DE20106991U1 - Stator structure for a brushless DC motor - Google Patents

Description

B/42.152/40-RL

Sunonwealth Electric Machine Industry Co.. Ltd.

12F-1, No. 120. Chung-Cheng ^1st Road. Kaohsiung. Taiwan/RoC .

Stator structure for a brushless DC motor

The present invention relates to a stator structure for a brushless DC motor, and more particularly to a stator structure for a brushless DC motor in which the reluctance is reduced and the conduction of magnetic flux is increased so that the torque is increased.

In Figures 1 and 2, a conventional stator structure is shown which comprises a shaft tube 901 equipped with an upper pole plate 902, a coil seat 903 and a lower pole plate 904. The coils of the coil seat 903 are excited to generate a magnetic field, whereby the magnetic lines of force run through the shaft tube 901, the upper pole plate 902 and the lower pole plate 904, whereby the front edges of the upper pole plate 902 and the lower pole plate 904 are inductively acted upon by the annular permanent magnet of the rotor, so that the rotor can be driven to rotate. In such a conventional stator structure, the thickness of the front edges of the upper pole plate 902 and the lower pole plate 904 creates an induction surface which is inductively acted upon by the annular permanent magnet of the

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Rotors interact inductively. Due to the small induction area, not enough torque is transmitted, so that the rotation speed is not stable.

Another conventional stator structure is shown in Figures 3 and 4 and has a shaft tube 911 provided with an upper pole plate 912, a coil seat 913 and a lower pole plate 914. The upper pole plate 912 and the lower pole plate 914 each have bent side walls 915, 916 extending toward the coil seat 913. In such a conventional stator structure, a larger induction area is formed by the side walls 915, 916 of the upper pole plate 912 and the lower pole plate 914, which inductively interacts with the annular permanent magnet of the rotor. The upper and lower pole plates are each formed by bending a silicon steel plate having a uniform thickness. Therefore, the induction area is increased by the side walls 915, 916, but the thickness of the cross section of the magnetically conductive passage of the upper and lower pole plates is not increased. Therefore, the torque is insufficient and the rotation speed is unstable, causing a rotation problem.

The primary object of the present invention is to provide a stator structure for a brushless DC motor in which a better magnetic conduction effect is achieved, thereby increasing the torque of the motor.

According to the present invention, a stator structure is provided for a brushless DC motor, which has a coil seat wound with coils and is provided with a mounting hole through which the magnetically conductive tube passes. An upper pole plate is arranged above the coil seat and a lower pole plate is arranged below the coil seat. The upper pole plate and the lower pole plate are each provided with pole ends. At least one upper magnetically conductive plate and one lower

Magnetically conductive plates are bonded to the upper pole plate and the lower pole plate, respectively. The upper pole plate, the lower pole plate, the upper magnetically conductive plate, and the lower magnetically conductive plate each have a positioning hole through which the magnetically conductive tube passes. Vertically extending side walls are formed on at least the pole ends of the upper pole plate, the lower pole plate, or an upper magnetically conductive plate or a lower magnetically conductive plate.

Further advantages and features of the present invention will become apparent from the following description of preferred embodiments, which is based on the accompanying drawings. In the drawing:

Figure 1 is an exploded perspective view of a conventional stator structure

according to the state of the art,

Figure 2 is a cross-sectional view of the conventional

Stator structure,

Figure 3 is an exploded perspective view of another conventional

Stator construction according to the state of the art,

Figure 4 is a cross-sectional view of the conventional

Stator structure,

Figure 5 is an exploded perspective view of a stator structure for a

brushless DC motor according to a first embodiment of the present invention,

Figure 6 is a cross-sectional view of the stator structure shown in Figure 5 for a brushless DC motor,

Figure 7 is an exploded perspective view of a stator assembly for

a brushless DC motor according to a second
Embodiment of the present invention,

Figure 8 is a cross-sectional view of the stator structure shown in Figure 7 for

a brushless DC motor,

Figure 9 is an exploded perspective view of a stator structure for a

brushless DC motor according to a third embodiment of the present invention,

Figure 10 is a cross-sectional view of the stator structure shown in Figure 9 for a brushless DC motor, and

Figure 11' is another cross-sectional view of the stator structure shown in Figure 9 for a brushless DC motor.

Reference is made to the drawing and initially to Figure 5. A stator structure for a brushless DC motor according to a first preferred
Embodiment of the present invention has a coil seat 10, an upper pole plate 11, a lower pole plate 12, upper magnetically conductive plates 13 and lower magnetically conductive plates 14.

The coil seat 10 can be a coil seat for a conventional brushless
DC motor, a conventional heat dissipation fan, etc., where the

Coil seat 10 is wound with coils 101 and is provided with a mounting hole 102 which enables a combination with the upper pole plate 11 and the lower pole plate 12.

The upper pole plate 11 is made of a magnetically conductive material and is provided with pole ends 111 and a magnetically conductive tube 112 which extends into the mounting hole 102 of the coil seat 10, thereby forming a magnetically conductive passage. A bearing which allows the rotation of a central shaft of a rotor can be housed in the magnetically conductive tube 112.

The lower pole plate 12 is made of a magnetically conductive material and is provided with pole ends 121 and a magnetic conducting tube 122 which extends into the mounting hole 102 of the coil seat 10, thereby forming a magnetically conductive passage. A bearing which allows rotation of the central shaft of the rotor can be accommodated in the magnetically conductive tube 122.

The upper magnetically conductive plate 13 is made of a magnetically conductive material and is secured between the upper pole plate 11 and the coil seat 10. The present invention has at least one upper magnetically conductive plate 13. The upper magnetically conductive plate 13 has pole ends 131 and a positioning hole 132 that allows passage and connection of the magnetically conductive tube 112 of the upper pole plate 11. In the preferred embodiment, the magnetically conductive tube 112 of the upper pole plate 11 has an outer diameter that is larger than the diameter of the positioning hole 132 of the upper magnetically conductive plate 13 so that the magnetically conductive tube 112 can be inserted in a tight, snug manner. In addition, the pole ends 131 of the at least one upper magnetically conductive plate 13 are provided with side walls 133 extending away in the vertical direction. The side walls 133 of the upper magnetically conductive

Plate 13 extend toward or away from the spool seat 10. As shown in the figure, the side walls 133 extend toward the spool seat 10.

The lower magnetically conductive plate 14 is made of a magnetically conductive material and is secured between the lower pole plate 12 and the coil seat 10. The present invention has at least one lower magnetically conductive plate 14. The lower magnetically conductive plate 14 has pole ends 141 and a positioning hole 142 that allows passage and connection with the magnetically conductive tube 122 of the lower pole plate 12. In the preferred embodiment, the magnetically conductive tube 122 of the lower pole plate 12 has an outer diameter that is larger than the diameter of the positioning hole 142 of the lower magnetically conductive plate so that the magnetically conductive tube 122 can be connected in a tight, snug manner. In addition, the pole ends 141 of the at least one lower magnetically conductive plate 14 are provided with side walls 143 extending in the vertical direction. The side walls 143 of the lower magnetically conductive plate 14 extend toward or away from the coil seat 10. As shown in the figure, the side walls 143 extend toward the coil seat 10.

In Figure 6, the stator structure for a brushless DC motor according to the first preferred embodiment of the present invention is assembled. After the magnetically conductive tubes 112, 122 of the upper pole plate 11 and the lower pole plate 12 are linked to the upper magnetically conductive plate 13 and the lower magnetically conductive plate 14, the magnetically conductive tubes 112, 122 are also linked in the mounting hole 102 of the coil seat 10 and contact each other so that the magnetically conductive tubes 112, 122 have a conducting effect transmitting the magnetic force, the upper pole plate 11 and the lower pole plate 12 together with the corresponding upper magnetically conductive plate and the corresponding lower magnetically conductive plate 14 form a further

can form a passage for the magnetic force. Thus, the upper pole plate 11 and the upper magnetically conductive plate 13 are stacked on the upper surface of the coil seat 10, while the lower pole plate 12 and the lower magnetically conductive plate 14 are stacked on the lower surface of the coil seat 10, with the side walls 133 projecting from the upper magnetically conductive plate 13 and the side walls 143 projecting from the lower magnetically conductive plate 14, thereby forming a larger sensing area and achieving a better magnetic conduction effect. Therefore, when the ring-shaped permanent magnet of the rotor inductively interacts therewith, the rotor can have a larger torque, thereby ensuring more stable rotation.

In Figure 7, a stator structure for a brushless DC motor according to a second preferred embodiment of the present invention is shown. It has a coil seat 20, an upper pole plate 21, a lower pole plate 22, upper magnetically conductive plates 23 and lower magnetically conductive plates 24.

In the preferred embodiment, the upper pole plate 21 is provided with pole ends 211 and a magnetically conductive tube 212, and the magnetically conductive tube 212 of the upper pole plate 21 passes through the positioning holes 232, 242, 222 of the upper magnetically conductive plate 23, the lower magnetically conductive plate 24 and the lower pole plate 22 and through the mounting hole 202 of the coil seat 20. The magnetically conductive tube 212 can form a magnetic conduction passage and accommodate therein a bearing that allows rotation of the central shaft of the rotor.

The lower pole plate 22 is provided with pole ends 221 and a positioning hole 222 which enables connection to the magnetically conductive tube 212. In the preferred embodiment, the magnetically conductive tube 212 of the upper pole plate 21 has an outer diameter which is larger than the diameter of the

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positioning hole 222 of the lower pole plate 22 so that the magnetically conductive tube 212 can be coupled in a firm, tight-fitting manner.

The present invention may include at least one upper magnetically conductive plate 23 and at least one lower magnetically conductive plate 24. The upper magnetically conductive plate 23 has pole ends 231 and a positioning hole 232, and the lower magnetically conductive plate 24 has pole ends 241 and a positioning hole 242. The pole ends 231 of the at least one upper magnetically conductive plate 23 are provided with side walls 233 extending in the vertical direction, and the pole ends 241 of the at least one lower magnetically conductive plate 24 are provided with side walls 243 extending in the vertical direction. The side walls 233, 243 may extend toward or away from the coil seat 20, respectively. In the figure, the side walls 233, 243 extend away from the coil seat 20, respectively.

In Figure 8, the stator structure for a brushless DC motor according to the second preferred embodiment of the present invention is shown in an assembled state. The magnetically conductive tube 212 of the upper pole plate 21 passes through the positioning holes 232, 242, 222 of the upper magnetically conductive plate 23, the lower magnetically conductive plate 24 and the lower pole plate 22 and through the mounting hole 202 of the coil seat 20. The arrangement of the magnetically conductive tube 212 of the upper pole plate 21 and the lower pole plate 22 passing through the lower magnetically conductive plate 24 is not limited as shown in the figure. The lower pole plate 22 may also be embedded between the lower magnetically conductive plate 24 and the coil seat 20. Thus, the magnetically conductive tube 212 has a conduction effect for the magnetic force, whereby the upper pole plate 21 and the lower pole plate 22 together with the corresponding upper magnetically conductive plate 23 and the lower magnetically conductive plate 24 provide a further passage for the magnetic force

Thus, the upper pole plate 21 and the upper magnetically conductive plate 23 are stacked on the top of the coil seat 20, while the lower pole plate 22 and the lower magnetically conductive plate 24 are stacked on the bottom of the coil seat 20, with the side walls 233 projecting from the upper magnetically conductive plate 23 and the side walls 243 projecting from the lower magnetically conductive plate 24, thereby forming a larger sensing area and providing a better magnetic conduction effect. Therefore, when the ring-shaped permanent magnet of the rotor inductively interacts therewith, the rotor can have a larger torque, thereby achieving more stable rotation.

In Figure 9, there is shown a stator structure for a brushless DC motor according to a third preferred embodiment of the present invention, which has a coil seat 30, an upper pole plate 31, a lower pole plate 32, an upper magnetically conductive plate 33, a lower magnetically conductive plate 34 and a magnetically conductive tube 35.

In the preferred embodiment, the coil seat 30 is wound with coils 301 and provided with a mounting hole 302 in which the magnetically conductive tube 35 is fastened.

The upper pole plate 31 is made of a magnetically conductive material and has pole ends 311 and a positioning hole 312 that allows passage and connection to the magnetically conductive tube 35. In the preferred embodiment, the magnetically conductive tube 35 has an outer diameter that is larger than the diameter of the positioning hole 312 so that connection in the magnetically conductive tube 35 is possible in a tight, tight-fitting manner. The pole ends 311 of the upper pole plate 31 are aligned with each other in the vertical direction.

extending side walls 313 which can extend towards or away from the coil seat 30.

The lower pole plate 32 is made of a magnetically conductive material and has pole ends 321 and a positioning hole 322 that allows passage and engagement with the magnetically conductive tube 35. In the preferred embodiment, the magnetically conductive tube 35 has an outer diameter that is larger than the diameter of the positioning hole 322 so that the magnetically conductive tube 35 can be engaged in a tight, snug manner. The pole ends 321 of the lower pole plate 32 are provided with vertically extending side walls 322 that can extend toward or away from the coil seat 30.

The upper magnetically conductive plate 33 is made of a magnetically conductive material and may be fixed on the other side of the upper pole plate 31, one side of which is connected to the coil seat 30 as shown in Figures 9 and 10, or fixed between the upper pole plate 31 and the coil seat 30 as shown in Figure 11, or may be simultaneously fixed between the upper pole plate 31 and the coil seat 30 and arranged on the other side of the upper pole plate 31, one side of which is connected to the coil seat 30. The present invention has at least one upper magnetically conductive plate 33 having pole ends 331 and a positioning hole 332 allowing connection to the magnetically conductive tube 35. In the preferred embodiment, the magnetically conductive tube 35 has an outer diameter that is larger than the diameter of the positioning hole 332 of the upper pole plate 33 so that it can be coupled to the magnetically conductive tube 35 in a firm, tight-fitting manner.

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The lower magnetically conductive plate 34 is made of a magnetically conductive material and can be arranged on the other side of the lower pole plate 32, one side of which is connected to the coil seat 30 as shown in Figures 9 and 10, or fixed between the lower pole plate 32 and the coil seat 30 as shown in Figure 11, or simultaneously fixed between the lower pole plate 32 and the coil seat 30 and arranged on the other side of the lower pole plate 32, one side of which is connected to the coil seat 30. The present invention has at least one lower magnetically conductive plate 34 with pole ends 341 and a positioning hole 342 that allows connection to the magnetically conductive tube 35. In the preferred embodiment, the magnetically conductive tube 35 has an outer diameter that is larger than the diameter of the positioning hole 342 of the lower pole plate 34 so that it can be coupled to the magnetically conductive tube 35 in a tight, snug manner.

The magnetically conductive tube 35 is made of a magnetically conductive material and can pass through the positioning holes 312, 322, 332, 342 of the upper pole plate 31, the lower pole plate 32, the upper magnetically conductive plate 33 and the lower magnetically conductive plate 34 and through the mounting hole 302 of the coil seat 30. In the preferred embodiment, the diameter of the magnetically conductive tube 35 is slightly larger than the diameter of the positioning holes 312, 322, 332, 342 so that it can be coupled to the magnetically conductive tube 35 in a tight, snug manner. In addition, the magnetically conductive tube 35 is provided with an annular lip 351 to prevent these parts from becoming loose. The magnetically conductive tube 35 can form a magnetically conductive passage and can accommodate a bearing therein to allow rotation of the central shaft of the rotor.

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In Figure 10, the stator structure for a brushless DC motor according to the third preferred embodiment of the present invention is shown in its assembled state. The magnetically conductive tube 35 passes through the upper pole plate 31, the lower pole plate 32, the upper magnetically conductive plate 33, the lower magnetically conductive plate 34 and the coil seat 30. Thus, the magnetically conductive tube 35 has a conduction effect for the magnetic force, whereby the upper pole plate 31 and the lower pole plate 32 together with the corresponding upper magnetically conductive plate 33 and the lower magnetically conductive plate 34 can form a further, i.e. larger, passage for the magnetic force. Thus, the upper pole plate 31 and the upper magnetically conductive plate 33 are stacked on the top of the coil seat 30, while the lower pole plate 32 and the lower magnetically conductive plate 34 are stacked on the bottom of the coil seat 30, with side walls 313 extending from the upper pole plate 31 and side walls 323 extending from the lower pole plate 32, thereby forming a larger sensing area and achieving a better magnetic conduction effect. Therefore, when the ring-shaped permanent magnet of the rotor inductively interacts therewith, the rotor can have a larger torque, thereby achieving a more stable rotation.

Having said all, the stator structure for a brushless DC motor according to the present invention has at least one upper magnetically conductive plate and at least one lower magnetically conductive plate which are superimposed on each other and can be fixed on the upper pole plate and the lower pole plate, respectively. Thus, the protruding side walls and the annular permanent magnet of the rotor will have a larger sensing area, and the upper magnetically conductive plate and upper pole plate which are superimposed on each other and the lower magnetically conductive plate and lower pole plate which are superimposed on each other will increase the passage for the magnetic force. Therefore, the rotor can transmit a better torque and can be used in the

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Rotation should not be subject to fluctuation, thus achieving a more stable rotation.

Although the invention has been described above in terms of its preferred embodiments, it will be understood that numerous modifications and variations are possible without departing from the basic spirit of the invention. The appended claims are intended to cover such modifications and variations as fall within the spirit of the invention.

Claims (22)

1. Stator structure for a brushless DC motor, with:
a coil seat ( 10 ) wound with coils ( 101 ) and provided with a mounting hole ( 102 ),
an upper pole plate ( 11 ) arranged above the coil seat ( 10 ) with pole ends ( 111 ) and a magnetic conductive tube ( 112 ),
a lower pole plate ( 12 ) arranged below the coil seat ( 10 ) with pole ends ( 121 ) and a magnetically conductive tube ( 122 ),
at least one upper magnetically conductive plate ( 13 ) with pole ends ( 131 ) and a positioning hole ( 132 ) through which the magnetically conductive tube ( 112 ) of the upper pole plate ( 11 ) can be passed, wherein the pole ends ( 131 ) of the at least one upper magnetically conductive plate ( 13 ) are provided with side walls ( 133 ) extending in the vertical direction, and
at least one lower magnetically conductive plate ( 14 ) with pole ends ( 141 ) and a positioning hole ( 142 ) through which the magnetically conductive tube ( 122 ) of the lower pole plate ( 12 ) can be passed, wherein the pole ends ( 141 ) of the at least one lower magnetically conductive plate ( 14 ) are provided with side walls ( 143 ) extending in the vertical direction,
wherein the magnetically conductive tubes ( 112 ) of the upper pole plate ( 11 ) and the lower pole plate ( 12 ) pass through the upper magnetically conductive plate ( 13 ) and the lower magnetically conductive plate ( 14 ) and are then connected to the mounting hole ( 132 ) of the coil seat ( 10 ). 2. A stator structure for a brushless DC motor according to claim 1, wherein the side walls ( 133 ) of the upper magnetically conductive plate ( 13 ) extend toward or away from the coil seat ( 10 ). 3. A stator structure for a brushless DC motor according to claim 1, wherein the side walls ( 133 ) of the lower magnetically conductive plate ( 14 ) extend toward or away from the coil seat ( 10 ). 4. A stator structure for a brushless DC motor according to claim 1, wherein the magnetically conductive tubes ( 112 ) of the upper pole plate ( 11 ) and the lower pole plate ( 12 ) each have an outer diameter larger than the diameter of the positioning holes ( 132 and 142 ) of the upper magnetically conductive plate ( 13 ) and the lower magnetically conductive plate ( 14 ) so that they can be coupled to the magnetically conductive tubes ( 12 ) in a firm, tight-fitting manner. 5. Stator structure for a brushless DC motor, with:
a coil seat ( 20 ) wound with coils ( 201 ) and provided with a mounting hole,
an upper pole plate ( 21 ) arranged above the coil seat ( 20 ) with pole ends ( 211 ) and a magnetically conductive tube ( 212 ),
a lower pole plate ( 22 ) arranged below the coil seat ( 20 ) with pole ends ( 221 ) and a positioning hole ( 222 ),
at least one upper magnetically conductive plate ( 23 ) with pole ends ( 231 ) and a positioning hole ( 232 ), wherein the pole ends of the at least one upper magnetically conductive plate ( 23 ) are provided with side walls ( 233 ) extending in the vertical direction, and
at least one lower magnetically conductive plate ( 24 ) with pole ends ( 241 ) and a positioning hole ( 242 ), wherein the pole ends of the at least one lower magnetically conductive plate ( 24 ) are provided with side walls ( 243 ) extending in the vertical direction, and
wherein the magnetically conductive tube ( 212 ) of the upper pole plate ( 21 ) passes through the positioning holes ( 232 , 242 and 222 ) of the upper magnetically conductive plate ( 23 ), the lower magnetically conductive plate ( 23 ) and the lower pole plate ( 24 ) and through the mounting hole ( 202 ) of the coil seat ( 20 ). 6. A stator structure for a brushless DC motor according to claim 5, wherein the side walls ( 233 ) of the upper magnetically conductive plate ( 23 ) extend toward or away from the coil seat ( 20 ). 7. A stator structure for a brushless DC motor according to claim 5, wherein the side walls ( 243 ) of the lower magnetically conductive plate ( 24 ) extend toward or away from the coil seat ( 20 ). 8. A stator structure for a brushless DC motor according to claim 5, wherein the magnetically conductive tube ( 212 ) of the upper pole plate ( 21 ) has an outer diameter larger than the diameter of the positioning holes ( 232 and 242 ) of the upper magnetically conductive plate ( 23 ) and the lower magnetically conductive plate ( 24 ) so that it can be coupled to the magnetically conductive tube ( 212 ) in a firm, tight-fitting manner. 9. A stator structure for a brushless DC motor according to claim 5, wherein the upper magnetically conductive plate ( 23 ) is fixed between the upper pole plate ( 21 ) and the coil seat ( 20 ). 10. A stator structure for a brushless DC motor according to claim 5, wherein the lower magnetically conductive plate ( 24 ) is bonded on the other side of the lower pole plate ( 22 ), one side of which is bonded to the coil seat ( 20 ). 11. A stator structure for a brushless DC motor according to claim 5, wherein the lower magnetically conductive plate ( 24 ) is fixed between the lower pole plate ( 22 ) and the coil seat ( 20 ). 12. A stator structure for a brushless DC motor according to claim 5, wherein the lower magnetically conductive plate ( 24 ) can be simultaneously fixed between the lower pole plate ( 22 ) and the coil seat ( 20 ) and can be bonded on the other side of the lower pole plate ( 22 ), one side of which is bonded on the coil seat ( 20 ). 13. Stator structure for a brushless DC motor, with:
a coil seat ( 30 ) wound with coils ( 301 ) and provided with a mounting hole ( 302 ),
an upper pole plate ( 31) arranged above the coil seat (30 ) with pole ends ( 311 ) and a positioning hole ( 312 ), wherein the pole ends ( 311 ) of the upper pole plate ( 31 ) are provided with side walls ( 313 ) extending in the vertical direction,
a lower pole plate ( 32) arranged below the coil seat (30 ) with pole ends ( 321 ) and a positioning hole ( 322 ), wherein the pole ends ( 321 ) of the lower pole plate ( 32 ) are provided with side walls ( 323 ) extending in the vertical direction,
at least one upper magnetically conductive plate ( 33 ) with pole ends ( 331 ) and a positioning hole ( 332 ), and
at least one lower magnetically conductive plate ( 34 ) with pole ends ( 341 ) and a positioning hole ( 342 ),
wherein a magnetic conducting tube ( 35 ) passes through the positioning holes ( 312 , 323 , 332 and 342 ) of the upper pole plate ( 31 ), the lower pole plate ( 32 ), the upper magnetically conductive plate ( 33 ) and the lower magnetically conductive plate ( 34 ) and through the mounting hole of the coil seat ( 30 ). 14. A stator structure for a brushless DC motor according to claim 13, wherein the side walls ( 313 ) of the upper pole plate ( 31 ) extend toward or away from the coil seat ( 30 ). 15. A stator structure for a brushless DC motor according to claim 13, wherein the side walls ( 323 ) of the lower pole plate ( 32 ) extend toward or away from the coil seat ( 30 ). 16. A stator structure for a brushless DC motor according to claim 13, wherein the magnetically conductive tube ( 35 ) has an outer diameter larger than the diameter of the positioning holes ( 312 , 322 , 332 and 342 ) of the upper pole plate ( 31 ), the lower pole plate ( 32 ), the upper magnetically conductive plate ( 33 ) and the lower magnetically conductive plate ( 34 ) so that it can be coupled to the magnetically conductive tube ( 35 ) in a firm, tight-fitting manner. 17. A stator structure for a brushless DC motor according to claim 13, wherein the upper magnetically conductive plate ( 33 ) is arranged on the other side of the upper pole plate ( 31 ), one side of which is connected to the coil seat ( 30 ). 18. A stator structure for a brushless DC motor according to claim 13, wherein the upper magnetically conductive plate ( 33 ) is fixed between the upper pole plate ( 31 ) and the coil seat ( 30 ). 19. A stator structure for a brushless DC motor according to claim 13, wherein the upper magnetically conductive plate ( 33 ) is simultaneously fixed between the upper pole plate ( 31 ) and the coil seat ( 30 ) and is arranged on the other side of the upper pole plate ( 31 ) with one side connected to the coil seat ( 30 ). 20. A stator structure for a brushless DC motor according to claim 13, wherein the lower magnetically conductive plate ( 34 ) is mounted on the other side of the lower pole plate, one side of which is connected to the coil seat ( 30 ). 21. A stator structure for a brushless DC motor according to claim 13, wherein the lower magnetically conductive plate ( 34 ) is fixed between the lower pole plate ( 32 ) and the coil seat ( 30 ). 22. A stator structure for a brushless DC motor according to claim 13, wherein the lower magnetically conductive plate ( 34 ) is simultaneously fixed between the lower pole plate ( 32 ) and the coil seat ( 30 ) and is arranged on the other side of the lower pole plate ( 32 ), one side of which is connected to the coil seat ( 30 ).