral; an incision in the base between each of the adjacent T-shaped teeth of the core from the steel plate to reduce stresses in the coagulation of the core; and essentially the C-shaped end of each of the T-shaped teeth, to reduce noise arising from the moment of the induction motor when it starts. 30. A method of manufacturing a motor stator with an external rotor, wherein using a conductive sheet, which is a base material; the base material is cut down to form two rows of cores from a steel plate having one pair of base parts in the form of a tape, opposite in width, and T-shaped teeth protruding alternately to the opposite base part; forming a multilayer annular spiral core by stacking the core from the steel plate while rolling the core from the steel plate into a spiral from the lower layer to the upper layer; and the spiral core is placed in an insulator of electrically insulating material having a shape complementary to the spiral core. 31. The method according to item 30, in which the base material is cut in two rows so that in the base part, opposite one side of the T-shaped teeth, an incision is formed having a shape identical to the shape of the end of one side of the T-shaped teeth. 32. The method according to clause 30, in which the T-shaped teeth of the core of the steel plate have a concavity made in them for pushing, designed for smooth separation of the core from steel plates. 33. The method according to clause 30, in which the end of the T-shaped teeth of the core of the steel plate give a C-shape to significantly reduce vibration and noise arising from the moment of the spiral core. 34. The method according to clause 30, wherein when placing the spiral core, cover the upper side of the spiral core with an upper insulator of electrically insulating material having a shape that complements the shape of the upper part of the spiral core; and covering the lower side of the spiral core with a lower insulator of electrically insulating material having a shape complementary to that of the lower part of the spiral core. 35. The method according to clause 30, in which the base part of the core of the steel plate has a notch to reduce stresses that occur during coagulation of the core.