KR20170006063A - Position sensor integrated brushless excitation field winding motor - Google Patents

Abstract

According to an embodiment of the present invention, a position sensor integrated field winding motor with brushless excitation includes: a resolver which penetrates a rotation shaft to be coupled thereto; a fixing unit which combines the resolver with the inside and has a wire on a primary side installed to apply AC power thereto; a rotating unit which penetrates the rotation shaft to be coupled thereto so as to be spaced apart from the fixing unit and has a wire on a secondary side installed to form induced voltage based on the wire on the primary side; and a rectifier which converts the induced voltage formed on the rotating unit into DC power.

Description

{POSITION SENSOR INTEGRATED BRUSHLESS EXCITATION FIELD WINDING MOTOR}

Field of the Invention [0002] The present invention relates to a field winding motor, and more particularly, to a brushless field winding motor in which a slip ring and a brush structure of a field winding motor are replaced and a rotary transformer in which a position sensor is integrated is applied.

In the rotor of the field winding type motor, a coil is wound to generate a magnetic flux, and a brush and a slip ring are provided outside the motor housing to apply a current. Slip rings and brushes are always in mechanical contact to apply current to the rotor windings.

However, the contact area of the slip ring and the brush for current application is small compared to the area of the slip ring. In addition, contact resistance increases at high current input, and heat generation and loss occur.

In addition, there is no problem in the initial motor operation, but as time passes, the contact surface wears due to mechanical contact. Such friction and abrasion may cause foreign matters such as metal powder to affect the service life of the motor, and sparks may occur, which may cause safety problems.

Further, in order to secure the required contact area, the contact area is widened, which is increased in size due to an increase in the axial length of the slip ring.

In recent years, the problem has been solved by replacing the slip ring and the broch with a resolver stator and a resolver rotor.

However, since the thickness of the resolver rotor is not uniform, there is a problem that the pressing area is uneven when the rotor is assembled, and the outer diameter of the resolver rotor is relatively increased, and rotation instability due to increase in inertia at high speed rotation may occur .

In addition, existing resolvers generate considerable heat, but there is no heat dissipation structure that dissipates heat to the outside.

The following prior art document relates to a brushless DC motor in which the waveform of an induced voltage is approximated to a sinusoidal wave through a change in the shape of a permanent magnet inserted in the rotor to improve efficiency and reduce vibration and noise, Possibly installed rotors. Discloses a technique relating to a magnet formed to protrude along the outer circumferential surface of a rotor, and does not include the technical gist of the present invention.

Korean Patent Publication No. 10-2007-0071405

The field winding motor of the brushless excitation type integrated position sensor according to the embodiment of the present invention aims to solve the following problems.

First, it is intended to provide an electric motor which solves the increase in contact resistance and size caused by the conventional slip ring and brush.

Second, an electric motor equipped with a rotary transformer with easy heat dissipation is provided.

The present invention has been made in view of the above problems, and it is an object of the present invention to provide an apparatus and method for controlling the same.

The field winding motor according to the embodiment of the present invention includes a resolver formed to penetrate through a rotary shaft, a fixing part having a primary winding connected to an inner side of the resolver, And a rectifier which is connected to the rotating shaft so as to be spaced apart from the fixed portion and has a secondary winding to form an induced voltage based on the primary winding, and a rectifier for converting the induced voltage formed in the rotating portion into direct current.

And a second receiving groove corresponding to the shape of the primary conductor is formed so as to receive the primary conductor. The first receiving groove is formed in one direction of the rotating shaft so as to receive the primary winding, Side frame.

The molding material is applied to the first receiving groove.

A secondary side conductor having a ring shape and having a third receiving groove formed in the other side of the rotary shaft so as to receive the secondary side winding, a second receiving side having a fourth receiving groove corresponding to the shape of the secondary side conductor to receive the secondary side conductor Side frame.

The rotating portion further includes a fixed bobbin configured to cover the fourth receiving groove so as to prevent the secondary winding from coming off.

And a rotary fan provided on the inner side of the rotary part and adapted to be attached to the rotary shaft. The rotary part is formed with a first ventilation hole in the rotation axis direction, and a second ventilation hole is formed through the rotary part in the rotation axis direction.

And further includes rotating fanring that prevents the rotating fan from being released in the direction of the rotating shaft.

The resolver includes a resolver stator attached to the inside of the stator, and a resolver rotor spaced apart from the inside of the resolver stator and formed to penetrate through the rotating shaft.

The resolver further includes statoring for preventing the resolver stator from being released in the direction of the rotating shaft, and a rotor ring for preventing the resolver rotor from being disengaged in the rotating shaft direction.

The field winding motor of the position sensor integrated type brushless excitation system according to the embodiment of the present invention includes a rotary transformer in place of the conventional slip ring and brush to reduce the contact resistance generated in the slip ring and the brush, There is an effect.

Further, since the ventilation hole is provided, heat generated in the winding can be discharged to the outside.

The effects of the present invention are not limited to those mentioned above, and other effects not mentioned can be clearly understood by those skilled in the art from the following description.

1 is a block diagram showing a field winding motor of a brushless excitation type integrated position sensor according to an embodiment of the present invention.
FIG. 2 is a perspective view showing a fixed portion and a rotating portion of a field winding motor of a brushless excitation type integrated position sensor according to an embodiment of the present invention.
3 is a perspective view illustrating a rotating part, a fixing part, and a resolver of a field winding motor of a brushless excitation type integrated position sensor according to an embodiment of the present invention.
FIG. 4 is a perspective view showing a frame and a core of a rotating part and a fixed part of a fixed winding motor of a brushless excitation type integrated position sensor according to an embodiment of the present invention.
5 is a cross-sectional view illustrating a rotating part and a fixing part of a field winding motor of a brushless excitation type integrated position sensor according to an embodiment of the present invention.
FIG. 6 is a cross-sectional view showing a magnetic flux formed in a rotary part and a fixed part of a field winding motor in a brushless excitation type integrated position sensor according to an embodiment of the present invention.
7 is a perspective view illustrating a rotary fan of a brushless excitation type integrated with a position sensor according to an embodiment of the present invention.
FIG. 8 is a perspective view illustrating a first vent hole of the brushless excitation type integrated position sensor according to an embodiment of the present invention. FIG.
9 is a perspective view showing a second ventilation hole of the brushless excitation type integrated position sensor according to the embodiment of the present invention.
FIG. 10 is a cross-sectional view showing a ventilation path of a brushless excitation type integrated with a position sensor according to an embodiment of the present invention.
11 is a perspective view showing a resolver of a brushless excitation type integrated with a position sensor according to an embodiment of the present invention.

The present invention will be described in detail with reference to the accompanying drawings. It is to be understood that the accompanying drawings are only for the understanding of the present invention and should not be construed as limiting the scope of the present invention.

1 and 2, the field winding motor of the brushless excitation type integrated position sensor according to the present invention includes a resolver 40, a fixing portion 10, a rotating portion 20, a rectifier 50, a rotor, And a stator.

The resolver (40) is formed to be coupled to the rotating shaft (25). The resolver 40 outputs a signal amplitude-modulated with a sinusoidal function and a cosine function to the position of the resolver rotor 24 to the converter 301 when a voltage of a constant magnitude and a constant frequency is applied to the resolver 40 . The converter 301 then calculates the position of the resolver rotor 24. The position of the rotor can be sensed by the calculation of the position of the resolver rotor 24.

The fixing portion 10 is provided with a primary winding 13 for coupling the resolver 40 to the inner side and applying AC power.

The rotating portion 20 is provided with a secondary winding 23 so as to be connected to the rotating shaft 25 so as to be spaced apart from the fixed portion 10 and to form an induced voltage based on the primary winding 13.

The rectifier (50) converts the induced voltage formed in the rotating part (20) to DC.

Therefore, when power is applied to the primary winding 13 of the fixing part 10, a voltage is induced in the secondary winding 23 of the rotating part 20. [

Thereafter, the voltage induced in the secondary side winding 23 passes through the rectifier 50 and is converted to DC, applied to the winding 123 of the rotor, and a magnetic flux is formed in the core 122 of the rotor.

The stator includes a stator winding 123 and a stator core, and the rotor includes a rotor winding and a rotor core. The rotor and the rotor winding 123 rotate in the stator to induce an electromotive force in the stator winding 123.

In this way, the resolver is provided inside the rotating part and the fixing part, and the length of the electric motor in the direction of the rotating shaft 25 is reduced compared to the conventional case.

In addition, since the outer diameter of the rotating portion 20 is equal to the outer diameter of the rotating portion 25 of the fixing portion 10 and the outer diameter of the rotating portion 20 is smaller than that of the conventional rotating portion 20, inertia is reduced.

3, 4 and 5, the fixed part 10 of the field winding motor of the brushless excitation type integrated position sensor according to the present invention includes a primary side conductor 12 and a primary side frame 11 can do.

The primary conductor 12 has a first receiving groove 53 formed in one direction of the rotary shaft 25 so as to receive the primary winding 13 in a ring shape.

The primary side frame 11 is formed with a second receiving groove 54 corresponding to the shape of the primary conductor 12 so as to receive and protect the primary side conductor 12.

The molding material may be applied to the first receiving groove 53 of the primary conductor 12 so that the primary winding 13 accommodated in the primary conductor 12 is fixed.

The rotating part 20 of the field winding motor of the brushless excitation type integrated position sensor according to the present invention may include a secondary side conductor 22 and a secondary side frame 21.

The secondary conductor 22 is formed with a third receiving groove 55 in the other direction of the rotary shaft 25 so as to receive the secondary winding 23 in a ring shape.

The secondary side frame 21 is formed with a fourth receiving groove 56 corresponding to the shape of the secondary side conductor 22 so as to receive and protect the secondary side conductor 22.

Further, the secondary winding 23 may further include a fixed bobbin 29 formed to cover the fourth receiving groove 56 to prevent the secondary winding 23 from coming off.

Further, stepped shapes corresponding to each other can be formed on the fixed bobbin 29 and the secondary frame 21 so as to be press-fitted into the secondary frame 21.

6, when the AC power is applied to the primary winding 11, the magnetic flux is generated in the primary conductor 12, which is a magnetic body, and such magnetic flux (direction of arrow in FIG. 6) Is formed in the secondary conductor (22) through the separation distance of the secondary frame (21). The magnetic flux formed in the secondary conductor 22 generates an induced voltage in the secondary winding 23, and the induced voltage enters the rectifier 50 and is converted into a direct current. The fixed portion 10 and the rotary portion 20 serve as a rotary transformer which is the same as the function of the transformer in a stationary state.

On the other hand, the primary conductor 12 and the secondary conductor 22 can be manufactured by sintering an electrical steel sheet laminate or SMC (Soft Magnetic Composite). When the electric steel sheet is applied, the primary winding 13 and the secondary winding 23 may be wound first and assembled to the primary frame 11 and the secondary frame 21, respectively.

In the case of the SMC, the primary winding 13 and the secondary winding 23 can be rolled and assembled by injection molding on the primary frame 11 and the secondary frame 21.

In addition, the materials of the primary and secondary conductors can be modified to meet performance or environmental requirements.

The primary side frame 11, the secondary side frame 21 and the fixed bobbin 29 may be made of aluminum or the like which is a semi-magnetic material in order to prevent magnetic flux from entering the resolver 40.

As shown in FIGS. 7, 8 and 9, the field winding motor of the brushless excitation type integrated position sensor according to the present invention further includes a rotary fan 26, and the first ventilation hole 51 and the second ventilation hole 52 may be formed.

The rotary fan 26 is provided inside the rotary unit 20 and is formed to be attached to the rotary shaft 25 through the rotary unit.

A first ventilation hole 51 is formed in the rotary part 20 in the direction of the rotary shaft 25 and a second ventilation hole 52 is formed in the fixing part 10 in the direction of the rotary shaft 25.

That is, the first ventilation hole 51 is formed in the secondary frame 21, and the second ventilation hole 52 is formed in the primary frame 11. [ The first ventilation holes 51 and the second ventilation holes 52 may be formed in a number of ways depending on the use environment.

Also, the weight of the fixing portion 10 and the rotation portion 20 is reduced by the first ventilation hole 51 and the second ventilation hole 52.

The rotary fan 26, the first ventilation hole 51 and the second ventilation hole 52 are formed in the same direction as the heat generated in the motor of the present invention such as the rotary part 20, the fixing part 10, the resolver 40, To the outside.

10, when the heat enters the first ventilation hole by the rotary fan 26, the space between the fixing part 10 and the rotary part 20 and the space through the second ventilation opening 52, And is discharged.

In addition, this structure can discharge the dust inside the electric motor of the present invention to the outside.

The rotary fan 26 may include a rotary fan ring 27 for preventing the rotary fan 26 from being released in the direction of the rotary shaft 25.

As shown in Fig. 11, the resolver 40 of the field winding motor of the brushless excitation type integrated position sensor according to the present invention may include a resolver stator 14 and a resolver rotor 24.

The resolver stator 14 is attached to the inside of the stator 10 and the resolver rotor 24 is formed so as to be spaced inside the resolver stator 14 and to be coupled to the rotating shaft 25.

A stator 15 for preventing the resolver stator 14 from being released in the direction of the rotating shaft 25 and a rotor ring for preventing the resolver rotor 24 from being released in the direction of the rotating shaft 25 can do.

Depending on the environment in which the resolver is manufactured, it can be formed as a lock nut instead of the rotor ring.

When the fixed portion 10 and the rotary portion 20 of the field winding motor of the position sensor integrated type brushless excitation system according to the present invention are installed at the end of the motor rear bearing, a moment is generated at the end of the rotary shaft 25, A motor rear bay ring may be provided in the space 60 between the primary frame 11 and the rotary shaft 25.

The embodiments and the accompanying drawings described in the present specification are merely illustrative of some of the technical ideas included in the invention. Therefore, it is to be understood that the embodiments disclosed herein are not for purposes of limiting the technical idea of the present invention, but rather are not intended to limit the scope of the technical idea of the present invention. It will be understood by those of ordinary skill in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined by the appended claims and their equivalents. It should be interpreted.

10: Fixing portion 11: Primary side frame
12: primary side conductor 13: primary side winding
14: Resolver stator 15: statoring
16: molding material 20:
21: secondary side frame 22: secondary side conductor
23: secondary winding 24: resolver rotor
25: rotating shaft 26: rotating fan
27: Rotating fan 28: Rotating ring
29: Fixed bobbin 40: Resolver
50: rectifier 51: first vent
52: second vent hole 53: first receiving groove
54: second receiving groove 55: third receiving groove
56: fourth receiving groove 60: space
100: electric motor 112: stator core
113: stator winding 122: rotor core
123: rotor winding 301: converter

Claims (9)

A resolver 40 formed to penetrate through the rotary shaft 25;
A fixing part (10) having a primary side winding (13) for coupling the resolver (40) to the inside and applying an alternating current power;
A rotation part 20 connected to the rotation shaft 25 so as to be spaced apart from the fixing part 10 and having a secondary winding 23 so as to form an induced voltage based on the primary winding 13;
A rectifier (50) for converting an induced voltage formed in the rotary part (20) into a direct current;
And a position sensor integrated type field winding motor of a brushless excitation type.
The method according to claim 1,
The fixing portion 10
A primary conductor 12 having a ring shape and having a first receiving groove 53 formed in one direction of the rotary shaft 25 so as to receive the primary winding 13;
A primary frame (11) formed with a second receiving groove (54) corresponding to the shape of the primary conductor (12) so as to protect the primary conductor (12);
And a position sensor integrated type field winding motor of a brushless excitation type.
3. The method of claim 2,
And a molding material is applied to the first receiving groove (53).
The method according to claim 1,
The rotation part 20
A secondary conductor (22) having a ring shape and having a third receiving groove (55) formed in the other side of the rotating shaft (25) to receive the secondary winding (23);
A secondary frame (21) formed with a fourth receiving groove (56) corresponding to the shape of the secondary conductor (22) to receive the secondary conductor (22);
A position sensor integrated type field winding motor of brushless excitation type.
5. The method of claim 4,
The rotation part 20
Further comprising a fixed bobbin (29) formed to cover the fourth receiving groove (56) so as to prevent the secondary winding (23) from coming off.
The method according to claim 1,
Further comprising a rotating fan (26) provided inside the rotating part (20) and formed to be attached to the rotating shaft (25)
A first ventilation hole 51 is formed in the rotation part 20 in the direction of the rotation shaft 25,
And a second vent hole (52) is formed through the fixing portion (10) in a direction of the rotation shaft (25).
The method according to claim 6,
Further comprising a rotary fan ring (27) for preventing the rotary fan (26) from being disengaged in the direction of the rotary shaft (25).
The method according to claim 1,
The resolver (40)
A resolver stator 14 attached inside the stator 10;
A resolver rotor (24) spaced from the inside of the resolver stator (14) and penetratingly connected to the rotating shaft (25);
And a position sensor integrated type field winding motor of a brushless excitation type.
9. The method of claim 8,
The resolver (40)
A stator 15 for preventing the resolver stator 14 from being released in the direction of the rotating shaft 25;
A rotor ring (28) for preventing the resolver rotor (24) from being released in the direction of the rotating shaft (25);
Further comprising a position sensor integrated type brushless excitation field field winding motor.

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