TWI392197B - Stator winding method - Google Patents

Description

Stator winding and wire bonding method (2)

The present invention relates to a stator winding and wire bonding method, and more particularly to a stator winding and wire bonding method for a single wire.

The conventional single-phase brushless fan stator design needs to accommodate a plurality of mutually stacked silicon steel sheets and coils wound around the silicon steel plate pole arms in a limited space, in order to improve the rotation efficiency and avoid stacking the silicon steel sheets stacked on each other. The thickness is saturated, which will widen each of the pole arms, but also causes a reduction in the winding space between the pole arms, and because the winding space is reduced, a thin copper wire is also required for winding.
Invented the invention patent No. I282654 in Taiwan, exposing a winding of a plurality of pole arms together with a double-stranded wire, but since the two wires are sequentially wound on the adjacent pole arms, the wires are not easily aligned and the two wires are It is easy to rub against each other to break the insulation layer on the surface of the wire, so that the motor is short-circuited.

The main object of the present invention is to provide a stator winding and wire bonding method, which comprises providing a stator having a certain sub-body, a first pole arm, a second pole arm, a third pole arm, and a fourth a pole arm, a fifth pole arm and a sixth pole arm, the stator system has an outer ring wall, the first pole arm, the second pole arm, the third pole arm, the fourth pole arm, the The fifth pole arm and the sixth pole arm are sequentially formed on the outer ring wall of the stator body; a wire is provided, the wire has an incoming end; the wire is wound around the first direction in the first direction a pole arm; the wire is wound around the third pole arm in the first direction and forms a first common contact; the wire is wound around the second pole arm in the first direction; a first direction is disposed on the sixth pole arm and forms a second common contact; the wire is wound around the fifth pole in the first direction; and the wire is wound in the second direction a quadrupole arm; cutting the wire to form the wire with an outlet end; and connecting the wire end of the wire to the second common contact To form a first power supply terminal, the conductor of the first line terminal and the common terminal joined to form a second power supply terminal. Since the present invention utilizes a single wire to wind the poles of the stator in different directions and has the effect of paralleling the coils, the utilization of the winding space is improved and the rotor is smoothly operated.

Referring to FIG. 1 , a method for winding and connecting a stator according to a preferred embodiment of the present invention includes the following steps: First, a stator 100 is provided, which has a certain sub-body 110 and a first pole. An arm 120, a second pole arm 130, a third pole arm 140, a fourth pole arm 150, a fifth pole arm 160 and a sixth pole arm 170. The stator body 110 has an outer ring wall 111 and The stator body upper surface 112, the first pole arm 120, the second pole arm 130, the third pole arm 140, the fourth pole arm 150, the fifth pole arm 160, and the sixth pole arm 170 are compliant Formed on the outer ring wall 111 of the stator body 110, wherein the first pole arm 120, the second pole arm 130, the third pole arm 140 are sequentially facing the stator body upper surface 112 in a clockwise direction. The fourth pole arm 150, the fifth pole arm 160 and the sixth pole arm 170, and each of the pole arms 120, 130, 140, 150, 160, 170 has an outer side surface 123, 133, 143, 153, 163 , 173.
Next, a wire 200 is provided, and the first pole arm 120, the third pole arm 140, the second pole arm 130, the sixth pole arm 170, and the fifth pole arm 160 are sequentially wound around the wire 200. In the present embodiment, the wire 200 is wound around the poles 120, 130, 140, 150, 160, 170 from the outer side of the stator 100 to the pole arms 120, 130, 140. Each of the outer sides 123, 133, 143, 153, 163, 173 of 150, 160, 170, including a first direction and a second direction, the first direction and the second direction being opposite directions, the wire The 200 series has an incoming end 210. In this embodiment, the incoming end 210 of the wire 200 is located between the first pole arm 120 and the second pole arm 130.
1 and 2, the wire 200 is wound from the first direction to the first pole arm 120. The first pole arm 120 has a first upper surface 121 and a first lower surface 122. In the first embodiment, the first outer surface 123 is in a counterclockwise direction, and the wire 200 is wound from the first lower surface 122 to the first upper surface 121.
Next, referring to FIGS. 1 and 2, the wire 200 is wound around the third pole arm 140 in the first direction to form a first common contact A1, and the third pole arm 140 has a third The upper surface 141 and the third lower surface 142 and the third outer surface 143 are formed between the second pole arm 130 and the third pole arm 140 in this embodiment. The wire 200 is wound from the first direction to the third pole arm 140. In the embodiment, the first direction is a counterclockwise direction, and the wire 200 is the third upper surface 141. The lower surface 142 is wound around the surface.
Then, referring to FIGS. 1 and 2, the wire 200 is wound from the first direction to the second pole arm 130. The second pole arm 130 has a second upper surface 131 and a second lower surface 132. And the second outer side 133, the wire 200 is wound around the second pole arm 130 by the first direction. In the embodiment, the first direction is a counterclockwise direction, and the wire 200 is The second lower surface 132 is wound around the second upper surface 131.
After that, please refer to FIGS. 1 and 2 again, in which the wire 200 is wound from the first direction to the sixth pole arm 170 and form a second common contact A2. The sixth pole arm 170 has a sixth upper portion. The surface 171, the sixth lower surface 172 and the sixth outer surface 173 are wound around the sixth pole arm 170 in the first direction. In this embodiment, the first direction is counterclockwise. In the direction, the wire 200 is wound from the sixth lower surface 172 to the sixth upper surface 171, and the second common contact A2 is formed between the sixth pole 170 and the fifth pole 160.
Then, referring to FIGS. 1 and 2, the wire 200 is wound from the first direction to the fifth pole arm 160. The fifth pole arm 160 has a fifth upper surface 161 and a fifth lower surface 162. And the fifth outer side 163, the wire 200 is wound around the fifth pole arm 160 in the first direction. In the embodiment, the first direction is a counterclockwise direction, and the wire 200 is The fifth lower surface 162 is wound around the fifth upper surface 161.
After that, please refer to the first and second figures, wherein the wire 200 is wound from the second direction to the fourth pole arm 150. The fourth pole arm 150 has a fourth upper surface 151 and a fourth lower surface 152. And the fourth outer side 153, the wire 200 is wound around the fourth pole arm 150 by the second direction. In the embodiment, the second direction is a clockwise direction, and the wire 200 is composed of the first The fourth upper surface 151 is wound around the fourth lower surface 152.
Then, the wire 200 is cut so that the wire 200 is formed with a wire end 220. In the embodiment, the wire end 220 of the wire 200 is located between the third pole arm 140 and the fourth pole arm 150. between.
Finally, the wire end 210 of the wire 200 is joined to the second common contact A2 to form a first power terminal, and the wire end 220 of the wire 200 is joined to the first common contact A1 to form a The second power terminal. Since the present invention utilizes a single wire 200, the first pole arm 120, the second pole arm 130, the third pole arm 140, the fourth pole arm 150, the fifth pole arm 160, and the first portion of the stator 100 The hexapole arm 170 is wound and has the effect of parallel connection, thereby increasing the utilization rate of the winding space and achieving the purpose of improving the efficiency of operation of the rotor.
The scope of the present invention is defined by the scope of the appended claims, and any changes and modifications made by those skilled in the art without departing from the spirit and scope of the invention are within the scope of the present invention. .

100‧‧‧ Stator
110‧‧‧stat body
111‧‧‧ outer ring wall
112‧‧‧The upper surface of the stator body
120‧‧‧First polar arm
121‧‧‧First upper surface
122‧‧‧First lower surface
123‧‧‧First outer side
130‧‧‧second pole arm
131‧‧‧Second upper surface
132‧‧‧Second lower surface
133‧‧‧Second outer side
140‧‧‧third pole arm
141‧‧‧ third upper surface
142‧‧‧ Third lower surface
143‧‧‧ third outer side
150‧‧‧ fourth pole arm
151‧‧‧ fourth upper surface
152‧‧‧ Fourth lower surface
153‧‧‧fourth outer side
160‧‧‧ fifth pole arm
161‧‧‧ fifth upper surface
162‧‧‧ fifth lower surface
163‧‧‧ fifth outer side
170‧‧‧ sixth pole arm
171‧‧‧ sixth upper surface
172‧‧‧ sixth lower surface
173‧‧‧6th outer side
200‧‧‧ wire
210‧‧‧Incoming end
220‧‧‧ outlet
A1‧‧‧ first joint
A2‧‧‧ second joint

1 is a schematic view showing a method of winding and connecting a stator according to a preferred embodiment of the present invention.
2 is a schematic view showing another method of winding and connecting a stator according to a preferred embodiment of the present invention.

100‧‧‧ Stator

110‧‧‧stat body

111‧‧‧ outer ring wall

112‧‧‧The upper surface of the stator body

120‧‧‧First polar arm

121‧‧‧First upper surface

122‧‧‧First lower surface

123‧‧‧First outer side

130‧‧‧second pole arm

131‧‧‧Second upper surface

132‧‧‧Second lower surface

133‧‧‧Second outer side

140‧‧‧third pole arm

141‧‧‧ third upper surface

142‧‧‧ Third lower surface

143‧‧‧ third outer side

150‧‧‧ fourth pole arm

151‧‧‧ fourth upper surface

152‧‧‧ Fourth lower surface

153‧‧‧fourth outer side

160‧‧‧ fifth pole arm

161‧‧‧ fifth upper surface

162‧‧‧ fifth lower surface

163‧‧‧ fifth outer side

170‧‧‧ sixth pole arm

171‧‧‧ sixth upper surface

172‧‧‧ sixth lower surface

173‧‧‧6th outer side

200‧‧‧ wire

210‧‧‧Incoming end

220‧‧‧ outlet

A1‧‧‧ first joint

A2‧‧‧ second joint

Claims (14)

A stator winding and wire bonding method, comprising at least:
Providing a stator having a certain sub-body, a first pole arm, a second pole arm, a third pole arm, a fourth pole arm, a fifth pole arm and a sixth pole arm, the stator The system has an outer ring wall, and the first pole arm, the second pole arm, the third pole arm, the fourth pole arm, the fifth pole arm and the sixth pole arm are sequentially formed on the stator body The outer ring wall;
Providing a wire, the first pole arm, the third pole arm, the second pole arm, the sixth pole arm, the fifth pole arm, and the fourth pole arm are sequentially wound around the wire Have an incoming end;
The wire is wound from the first direction to the first pole arm;
The wire is wound from the first direction to the third pole arm and forms a first common contact;
The wire is wound from the first direction to the second pole arm;
The wire is wound from the first direction to the sixth pole arm and forms a second common contact;
The wire is wound from the first direction to the fifth pole arm;
The wire is wound from the second direction to the fourth pole arm;
Cutting the wire such that the wire forms a wire end; and engaging the wire end of the wire with the second common contact to form a first power terminal, the wire end of the wire and the first wire The common contacts are joined to form a second power terminal.
The stator winding and wire bonding method according to claim 1, wherein the stator system has a certain upper surface of the sub-body, and the first pole is oriented in a clockwise direction facing the upper surface of the stator body. a diode arm, the third pole arm, the fourth pole arm, the fifth pole arm, and the sixth pole arm.
The stator winding and wire bonding method according to claim 1, wherein the first direction and the second direction are opposite directions.
The stator winding and wire bonding method of claim 1, wherein the first direction is a counterclockwise direction and the second direction is a clockwise direction.
The method of claim 1 or 2, wherein the first pole arm has a first upper surface and a first lower surface, the wire is from the first lower surface to the first The upper surface is wound around.
The method of claim 2, wherein the second pole arm has a second upper surface and a second lower surface, the wire is from the second lower surface to the second The upper surface is wound around.
The stator winding and wire bonding method of claim 1, wherein the third pole arm has a third upper surface and a third lower surface, the wire is from the third upper surface to the third The lower surface is wound around.
The stator winding and wire bonding method of claim 1, wherein the fourth pole arm has a fourth upper surface and a fourth lower surface, the wire is from the fourth upper surface to the fourth The lower surface is wound around.
The stator winding and wire bonding method according to claim 1, wherein the fifth pole arm has a fifth upper surface and a fifth lower surface, and the wire is from the fifth lower surface to the fifth The upper surface is wound around.
The stator winding and wire bonding method of claim 1, wherein the sixth pole arm has a sixth upper surface and a sixth lower surface, and the wire is from the sixth lower surface to the sixth The upper surface is wound around.
The stator winding and wire bonding method of claim 1, wherein the wire end of the wire is located between the first pole arm and the second pole arm.
The stator winding and wire bonding method of claim 1, wherein the wire end of the wire is located between the third pole arm and the fourth pole arm.
The stator winding and wire bonding method of claim 1, wherein the first common contact is formed between the second pole arm and the third pole arm.
The stator winding and wire bonding method according to claim 1, wherein the second common contact is formed between the sixth pole arm and the fifth pole arm.