TW201532370A - Composite doublet stator and its winding method - Google Patents

Abstract

This invention relates to a composite doublet stator and its winding method. The winding method comprises using a winding machine to wind a single conductive wire around the first to fourth arms of the composite doublet stator to gradually form a first, a second and a third conductive wire layers, wherein the head and tail of the first conductive wire layer are respectively wound around the first and second pole pins, the head and tail of the second conductive wire layer are respectively wound around the fourth and third pole pins, the head of the third conductive wire layer is wound around the second pole pin and cascaded to the tail of the first conductive wire layer, and its tail is wound around the fourth pole pin. The total wire length of the first conductive wire layer and the third conductive wire layer is equal to the wire length of the second conductive wire layer. The composite doublet stator and its winding method may be used in conjunction with the winding machine to achieve the function of automatic wire separation and winding so as to save labor expenditure and reduce manual defect to promote productivity.

Description

Composite two-wire stator and winding method thereof

The invention relates to a composite two-wire stator and a winding method thereof, in particular to a composite two-wire stator capable of automatically dividing and winding a winding machine to reduce manpower expenditure and a winding method thereof.

The two-wire stator has a specific use, and the two-wire stator comprises a plurality of stacked silicon steel sheets, and a magnetic pole portion on which a plurality of winding wires are arranged on the silicon steel sheet, wherein the stacked silicon steel sheets are placed on the winding machine to make a winding. The wire machine performs winding work on the magnetic pole portion in a two-wire winding manner. However, the two-wire winding two-wire head and the two-wire tail need to be manually divided and entangled, and cannot be automatically achieved by the winding machine. The purpose of dividing the line and tangling is labor-intensive, and the manual line and the entangled line are also inaccurate due to human error, resulting in a decline in production yield.

The main object of the present invention is to provide a composite two-wire stator and a winding method thereof, thereby improving the current two-wire stator winding method of the winding machine with two wires, requiring manual dividing and winding, which causes labor and labor. The problem of reduced production yield.

In order to achieve the foregoing object, the composite two-wire stator of the present invention comprises a body formed by a plurality of stacked silicon steel sheets, the body being provided with a ring portion, and a first magnetic pole arranged at intervals on the outer side surface of the ring portion is formed. a second magnetic pole portion, a third magnetic pole portion and a fourth magnetic pole portion, the first magnetic pole portion includes a first pole arm and a first magnetic pole pin, and the second magnetic pole portion includes a second pole arm and a a second magnetic pole pin, the third magnetic pole portion includes a third pole arm and a third magnetic pole pin, the fourth magnetic pole portion includes a fourth pole arm and a fourth magnetic pole pin, and the first pole arm and the third pole a first wire layer, a second wire layer and a third wire layer are disposed on the pole arm and are stacked in a first direction, and the second pole arm and the fourth pole arm are respectively provided with a first wire layer, a second wire layer, and a third wire layer, which are disposed in two directions, and have a first direction opposite to the second direction, wherein a wire end of the first wire layer is wound around the first magnetic pole pin The wire tail is wound around the second magnetic pole pin, and the wire end of the second wire layer is wound around the fourth magnetic pole pin and wound at the end of the wire a third magnetic pole pin, the wire end of the third wire layer is wound around the second magnetic pole pin and serially connected to the tail end of the first wire layer, and the wire tail of the third wire layer is wound around the fourth magnetic pole pin, the line of the first wire layer The sum of the line lengths of the long and third wire layers is equal to the line length of the second wire layer.

In order to achieve the foregoing object, the winding method of the composite two-wire stator of the present invention uses a wire winding machine to wind a body formed by stacking the silicon steel sheets, and the winding of the composite two-wire stator is wound. The method includes: a step of forming a first wire layer, the wire end of the wire is first wound around the first magnetic pole pin of the body, and then the wire is wound in a first direction around the first pole arm of the body, and then opposite to the first direction a second direction of winding the second pole arm of the body, and then winding the third pole arm of the body in a first direction, and then winding the fourth pole arm of the body in a second direction, and then winding the second magnetic pole pin of the body And cutting to form a first wire layer; in the forming step of the second wire layer, the winding machine is wound around the fourth magnetic pole pin of the body with the wire end of the same wire, and then wound around the first pole of the body in the first direction And winding the second pole arm of the body in a second direction opposite to the first direction, then winding the third pole arm of the body in a first direction, and winding the fourth pole arm of the body in a second direction, Third magnetic pole wound on the body And cutting to form a second wire layer; in the forming step of the third wire layer, the wire winding machine is wound on the second magnetic pole pin of the body with the wire end of the same wire, and is connected in series with the tail end of the first wire layer, And then winding the wire in a first direction around the first pole arm of the body, and then winding the second pole arm of the body in a second direction opposite to the first direction, and then winding the third pole arm of the body in a first direction, And winding the fourth pole arm of the body in a second direction, and then winding the fourth pole pin of the body and cutting to form a third wire layer, and the line length of the first wire layer and the line length of the third wire layer The sum of the lines is equal to the line length of the second wire layer.

According to the above, the winding method of the composite two-wire stator allows the winding machine to wind the same wire on the body, and repeats three times to form the first, second and third wire layers respectively, and can borrow The wire end of the third wire layer is connected in series with the wire tail of the first wire layer by a winding machine, so that the total length of the wire length of the first wire layer of the composite two-wire stator and the wire length of the third wire layer is equal to The length of the second wire layer is the same, so that the resistance value is the same as the inductance. The composite two-wire stator and its winding method can achieve the functions of automatic dividing and entanglement with the winding machine, greatly reducing labor expenditure and reducing human operation. Poor quality and quality hazards, which in turn increase production yield.

Referring to FIG. 1 and FIG. 2, a preferred embodiment of a method for winding a composite two-wire stator according to the present invention includes a body 10 formed by a plurality of stacked silicon steel sheets, and a ring portion is disposed on the body 10. 11. A first magnetic pole portion 12, a second magnetic pole portion 13, a third magnetic pole portion 14 and a fourth magnetic pole portion 15 are formed on the outer side surface of the ring portion 11, and the first magnetic pole portion 12 includes a first a pole arm 121 and a first pole pin 122. The second pole portion 13 includes a second pole arm 131 and a second pole pin 132. The third pole portion 14 includes a third pole arm 141 and a third pole. The magnetic pole pin 142 includes a fourth pole arm 151 and a fourth pole pin 152. Please refer to FIG. 1 , FIG. 6 to FIG. 8 , and the first pole arm 121 and the third pole arm 141 . A first wire layer 20, a second wire layer 30, and a third wire layer 40 are disposed in the first direction and are stacked on the second pole arm 131 and the fourth pole arm 151. The first wire layer 20, the second wire layer 30 and the third wire layer 40 are wound around the second direction, and the first direction is opposite to the second direction.

The wire head 21 of the first wire layer 20 is wound around the first magnetic pole pin 122 and the wire tail 22 is wound around the second magnetic pole pin 132. The wire end 31 of the second wire layer 30 is wound around the fourth magnetic pole pin 152 and the tail end 32. Wound around the third magnetic pole pin 142, the wire end 41 of the third wire layer 40 is wound around the second magnetic pole pin 132 and serially connected to the tail 22 of the first wire layer 20, and the tail 42 of the third wire layer 40 is wound around The four magnetic pole pins 152 have a total length of the line length of the first wire layer 20 and a line length of the third wire layer 40 equal to the line length of the second wire layer 30.

In the above, the line length of the first wire layer 20 is 2/3 times the line length of the second wire layer 30, and the line length of the third wire layer 40 is 1/3 times the line length of the second wire layer 30.

The winding method of the composite two-wire stator is a winding body formed by winding a wire 50 on a pair of stacked silicon steel sheets, and the winding method of the composite two-wire stator comprises a first wire layer The forming step of 20, the forming step of the second wiring layer 30, and the forming step of the third wiring layer 40.

Referring to FIG. 1 and FIG. 3, in the forming step of the first wire layer 20, the wire end 21 of the wire 50 is first wound around the first magnetic pole pin 122 of the body 10, and then the wire 50 is wound in the first direction. The first pole arm 121 of the body 10 is wound around the second pole arm 131 of the body 10 in a second direction opposite to the first direction, and then wound around the third pole arm 141 of the body 10 in a first direction, and then The second pole 151 of the body 10 is wound in the second direction, and then wound around the second pole pin 132 of the body 10 and cut. Referring to FIG. 6 , the wire 50 is first, second, and A first wire layer 20 is formed on the third and fourth pole arms 121, 131, 141, 151, and as shown in FIG. 3, the wire end 21 of the first wire layer 20 is wound around the first magnetic pole pin 122 and the wire tail 22 is wound around The second magnetic pole pin 132.

Referring to FIG. 1 and FIG. 4, in the forming step of the second wire layer 30, the winding machine is wound around the fourth magnetic pole pin 152 of the body 10 with the wire head 31 of the same wire 50, and then wound in the first direction. The first pole arm 121 of the body 10 is wound around the second pole arm 131 of the body 10 in a second direction opposite to the first direction, and then wound around the third pole arm 141 of the body 10 in a first direction, and then The second pole 151 of the body 10 is wound in the second direction, and then wound around the third pole pin 142 of the body 10 and cut. Referring to FIG. 7 , the wire 50 is first, second, third, and The second wire layer 30 is formed outside the first wire layer 20 of the quadrupole arms 121, 131, 141, 151, and as shown in FIG. 4, the wire head 31 of the second wire layer 30 is wound around the fourth magnetic pole pin 152 and the tail end 32 is wound around the third magnetic pole pin 142.

Referring to FIG. 1 and FIG. 5, in the forming step of the third wire layer 40, the winding machine is wound around the second magnetic pole pin 132 of the body 10 with the wire head 41 of the same wire 50, and the first wire layer is The wire tail 22 of the 20 is connected in series, and then the wire 50 is wound around the first pole arm 121 of the body 10 in a first direction, and then wound around the second pole arm 131 of the body 10 in a second direction opposite to the first direction, and then The third pole arm 141 of the body 10 is wound in a first direction, and then wound into the fourth pole arm 151 of the body 10 in a second direction, and then wound around the fourth pole pin 152 of the body 10 and cut off. As shown, the wire 50 forms a third wire layer 40 outside the second wire layer 30 of the first, second, third and fourth pole arms 151, and as shown in FIG. 5, the wire end of the third wire layer 40 41 is wound around the second magnetic pole pin 132 and serially connected to the tail 22 of the first wire layer 20, and the tail 42 of the third wire layer 40 is wound around the fourth magnetic pole pin 152.

In summary, the winding method of the composite two-wire stator is matched with the winding machine, and a wire 50 is wound around the first pole arm 121, the second pole arm 131, the third pole arm 141 and the fourth body of the body 10. The pole arm 151 repeats three windings to sequentially form the first wire layer 20, the second wire layer 30 and the third wire layer 40, and passes the wire head 41 of the third wire layer 40 and the first wire layer through the winding machine. The wire tail 22 of the 20 is connected in series with the second magnetic pole pin 132 such that the total length of the line length of the first wire layer 20 of the composite two-wire stator and the line length of the third wire layer 40 is equal to the line of the second wire layer 30. Long, the resistance value is the same as the inductance, so the composite two-wire stator and its winding method cooperate with the winding machine to achieve the functions of automatic branching and tangling, which can save manpower expenditure and facilitate process control, and reduce personnel-induced artificial Poor quality and quality hazards, to achieve the purpose of improving production yield.

10‧‧‧ Ontology
11‧‧‧ Ring Department
12‧‧‧First magnetic pole
121‧‧‧First arm
122‧‧‧First magnetic pole pin
13‧‧‧Second magnetic pole
131‧‧‧Secondary arm
132‧‧‧Second magnetic pole pin
14‧‧‧ Third magnetic pole
141‧‧‧ third pole arm
142‧‧‧ Third magnetic pole pin
15‧‧‧4th magnetic pole
151‧‧‧ fourth pole arm
152‧‧‧fourth magnetic pole pin
20‧‧‧First wire layer
21‧‧‧ thread head
22‧‧‧Line tail
30‧‧‧Second wire layer
31‧‧‧ thread head
32‧‧‧Line tail
40‧‧‧ third wire layer
41‧‧‧ thread head
42‧‧‧tail
50‧‧‧ wire

1 is a schematic view showing a wire winding of a preferred embodiment of a composite two-wire stator and a winding method thereof according to the present invention. 2 is a schematic view showing the wire ends and tail ends of the first, second and third wire layers of a preferred embodiment of the composite two-wire stator and its winding method of the present invention. 3 is a schematic view showing the wire end and the tail end of the first wire layer of a preferred embodiment of the composite two-wire stator and its winding method of the present invention. 4 is a schematic view showing a wire end and a wire tail of a second wire layer of a preferred embodiment of the composite two-wire stator and its winding method of the present invention. FIG. 5 is a schematic view showing a wire end and a wire tail of a third wire layer according to a preferred embodiment of the composite two-wire stator and the winding method thereof. 6 is a schematic view showing a first wire layer of a preferred embodiment of the composite two-wire stator and its winding method of the present invention. 7 is a schematic view showing a second wire layer of a preferred embodiment of the composite two-wire stator and its winding method of the present invention. 8 is a schematic view showing a third wire layer of a preferred embodiment of the composite two-wire stator and its winding method of the present invention.

10‧‧‧ Ontology

11‧‧‧ Ring Department

12‧‧‧First magnetic pole

121‧‧‧First arm

122‧‧‧First magnetic pole pin

13‧‧‧Second magnetic pole

131‧‧‧Secondary arm

132‧‧‧Second magnetic pole pin

14‧‧‧ Third magnetic pole

141‧‧‧ third pole arm

142‧‧‧ Third magnetic pole pin

15‧‧‧4th magnetic pole

151‧‧‧ fourth pole arm

152‧‧‧fourth magnetic pole pin

21‧‧‧ thread head

22‧‧‧Line tail

31‧‧‧ thread head

32‧‧‧Line tail

41‧‧‧ thread head

42‧‧‧tail

Claims (4)

A composite two-wire stator comprising a body formed by a plurality of stacked silicon steel sheets, wherein the body is provided with a ring portion, and a first magnetic pole portion and a second magnetic pole are arranged on the outer side surface of the ring portion. a third magnetic pole portion and a fourth magnetic pole portion, the first magnetic pole portion includes a first pole arm and a first magnetic pole pin, and the second magnetic pole portion includes a second pole arm and a second magnetic pole pin, The third magnetic pole portion includes a third pole arm and a third magnetic pole pin. The fourth magnetic pole portion includes a fourth pole arm and a fourth magnetic pole pin, and is disposed on the first pole arm and the third pole arm. a first wire layer, a second wire layer and a third wire layer are wound and arranged in a first direction, and the second pole arm and the fourth pole arm are both disposed in a second direction and stacked a first wire layer, a second wire layer and a third wire layer, wherein the first direction is opposite to the second direction, wherein the wire end of the first wire layer is wound around the first magnetic pole pin and the wire tail is wound around the second wire a magnetic pole pin, the wire end of the second wire layer is wound around the fourth magnetic pole pin and the wire tail is wound around the third magnetic pole pin, The wire end of the wire layer is wound around the second magnetic pole pin and serially connected to the tail end of the first wire layer, and the wire tail of the third wire layer is wound around the fourth magnetic pole pin, and the wire length of the first wire layer and the third wire layer The sum of the line lengths is equal to the line length of the second wire layer. The composite two-wire stator according to claim 1, wherein the line length of the first wire layer is 2/3 times the line length of the second wire layer, and the line length of the third wire layer is the line of the second wire layer. 1/3 times longer. A winding method for a composite two-wire stator, which uses a wire winding machine to wind a body formed by stacking a pair of silicon steel sheets, and the winding method of the composite two-wire stator comprises: a first wire a step of forming a layer, the wire end of the wire is first wound around the first magnetic pole pin of the body, and then the wire is wound around the first pole arm of the body in a first direction, and then wound in a second direction opposite to the first direction The second pole arm of the body is then wound around the third pole arm of the body in a first direction, and then wound around the fourth pole arm of the body in a second direction, and then wound around the second pole pin of the body and cut to form a first wire layer; a second wire layer forming step, the wire winding machine is wound around the fourth magnetic pole pin of the body with a wire end of the same wire, and then wound around the first pole arm of the body in a first direction, and then a second direction arm of the body is wound in a second direction opposite to the second direction arm, and then wound around the third pole arm of the body in a first direction, and then wound around the fourth pole arm of the body in a second direction, and then wound on the body Three magnetic poles are cut and cut to form a second wire a step of forming a third wire layer, the wire winding machine is wound around the second magnetic pole pin of the body with a wire end of the same wire, and is connected in series with the wire tail of the first wire layer, and then the wire is wound around the body in a first direction a first pole arm, which is wound around the second pole arm of the body in a second direction opposite to the first direction, and then wound around the third pole arm of the body in a first direction, and then wound around the body in a second direction The quadrupole arm is further wound around the fourth magnetic pole pin of the body and cut to form a third wire layer, and the sum of the line length of the first wire layer and the line length of the third wire layer is equal to the line of the second wire layer long. The winding method of the composite two-wire stator according to claim 3, wherein the line length of the first wire layer is 2/3 times longer than the line length of the second wire layer, and the wire length of the third wire layer is second. The wire layer is 1/3 times longer than the wire length.