阅读说明：本技术 利用多重多相线圈磁场锁定的电磁机械 (Electromagnetic machine with multiple polyphase coil magnetic field locking ) 是由 明南秀 于 2020-02-10 设计创作，主要内容包括：本申请涉及电磁机械,所述电磁机械包括：旋转轴；定子,所述定子包括多相线圈；动子(1转子),所述动子(1转子)与定子隔开预设间隔,包括多相线圈；及控制部,所述控制部独立地控制定子的第一磁场及动子(1转子)的第二磁场。根据本申请的电磁机械具有如下效果,即,可以解决能够独立地主动控制的绕线型定子与动子(1转子)在启动或必要时的扭矩问题,可以以最小大小发生最大驱动扭矩,可以使效率最大化。(The present application relates to an electromagnetic machine, comprising: a rotating shaft; a stator including a multi-phase coil; the rotor (1) is separated from the stator by a preset interval and comprises a multiphase coil; and a control unit that independently controls the first magnetic field of the stator and the second magnetic field of the mover (1 rotor). The electromagnetic machine according to the present application has the effects that the torque problem of the winding type stator and the mover (1 rotor) which can be independently and actively controlled at the starting or when necessary can be solved, the maximum driving torque can be generated with the minimum size, and the efficiency can be maximized.)

1. An electromagnetic machine, comprising:

a stator including a multi-phase coil;

the rotor comprises a multi-phase coil and is separated from the stator by a preset interval; and

and a control unit that independently controls the first magnetic field of the stator and the second magnetic field of the mover.

2. The electromagnetic machine of claim 1,

the control portion controls the first magnetic field by controlling a first current coupled into the multi-phase coils of the stator, and the control portion controls the second magnetic field by controlling a second current coupled into the multi-phase coils of the mover.

3. The electromagnetic machine of claim 2,

the control section controls the phase and amplitude of the first current and the phase and amplitude of the second current, respectively.

4. The electromagnetic machine of claim 1,

the controller switches the first current to the multi-phase coil of the stator or switches the second current to the multi-phase coil of the mover in at least one of a direct connection method, a slip ring method, and a wireless inductive coupling method.

5. The electromagnetic machine of claim 1,

the control unit controls the electromagnetic machine so that the first magnetic field of the stator and the second magnetic field of the mover are locked to each other at an initial stage of driving.

6. The electromagnetic machine of claim 1,

the control unit controls the first magnetic field and the second magnetic field to move in the same direction or in opposite directions.

7. The electromagnetic machine of claim 1,

the mover is a rotor that is connected to a rotating shaft and rotates about the rotating shaft.

8. The electromagnetic machine of claim 7,

the control unit maintains a first magnetic field of the stator and a second magnetic field of the mover to be locked with each other, and individually controls the first magnetic field and the second magnetic field to generate a torque and a speed of the rotating shaft.

9. The electromagnetic machine of claim 1,

the electromagnetic machine is a linear electromagnetic machine or a rotary electromagnetic machine.

10. The electromagnetic machine of claim 1,

the stator includes a first array of coils,

the mover includes a second coil array formed to be spaced apart from the first coil array by a preset interval and having a mirror image in a spaced-apart direction,

the first array of coils includes at least one first half-cycle and at least one second half-cycle formed adjacent to each other,

the first half cycle includes at least two coils having current flowing directions different from each other, and

the first half cycle and the second half cycle have mirror images in adjacent directions.

11. The electromagnetic machine of claim 10,

the direction of the magnetic field formed between the two coils forming the first half cycle and the direction of the magnetic field formed between the two coils forming the second half cycle are opposite to each other.

12. The electromagnetic machine of claim 10, wherein the first half-cycle comprises:

a first layer adjacent to the second coil array, including at least two coils having current flow directions different from each other;

a second layer located on top of the first layer, including a second layer of coil structures having the same direction of current flow as the coil structures of the first layer but located further outside than the first layer of coil structures; and

a third layer located on the upper portion of the second layer, including a third layer coil structure having a current direction opposite to each other with respect to the second layer coil structure but located more inside than the second layer coil structure.

13. The electromagnetic machine of claim 12, further comprising:

a fourth layer located on an upper portion of the third layer, including a fourth layer coil structure having a same current direction as the coil structure of the third layer but located more outside than the third layer coil structure.

14. The moving electromagnetic machine of claim 10, wherein the first half-cycle comprises:

a lower layer adjacent to the second coil array, including at least two coils having current flowing directions different from each other;

an upper layer positioned above the lower layer and including an upper coil structure having a current direction opposite to that of the lower coil structure.

15. The electromagnetic machine of claim 10,

the first coil array comprises a plurality of first half cycles and a plurality of second half cycles, and

the first half cycle and the second half cycle are periodically formed in adjacent directions.

16. The moving electromagnetic machine of claim 10,

the length of the first coil array or the second coil array extends along a current flow direction,

the first coil array or the second coil array comprises a segmented annular current profile or a segmented solenoid current profile.

17. A magnetic field synchronous coupling dual feed electromagnetic machine system comprising an electromagnetic machine according to claim 1.

Technical Field

The present invention relates to an Electromagnetic machine using multiple multiphase coil magnetic field locking, and more particularly, to an Electromagnetic machine using multiple multiphase coil magnetic field locking, which includes an actively controllable rotor and stator independently generating a Rotating magnetic field (Rotating magnetic field) in an Electromagnetic machine (Electromagnetic machine), and independently controls the rotor and stator to serve as a motor, thereby increasing Torque (Torque) required at start-up or during operation, and preferably adjusting direction, Torque, and speed, and also serving as a generator, which can eliminate instability of a power source (prime mover), supply stable electric power, have a wide operating range, have high efficiency with a small size, and also can adjust Torque and speed in a wide area.

Background

In many industrial fields, there is a great demand for mounting reversible electromagnetic machines comprising rotating members within a system. Depending on the operating conditions of the system in which the machine is installed, it is converted into mechanical energy produced by the rotary motion of such a rotating member, and it is a Generator (Generator) that generates electrical energy using such mechanical energy. The power generated by such a generator may be supplied to or stored in other system elements. In addition, a Motor (Motor) supplies electric energy to a machine and converts the electric energy into mechanical energy to rotate a rotating member to obtain rotational power.

The electromagnetic machine used in such a motor/generator is the most widely used electric apparatus in the periphery of our lives, has a capacity of from a small size of several tens of watts to a large size of several MW, and is widely used in homes and industrial fields, particularly, electric fans, washing machines, refrigerators, automobiles, elevators, water pumps, cranes, and the like. The general demand for such electromagnetic machines is not only cost saving, especially in transport devices such as ground vehicles or aircraft, but also miniaturization and weight reduction.

In addition, the electromagnetic machine is constituted by a stator and a rotor. In general, the rotor operates on the principle that a rotational torque is generated by a rotating magnetic field generated when a current flows in a stator coil (coil). A force by which the rotor is rotated by means of the rotational torque is used as the rotational power.

The dc motor generates torque by driving an armature coil in a gap using a fixed magnetic field. In order to switch an armature, a commutator is required for switching a current, an induction motor has a stator having a plurality of phase coils for generating a moving or rotating magnetic field in a gap, and a rotor generates a predetermined magnetic field from a permanent magnet or an electromagnet and rotates at the same speed as the rotor shaft. In other words, the conventional electromagnetic machine has a magnetic field fixed to a shaft to rotate.

In the dc motor, since a mechanical commutator (brush) is used, regular maintenance is required, and it is difficult to drive the dc motor at high speed, and the installation place is limited. On the other hand, in a Permanent Magnet Synchronous Motor (PMSM) without a mechanical rectifier, there are problems that surplus is small at the time of maximum output and Magnet performance is low at high temperature because a Permanent Magnet is used.

Generally, in an induction motor, torque generated by inertia of a load and the motor itself at the time of starting is small, and it takes time to normally operate. In addition, when the motor is started, a large current called an inrush current (In-rush current) temporarily flows through the motor coil. Therefore, when the induction motor is used, there is a problem that the inrush current needs to be adjusted well.

Induction motors can be roughly classified into a Squirrel cage induction motor (Squirrel cage induction motor) and a Wound motor (Wound motor). The cage type induction motor has a simple and firm structure, is easy to operate, and is easy to maintain. However, the structural characteristics require a large current at the time of starting, and a small torque is generated. Therefore, it is difficult to apply the method to a case where frequent start and stop are required or a control speed or a power source capacity is required to be small.

In addition, the wire-wound motor generates a large torque with a small starting current as compared with a cage motor. However, in order to generate a large torque, the size of the motor itself needs to be increased, which causes a problem of cost increase. In addition, the wire-wound motor requires a slip ring.

Disclosure of Invention

The present application is directed to solving the conventional problems as described above, and an object of the present application is to provide an electromagnetic machine including a wound rotor and a stator that can be actively controlled independently.

Another object of the present application is to provide a double-fed Electromagnetic Machine (double Active Electromagnetic Machine) system that utilizes an Electromagnetic Machine including a wound rotor and a stator that can be actively controlled independently, thereby reducing the system scale and improving efficiency.

As an embodiment intended to achieve the above object, an electromagnetic machine according to an embodiment of the present application includes: a stator including a multi-phase coil; the rotor is separated from the stator by a preset interval and comprises a multi-phase coil; and a control unit that independently controls the first magnetic field of the stator and the second magnetic field of the mover.

The controller may control a first current to be supplied to the multi-phase coils of the stator and a second current to be supplied to the multi-phase coils of the mover, so that the first magnetic field and the second magnetic field may be controlled.

The control unit may control the phase and amplitude of the first current and the second current, respectively.

The controller may switch the first current to the multi-phase coil of the stator or the second current to the multi-phase coil of the mover in at least one of a direct-connection method, a slip-ring (slip-ring) method, and a wireless inductive coupling method.

In addition, the control unit may control the electromagnetic machine so that the first magnetic field of the stator and the second magnetic field of the mover are locked to each other at an initial driving stage.

The control unit may control the moving directions of the first magnetic field and the second magnetic field in the same direction or in opposite directions.

The mover may be a rotor that is coupled to a rotation shaft and rotates around the rotation shaft.

The control unit may control the first magnetic field and the second magnetic field of the rotor to generate the torque and the speed of the rotating shaft by controlling the first magnetic field and the second magnetic field, respectively, while keeping the first magnetic field of the stator and the second magnetic field of the rotor locked to each other.

In addition, the electromagnetic machine may be a linear electromagnetic machine or a rotary electromagnetic machine.

In addition, the stator may include a first coil array, the mover may include a second coil array formed at a predetermined interval from the first coil array, with mirror images in the spaced direction, and the first coil array may include at least one first half-cycle and at least one second half-cycle formed adjacent to each other, the first half-cycle may include at least two coils having current flow directions different from each other, and the first half-cycle and the second half-cycle may have mirror images in the adjacent directions.

In addition, the direction of the magnetic field formed between the two coils forming the first half period and the direction of the magnetic field formed between the two coils forming the second half period may be opposite to each other.

In addition, the first half cycle may include: a first layer adjoining the second coil array, including at least two coils having current flow directions different from each other; a second layer located on top of the first layer, including a second layer of coil structures having the same direction of current flow as the coil structures of the first layer but located further outside than the first layer of coil structures; and a third layer located on the upper portion of the second layer, including a third layer coil structure having a current direction opposite to each other with respect to the second layer coil structure but located more inside than the second layer coil structure.

In addition, the method may further include: a fourth layer located on an upper portion of the third layer, including a fourth layer coil structure having a same current direction as the coil structure of the third layer but located more outside than the third layer coil structure.

In addition, the first half cycle may include: a lower layer adjacent to the second coil array, including at least two coils having current flowing directions different from each other; an upper layer positioned above the lower layer and including an upper coil structure having a current direction opposite to that of the lower coil structure.

In addition, the first coil array may include a plurality of first half cycles and a plurality of second half cycles, and the first half cycles and the second half cycles may be periodically formed in adjacent directions.

Additionally, with respect to the first coil array or the second coil array, the length may be elongated along the current flow direction, and may include a segmented annular (Toroid) or segmented Solenoid (Solenoid) current distribution.

As an embodiment for achieving the above object, a Field synchronous coupling (Field Lock) doubly-fed electromagnetic machine system according to an embodiment of the present application includes an electromagnetic machine, the electromagnetic machine including: a stator including a multi-phase coil; the rotor is separated from the stator by a preset interval and comprises a multi-phase coil; and a control unit that independently controls the first magnetic field of the stator and the second magnetic field of the mover.

Therefore, with the above problem solution, the following effects are expected.

The electromagnetic machine including the independently actively controllable wound-rotor and stator according to the present application can solve a starting torque greater than a normal operation state due to a load and inertia of the motor itself at the time of starting, using a rotating magnetic field generated by the independently actively controllable wound-rotor. Therefore, the maximum driving torque can be generated with the minimum size, and the efficiency can be maximized. In addition, the control-based rapid operation can be realized, and the control-based rapid operation device has a wide dynamic range and can be safely operated.

If a Double-Fed Electromagnetic Machine (Double-Fed Electromagnetic Machine) of a new concept using an Electromagnetic Machine including a wound rotor and a stator capable of being actively controlled independently according to the present application is applied to a new renewable energy system such as offshore wind power generation, tidal power generation, wave power generation, etc., driving torque and speed can be efficiently controlled without a transmission, thereby having advantages that the size can be reduced and the efficiency can be increased.

On the other hand, if an in-wheel motor of an electromagnetic machine using a wound-rotor type rotor and a stator according to the present application, which are capable of being actively controlled independently, is utilized, it is possible to minimize the size, to attach to each wheel and to control the driving torque and speed of each wheel individually and efficiently, and thus it can be applied to future automobiles such as electric automobiles.

Drawings

FIG. 1 is a block diagram of an electromagnetic machine according to one embodiment of the present application.

FIG. 2 is a schematic cross-sectional view illustrating an internal structure of an electromagnetic machine according to one embodiment of the present application.

FIG. 3 is another schematic cross-sectional view illustrating an internal structure of an electromagnetic machine in accordance with one embodiment of the present application.

FIG. 4 is a diagrammatic, schematic illustration of driving or controlling an electromagnetic machine according to one embodiment of the present application.

FIG. 5 is a circuit diagram illustrating an equivalent circuit for an electromagnetic machine according to one embodiment of the present application.

FIG. 6 is a schematic illustration of a generalized wind-powered double-fed Electromagnetic Machine (double Active Electromagnetic Machine) for applying Electromagnetic machines according to one embodiment of the present application.

FIG. 7 is a schematic illustration of an In-wheel (In-wheel) drive electromagnetic machine for application of the electromagnetic machine according to one embodiment of the present application.

FIG. 8 is another schematic illustration of a generalized in-wheel drive electromagnetic machine for use with the electromagnetic machine according to one embodiment of the present application.

Fig. 9 shows forces between a stator and a mover according to an embodiment of the present application.

Fig. 10 is a schematic cross-sectional view schematically illustrating current flow and magnetic flux magnitude of a coil array of a stator and a mover according to an embodiment of the present application.

Fig. 11 is a schematic cross-sectional view showing a coil array of a stator and a mover according to an embodiment of the present application with 2 phase difference coil groups.

Fig. 12 is a schematic cross-sectional view schematically illustrating current flow and magnetic flux magnitude of a coil array of a stator and a mover according to an embodiment of the present application.

Fig. 13 is a schematic perspective view of a coil array structure of a stator and a mover according to an embodiment of the present application.

Fig. 14 is a conceptual diagram schematically illustrating the interaction of magnetic fields and currents generated by the coil array structure of the stator and the mover according to the embodiment of the present application.

Fig. 15 is a schematic sectional view schematically showing a coil array having laminated coils and to which a stator and a mover according to an embodiment of the present application are applied in a horizontal direction.

Fig. 16 is a schematic sectional view schematically showing a coil array having a laminated coil and to which a stator and a mover according to an embodiment of the present application are applied in a three-dimensional structure.

Fig. 17 is a diagram of simulation results for a structure of a coil array to which a stator and a mover according to an embodiment of the present application are applied in a three-dimensional structure.

Fig. 18 is a diagram of simulation results for a structure of a coil array to which a stator and a mover according to an embodiment of the present application are applied in a three-dimensional structure.

Fig. 19 is a schematic sectional view schematically showing a coil array having a planar coil structure and to which a stator and a mover according to an embodiment of the present application are applied.

Fig. 20 is a schematic sectional view schematically showing a coil array having a planar coil structure and to which a stator and a mover according to an embodiment of the present application are applied in a three-dimensional structure.

Fig. 21 is a diagram of simulation results for a structure of a coil array having a planar coil structure and to which a stator and a mover according to an embodiment of the present application are stereoscopically applied.

Detailed Description

Preferred embodiments of the present application will be described in detail below with reference to the accompanying drawings. The advantages and features of the present application and methods of accomplishing the same will become apparent with reference to the following detailed description of the embodiments taken in conjunction with the accompanying drawings. However, the present application is not limited to the embodiments described herein, and may be embodied in different forms. Rather, the embodiments described herein are provided so that this disclosure will be thorough and complete, and will fully convey the concept of the application to those skilled in the art, and the application will only be defined by the scope of the appended claims. On the other hand, like reference numerals refer to like constituent elements throughout the specification.

The terminology used in the description is for the purpose of describing the embodiments and is not intended to be limiting of the application. In this specification, the singular forms also include the plural forms as long as they are not specifically mentioned in the sentence. The use of "comprising" and/or "comprising" in the specification does not exclude the presence or addition of one or more other elements, steps, acts and/or components than those listed. In addition, since the preferred embodiment is described, the reference numerals provided in the description order are not necessarily limited to the description order. In the present specification, the meaning does not exclude the case where a certain component or member is mentioned or other components or members, and if necessary, other components or members may be additionally inserted.

The descriptions and examples provided in this specification are presented for illustrative purposes and are not intended to limit the scope of the appended claims (scope). The present description should be considered as illustrating the principles of the present application and not as limiting the claims of the described embodiments and/or the spirit (spirit) and scope of the present application. One of ordinary skill in the art may adapt the application for its particular application.

The embodiments described in the present specification will be described with reference to a cross-sectional view and a plan view, which are ideal schematic diagrams of the present application. In the drawings, the thickness of the film and the region are exaggerated for effective explanation of the technical contents. Therefore, the form of the schematic diagram may be distorted due to manufacturing techniques and/or tolerance errors. Therefore, the embodiments of the present application are not limited to the specific forms shown, and include changes in form that are produced in accordance with the manufacturing process. For example, the etched area shown as a right angle may be in the form of a circle or a predetermined curvature. Therefore, the regions shown in the drawings have a schematic property, and the patterns of the regions shown in the drawings are for showing the specific forms of the element regions, and are not intended to limit the scope of the invention.

The electromagnetic machine according to an embodiment of the present application includes a stator 110, a mover 120, and a control portion 130.

The stator 110 and the mover 120 include multi-phase coils 111 and 121, respectively, which are formed to be spaced apart from each other by a predetermined interval d. The control unit 130 independently controls the first magnetic field of the stator and the second magnetic field of the mover. By controlling the direction of the current flowing in the polyphase coils, a magnetic field is formed by means of the current, and by controlling the current flowing in the polyphase coils, the movement or direction of the magnetic field can be controlled.

The controller 130 controls a first current to be applied to the stator multi-phase coil 111 and a second current to be applied to the mover multi-phase coil 121, thereby controlling the first magnetic field and the second magnetic field. The control unit may control the phase and amplitude of the first current and the second current, respectively.

The control unit 130 may control the electromagnetic machine so that the first magnetic field of the stator and the second magnetic field of the mover are locked to each other at the start of driving, and may control the moving directions of the first magnetic field and the second magnetic field in the same direction or in opposite directions.

The mover 120 may be a rotor coupled to a rotation shaft and rotating around the rotation shaft, and the control unit 130 may generate torque and speed of the rotation shaft by controlling the first magnetic field and the second magnetic field of the mover while keeping the first magnetic field of the stator and the second magnetic field of the mover locked to each other.

The stator 110 and the mover 120 may be circular to have a coaxial form. The multi-phase coils 111, 121 arranged in a linear array may be applied to a linear motor. In addition, both linear and rotary electromagnetic machines may be used.

There is a small air gap between the stator and the mover, wherein the mover is freely rotatable with respect to the stator, centered coaxially. If currents flow in the polyphase coils of the stator, a periodic magnetic field is generated in the air gap. Similarly, if a current flows in the polyphase coils of the mover, a periodic magnetic field is generated in the air gap.

A moving magnetic field is generated in the air gap if the polyphase coils of the stator are excited by sine wave input currents with an appropriate phase difference, and a moving magnetic field is generated in the air gap if the polyphase coils of the mover are excited by sine wave input currents with an appropriate phase difference.

When the mover moves at a preset speed with respect to the stator, a magnetic field generated by a preset current through a multi-phase coil of the mover moves with the movement of the mover. Sinusoidal wave currents passing through the multiphase coils of the mover generate a rotating magnetic field with respect to the rotation axis of the mover. If the mover rotates, the rotation of the magnetic field in the air gap rotates at a speed determined by a combination of the magnetic field rotation speed and the shaft rotation speed.

In relation to the stationary coordinate system, the velocity of the magnetic field in the air gap generated by the mover is a combination of the velocity of the magnetic element generated by the current of the mover coils and the velocity of the mover.

The polyphase coils provided in the stator and the mover mean 2 or more individual coils each of which generates a periodic magnetic field in the air gap as a function of angle when a current flows. In a 360 degree angle, an integer number of spatial periods or periods may be included. When the number of the phase coils is two or more, the second coil is offset and arranged at a fixed angle with respect to the first coil. For example, in the case of a 2-phase coil, the coil may be moved at 1/4 cycles (or 90 degrees in Electrical angle), and in the case of a 3-phase coil, the coil may be moved at 1/3 cycles (or 120 degrees in Electrical angle).

By supplying current to the coils, the total magnetic field generated by all the coils is the sum of the magnetic fields generated by the current through each coil. By varying the amount of current in the coil, the phase and amplitude of the magnetic field can be varied.

The polyphase currents for the polyphase coils can be supplied to the stator and the mover freely rotating in relation to the stator by means of different coupling means including slip rings or wireless inductive coupling. The multiphase current may be supplied to the electromagnetic machine through fixed conductors or other coupling means that enable power and control signals to be transferred to the electromagnetic machine.

An electromagnetic machine according to one embodiment of the present application utilizes rotating magnetic fields generated by time-varying currents supplied at different phases in stator and/or mover coils. When current is supplied to the multiple coils, an integral multiple periodic magnetic field variation is generated.

The number of each period of the magnetic field generated by the stator and the mover may be the same. The mover and the stator are in a state of magnetic field locking with each other when they are magnetized by respective currents. In other words, the mover is located at a fixed angular position of the magnetic field generated by the stator, and the magnetic field generated by the mover attracts each other. In the polyphase coils of the stator, the phase current of the mover is fixed as the phase of the current changes, and conversely, the magnetic field pattern in the air gap generated by the stator moves as the phase of the current changes. As the stator magnetic field moves, the mover magnetic field moves together to keep the magnetic field locked. A similar event occurs as the stator phase is unchanged and the phase of the mover current is changed.

If the currents of the coils of the stator and the mover change, the magnetic fields generated by the multi-phase coils move. When the currents vary in time in exactly the same way in both the stator and the rotor, generating rotation of the same magnetic field in the same way, in the same way the magnetic field lock causes the mover to rotate in the opposite direction, twice the speed of rotation of the magnetic field, whereas when the magnetic field rotation of the stator and the mover are in the opposite direction, the mover remains stationary due to the magnetic field lock.

When the rotation speed of the moving magnetic field of the stator is equal to the sum of the speeds of the moving magnetic fields generated by the mover, which are determined according to the speed and frequency of the mover, magnetic field lock is formed.

If there is an external force that attracts the mover in the direction opposite to the mover, the mechanical power is transmitted to the mover. At this time, a small phase shift occurs in the electromagnetic wave and the current. The external force is equalized by a force generated in an element that moves due to a magnetic field and an electric current. For example, if the stator current amplitude is fixed and a fixed amplitude harmonic moving magnetic field is generated, the moving element current amplitude is increased.

With independent, simultaneous control of the phases, the frequency and amplitude of the current in the stator and mover not only protects the payload and the electromagnetic machine, but also provides extensive dynamic control.

Fig. 2 is a schematic cross-sectional view illustrating an internal structure of an electromagnetic machine including a winding type rotor and a stator capable of being independently actively controlled according to an embodiment of the present application. Fig. 2 is a rotary electromagnetic machine in which a mover is connected to a rotary shaft as a rotor and rotates while maintaining a gap from a stator, and the electromagnetic machine of fig. 2 will be described as an example. Fig. 2 is an embodiment, and an electromagnetic machine according to an embodiment of the present application is of course not limited thereto.

As shown in fig. 2, an electromagnetic machine 1100 according to an embodiment of the present invention may include a Stator (Stator)120 fixed inside a housing 1110, a rotating Shaft (1 sharp) 130 penetrating the housing 1110, a Rotor (Rotor)140 surrounding the rotating Shaft 1130, and a control unit 1150 disposed at one end of the Stator 1120 and the Rotor 1140. For the sake of illustration, the positions of the stator 1120, the rotary shaft 1130, the rotor 1140, and the controller 1150 in the housing 1110 are specified, but the present invention is not limited thereto, and an appropriate position may be rearranged within a range not departing from the spirit of the present invention.

The rotation shaft 1130 is disposed to penetrate the center of the housing 1110 in the longitudinal direction. Further, bearings 1160 are provided at both ends of the housing 1110 supported by the rotary shaft 1130. On the other hand, the rotatable housing 1111 is disposed outside the control section 1150 such that an external power line (not shown) is not wound when rotated. In this case, the housing 1110 is exemplarily illustrated as being provided with a rotatable housing 1111 so that the external power line is not wound, but is not limited thereto, and may be fixed when power is wirelessly supplied or otherwise transferred. On the other hand, when wireless power and signals are supplied, since one side rotates at high speed, an interval 1s between the control section 1150 and the stator 1120 and the rotor 1140 is required.

Further, a stator 1120 is attached and fixed to an inner peripheral surface of the housing 1110, and the stator 1120 includes a multi-phase coil (not shown). The stator 1120 includes a rotor 1140 including a rotation shaft 1130 inside the stator 1120, and the rotor 1140 shares a center with the rotation shaft 1130 and the stator 1120 and is spaced apart from the stator 1120 by a predetermined interval, i.e., an Air gap (Air gap) d, in a direction of the rotor 1130. On the other hand, the rotor 1140 in one embodiment according to the present application includes a multi-phase coil (not shown in the drawing).

The stator 1120, the rotary shaft 1130, and one end of the rotor 1140 in the housing 1110 include a controller 1150 for transmitting and receiving electric power. At this time, the control part 1150 may supply a first power to the stator 1120 to generate a first rotating magnetic field (not shown in the drawing), may adjust the supplied first power, and may control the magnitude, frequency, etc. of the first rotating magnetic field. The first power is transmitted and received from the controller 1150 to the polyphase coils of the stator 1120 through the stator switch 1125 in any one selected from a direct connection method (not shown), a slip-ring method (not shown), a wireless inductive coupling method (not shown), and a combination thereof. The stator switching unit 1125 is a unit for generating Pulse Width Modulation (PWM), and may include an inverter and a converter. The stator switch 1125 is coupled to one end of the stator 1120 and is exemplarily illustrated, but is not limited thereto, and the stator switch 1125 may be included in the controller 1150.

In addition, the control unit 1150 may supply a second electric power to the rotor 1140, generate a second rotating magnetic field (not shown) independently of the first rotating magnetic field, adjust the supplied second electric power, and control the magnitude, frequency, and the like of the second rotating magnetic field. The second power is transmitted and received from the controller 1150 to and from the polyphase coils of the rotor 1140 via the rotor switching unit 1145 in any one selected from a slip ring system (not shown), a wireless inductive coupling system (not shown), and a combination thereof.

On the other hand, the control unit 1150 may transmit a control command to the stator 1120 in any one selected from a direct wire connection method (not shown), a slip ring connection method (not shown), a wireless inductive coupling method (not shown), and a combination thereof. The control unit 1150 may transmit a control command to the rotor 1140 in any one selected from a slip ring system (not shown), a wireless inductive coupling system (not shown), and a combination thereof. At this time, when the control part 1150 supplies the first power and the second power to the stator 1120 and the rotor 1140, respectively, in a wireless inductive coupling manner, it is possible to avoid interference using frequencies different from each other with respect to the control command transmitted in the wireless inductive coupling manner.

Fig. 3 is a schematic cross-sectional view illustrating an internal structure of an electromagnetic machine including a winding type rotor and a stator capable of being independently actively controlled according to an embodiment of the present application.

As shown in fig. 3, an electromagnetic machine 1200 including a winding type rotor and a stator capable of being actively controlled independently according to an embodiment of the present application may include a stator 1220 fixed to an inner side of a housing 1210, a rotating shaft 1230 penetrating the housing 1210, a rotor 1240 surrounding the rotating shaft 1230, and a control part 1250 disposed at one end of the stator 1220 and the rotor 1240. Referring to fig. 3, electromagnetic machine 1200 according to one embodiment of the present application is an example in which stator 1220 and rotor 1240 are embodied in control section 1250 by stator slip ring 1221 and rotor slip ring 1241. Here, the control part 1250 is exemplarily shown to be disposed inside the outer case 1210, but is not limited thereto, and the control part 1250 may be disposed outside the outer case 1210.

FIG. 4 is a diagrammatic, schematic illustration of driving or controlling an electromagnetic machine in accordance with an embodiment of the present application.

Referring to fig. 4, when a control command 1352 of the control part 1350 is transmitted to the stator switching part 1325 through the control circuit 1351 in order to drive the stator 1320, a first power is supplied from the power supply/grid 1370 to the multi-phase coils (not shown in the drawing) of the stator 1320 through the stator switching part 1325, and a first rotating magnetic field (not shown in the drawing) is generated. On the other hand, in order to control the stator 1320, when a control command 1352 of the control part 1350 is transmitted to the stator switching part 1325 via the control circuit 1351, electric power (not shown in the drawing) generated from the stator 1320 is supplied to the electric power supply device/grid 1370 via the stator switching part 1325.

In addition, in order to drive the rotor 1340, when a control command 1352 of the control unit 1350 is transmitted to the rotor switching unit 1345 via the control circuit 1351, a second electric power is supplied from the electric power supply/grid 1370 to the multi-phase coils (not shown) of the rotor 1340 via the rotor switching unit 1345, and a second rotating magnetic field (not shown) is generated. On the other hand, in order to control the rotor 1340, when a control command 1352 of the control part 1350 is transmitted to the rotor switching part 1345 via the control circuit 1351, electric power (not shown in the figure) generated from the rotor 1340 is supplied to the electric power supply device/grid 1370 via the rotor switching part 1345.

On the other hand, the second rotating magnetic field is measured in magnitude, frequency, and the like of the first rotating magnetic field by a sensor 1380 included in the stator 1320, and the measured value 1353 is transmitted to the control circuit 1351 to be compared with the magnitude, frequency, and the like of the second rotating magnetic field, thereby actively controlling the stator 1320 and the rotor 1340 for optimizing the torque and efficiency of the electromagnetic machine. In addition, the first rotating magnetic field also measures the magnitude, frequency, etc. of the second rotating magnetic field through a sensor 1380 included in the rotor 1340, and transmits the measurement value 1354 to the control circuit 1351 to be compared with the magnitude, frequency, etc. of the first rotating magnetic field, thereby actively controlling the stator 1320 and the rotor 1340 for optimizing the torque and efficiency of the electromagnetic machine. On the other hand, the sensors 1380 measure at least one or more dynamic operating conditions (torque, current, voltage, position, speed, etc.) of the stator 1320 and rotor 1340 for optimizing use of the electromagnetic machine. In addition, the electromagnetic machine can be operated efficiently and safely by using not only the dynamic operation state measurement value secured by the sensor 1380 but also the state information of the power supply device/grid 1370.

Fig. 5 is a circuit diagram illustrating an equivalent circuit for an electromagnetic machine including independently actively controllable wound rotors and stators according to one embodiment of the present application.

As shown in fig. 5, an equivalent circuit 1400 of an electromagnetic machine including a wound rotor and a stator capable of being actively controlled independently according to one embodiment of the present application includes an equivalent circuit 1420 of the stator and an equivalent circuit 1440 of the rotor. At this time, the electromagnetic machine according to one embodiment of the present application is described as a 2-phase coil having a phase difference of 90 ° for illustrative purposes, but is not limited thereto, and can be easily applied to even a multi-phase coil as long as a practitioner can easily use it. The force according to lorentz's law can be expressed in the following mathematical formula.

[ mathematical formula 1 ]

F＝lB_Si_r

Wherein F is the force generated in the wire, l is the length of the rod-shaped wire, B_SIs the magnitude of the magnetic field generated by the current flowing in the stator coil, i_rIs the value of the current flowing in the mover electric wire.

In the electromagnetic-mechanical equivalent circuit 1400 according to an embodiment of the present application, assuming that a rotating magnetic field generated in the equivalent circuit 1420 of the stator is generated in the Z-axis direction, the current supplied in the equivalent circuit 1440 of the rotor is supplied in the Y-axis direction, which can be expressed by the following equation. In particular, the magnetic flux generated by the current flowing in the coil a of the stator can be approximated to a sine wave and can be expressed by the following mathematical expression.

[ mathematical formula 2 ]

The stator coils may have multiple cycles of an electromagnetic machine. In mathematical formula 2, superscript a means coil (phase) a. In addition, a Magnetic Flux (Magnetic Flux) occurs in the phase a coil of the stator. Also, the phase B coil electrically exhibits a 90 ° phase difference with respect to the phase a coil, and the magnetic flux generated by the current flowing in the phase B coil can be expressed by the following mathematical expression.

[ mathematical formula 3 ]

Therefore, the phase a coil and the phase B coil are overlapped by the current flowing through the stator coil and changing with the set time difference, and the traveling magnetic field is formed as follows. This can be expressed by the following mathematical formula.

[ mathematical formula 4 ]

Or

B_Z(x，t)＝B₀cos(k_Sx_S)cos(ω_St)+B₀sin(k_Sx_S)sin(ω_St)＝B₀cos(k_Sx_S-ω_S ^t)

Similar to the rotating magnetic field generated by the current flowing in the stator coil, the current flowing in the rotor coil may be approximated as a sine wave. The current flowing in the phase a coil of the rotor can be expressed by the following mathematical expression.

[ math figure 5 ]

Further, the phase B coil has a phase difference of 90 ° with respect to the phase a coil, and the current flowing in the phase B coil of the rotor can be expressed by the following mathematical expression.

[ mathematical formula 6 ]

Therefore, the current flowing in the rotor coil can be as follows due to the overlap of the phase a coil and the phase B coil. This can be expressed by the following mathematical formula.

[ mathematical formula 7 ]

Or

i_Y(x，t)＝i₀cos(k_mx_m-ω_mt)

The lorentz force F (x, t) generated by the electromagnetic machine can be expressed from the following mathematical expressions, 4 and 7. Here, the lorentz force is analyzed by the interaction of the magnetic field generated from the stator and the current generated from the rotor, but this is merely exemplary, and the opposite case can be resolved.

[ mathematical formula 8 ]

F(x，t)＝1B₀i₀cos[k_sx_s-ω_st]cos[k_mx_m-ω_m ^t-φ]

Where φ is the phase difference between the rotor and the stator. In addition, if x is assumed_mCompare x_SAt a velocity v_mThe movement (relative to the stator coils) can be expressed by the following mathematical expression.

[ mathematical formula 9 ]

x_m＝x_S-v_mt

The torque resolved in the equivalent circuit 1400 of the electromagnetic machine is proportional to the magnetic field that can be resolved from the equivalent circuit 1420 of the stator and the equivalent circuit 1440 of the rotor, and can be expressed by the following equation. Here, the torque is analyzed as a magnetic field generated in the stator and the rotor, but this is merely exemplary and may be analyzed as a current generated in the stator and the rotor.

[ MATHEMATICAL FORMULATION 10 ]

τ＝kB_SB_m

At this time, the magnetic field resolved in the equivalent circuit 1440 of the rotor is proportional to the current flowing in the rotor coil according to Biot-Savart law (Biot-Savart). Therefore, as can be seen from equation 9, the torque is proportional to the currents flowing through the stator and the rotor, which can be actively controlled independently. On the other hand, in the case of a normal motor, the current flowing in the rotor is induced or derived from the stator, and in order to control it, the stator is controlled. Therefore, the electromagnetic machine according to the present application can be driven by independent current combinations of the stator and the rotor, and when the electromagnetic machine is used, the possible torque range is wide, the reaction time can be shortened, and the efficiency can be optimized. In addition, the electromagnetic machine according to one embodiment of the present application is easy to ensure safety when in use.

FIG. 6 is a schematic illustration of a generalized wind-powered Doubly-fed Electromagnetic Machine (double Active Electromagnetic Machine) including an Electromagnetic Machine according to one embodiment of the present application. In fig. 6, only an example of wind power generation is illustrated, but the application example is not limited thereto, and may be applied to a new renewable energy system such as tidal power generation or wave power generation, etc., which can include an electromagnetic machine according to an embodiment of the present application.

Referring to fig. 6, a doubly fed electromagnetic machine 1505 for wind power generation including an electromagnetic machine according to an embodiment of the present application may electromagnetically embody a Continuously Variable Gear Ratio (Continuously Variable Gear Ratio) without a transmission, which is a power generation or regenerative braking device that may generate a large driving torque. The rotary blade 1501 is connected to the electromagnetic machine 1500 via a power shaft 1502. The output of the electromagnetic machine 1500 is transmitted to a load 1506 via a power conversion device 1503 and a power grid 1504.

Therefore, in the double feed electromagnetic mechanical system including the electromagnetic machine according to one embodiment of the present application, the driving torque and speed can be efficiently controlled without a transmission, thereby having advantages that the size can be reduced and the efficiency can be increased. In addition, since there is no physical gear, it is possible to quickly cope with a failure.

Fig. 7 and 8 are schematic diagrams for a vehicle including a generalized In-wheel (In-wheel) drive motor to which an electromagnetic machine according to one embodiment of the present application is applied. In fig. 7 and 8, only an example of the in-wheel drive motor is described, but the application example is not limited thereto. On the other hand, fig. 7 is a schematic configuration diagram relating to driving of a vehicle including the electromagnetic machine of the present application, and fig. 8 is a schematic configuration diagram relating to braking of a vehicle including the electromagnetic machine of the present application.

Referring to fig. 7, an energy source, such as a dc power source of the battery 1601, is converted into an ac power source via an inverter 1604. The electric power thus converted, if applied to the electromagnetic machine 1600 according to an embodiment of the present application, generates a driving force, which is transmitted to each wheel via a power shaft (not shown in the drawings) to drive the vehicle.

Referring to fig. 8, when braking, an inertial force of a running vehicle is transmitted to an electromagnetic machine 1700 according to an embodiment of the present application via the power shaft, and a Regenerative braking state is achieved. At this time, the generated power is converted into heat by the inverter 1704, and used as an energy source, for example, a battery 1701 or a capacitor 1702, or dissipated in a brake resistor 1703.

Therefore, by means of the in-wheel motor comprising the electromagnetic machine according to one embodiment of the application, the size of the motor is minimized, the motor is additionally arranged on each wheel, the driving torque and the speed of each wheel are independently and respectively and efficiently controlled, and therefore the stability of a vehicle can be ensured, and the driving performance is improved. In particular, since the rotor is independently controlled without a physical gear, the reaction time is short, and the driving situation can be quickly dealt with.

Fig. 9 shows forces between a stator and a mover (rotor) according to an embodiment of the present application. The mover is movable in the x direction (in a rotary electromagnetic machine, x is an axial rotation direction). The mover does not move in the y or z direction, and the force in the z direction means the direction of the attraction or repulsion force between the mover and the stator.

An alternating magnetic field is generated at the air gap if the polyphase coils of the stator are driven with DC currents, and at the air gap if the polyphase coils of the mover are driven with DC currents. With a spatial period of the magnetic field of 0.01m in the x-direction, the currents of the polyphase coils effect a magnetic field lock in the y-direction, the magnetic field of the air gap changing periodically in the x-direction.

The graph may be displayed as the restoring force, the force in the x-direction required to return to a stable equilibrium position, (-0.5 cycles < x <0.5 cycles), and the repulsive force, the force required to push the mover to a stable position. The point where (0.5 × cycle < x <1.0 × cycle) x ═ 0.5 × cycle is a saddle point (saddlepoint). The force and displacement act as a periodic function of the mover's deflection angle. A restoring force exists at a position where the mover and the stator face each other with opposite polarities to each other, and if this condition is satisfied, it is defined that the mover and the stator are in "Field locking". The magnetic field lock may be maintained with the stator, and the mover generates an additional rotating magnetic field during rotation of the mover.

Magnetic Field locking (Field locking) may be formed in an electromagnetic machine having a gap (air gap) with a predetermined interval between a stator having a multi-phase coil capable of generating a moving magnetic Field and a mover having a multi-phase coil capable of separately generating a moving magnetic Field, the mover being movable while maintaining the predetermined interval in a current flowing direction and a normal line direction. The moving magnetic field is generated by being concentrated in the gap, and the vector direction of the magnetic field, the current flowing direction and the moving direction of the moving body have a mutually perpendicular relation.

The magnetic field locking phenomenon is a stable state in which magnetic fields generated by currents flowing in respective multi-phase coils of the stator and the mover are kept facing each other with polarities of the magnetic fields opposite to each other. If the mover is moved by an external force while being out of the stable state, a restoring force to return to an original state is generated, and when the moving distance is small, the restoring force is proportional to the moving distance and the direction of the force is opposite to the moving direction.

Before the electromagnetic machine starts driving, magnetic field locking is formed, and during driving, the starting current (In-rush current) at the start of driving is kept below a rated level to start driving. The magnetic field lock is maintained during driving, so that the torque required in a wide dynamic operation region can be quickly responded, and the safety can be ensured by a Bi-directional power transfer (Bi-directional power transfer) function.

The rotor position may be stable when the mover and the stator are facing with opposite polarities to each other. If the mover and the stator are displaced in such a manner that the same poles face each other, the repulsive force pushes the mover toward a stable region. The restoring force is present at opposite pole faces, whereas the repulsive force occurs at similar pole faces.

During operation of the motor, external loads, such as friction, on the shaft may apply f _ ext (f _ ext <0), and the mover position may be away from a stable equilibrium (x <0, fx > 0). An electric motor means a device that performs a task of converting an electric quantity into mechanical energy.

During operation of the generator, an external load pushes the mover with f _ ext >0 in the x-direction, and the external force can be balanced by means of a restoring force fx <0. In this case, the generator means a device that converts mechanical work into electric energy.

The stator and the mover of the electromagnetic machine according to the embodiments of the present application may be formed in a coil array. For example, it may be formed in a coil array as shown in fig. 10. Next, the coil array constituting the stator and the mover will be specifically described.

The stator includes a first coil array, the mover includes a second coil array formed at a predetermined interval from the first coil array, having mirror images in spaced directions, the first coil array includes at least one first half cycle and at least one second half cycle formed adjacent to each other, the first half cycle may include at least two coils having current flowing directions different from each other, and the first half cycle and the second half cycle may have mirror images in adjacent directions.

Fig. 10 is a schematic cross-sectional view schematically illustrating current flow and magnetic flux magnitude of a coil array of a stator and a mover according to an embodiment of the present application. As shown in fig. 10, a coil array 2100 according to one embodiment of the present application includes a first coil array 2110 and a second coil array 2120. Hereinafter, the coil array means a coil array of the stator and the mover.

The first and second coil arrays 2110 and 2120 are formed at predetermined intervals, and have Mirror images (Mirror images) in the spaced directions. That is, the first coil array 2110 and the second coil array 2120 have mirror images with the x-axis as the axis of symmetry. Here, the mirror image has a structure corresponding to each other with the axis of symmetry as a center, and means a structure like a mirror.

At this time, the first coil array 2110 includes at least one first half period and at least one second half period formed adjacent to each other. The first half-cycle 2150 and the second half-cycle 2160 are formed into one cycle, and each space period λ can be used_SRepeating the same structureA periodic morphology is formed. The first half-cycle 2150 includes at least two coils whose current flow directions are different from each other, and the first half-cycle and the second half-cycle have mirror images in adjacent directions. That is, first half-cycle 2150 has a symmetry axis about the z-axis, which is a mirror image of second half-cycle 2160.

If referring to fig. 10, the first coil array 2110 is spaced apart from the second coil array 2120 by a predetermined interval in the z-axis direction, i.e., by an air gap (air gap) d. The distance between the first coil array 2110 and the second coil array 2120 may be set by a magnetic flux or other means so as to be embodied by the coil array, and may be set by a user.

First half period 2150 includes at least two coils whose current flow directions are different from each other. Fig. 10 shows an embodiment in which first half period 2150 is formed in a plurality of layers, but this is just one example, and first half period 2150 may include at least two coils whose current flow directions are different from each other. The current flow directions of the two coils may be opposite to each other. The current of one coil may flow in a direction (+ y direction) flowing into the plane of fig. 10, and the current of the other coil may flow in a direction (-y direction) flowing out of the plane of fig. 10. When a current flows in one direction in the coil, a magnetic field is formed in the coil. When current flows in the plane of fig. 10, a magnetic field is formed in the clockwise direction of the winding coil, and when current flows out of the plane of fig. 10, a magnetic field is formed in the counterclockwise direction of the winding coil. Here, the two coils included in the first half period 2150 may be coils included in the first layer (1st upper layer) on the first half period 2150 of fig. 10. The magnetic field between the two coils is formed in the direction of the second coil array 2120 by the counterclockwise magnetic field generated by the coil located on the right side and having the current flowing out of the plane and the clockwise magnetic field generated by the coil located on the left side and having the current flowing in the plane, and the magnetic flux is intensified.

A second half cycle 2160, having a mirror image of the first half cycle 2150, forms a coil on the right side where current flows into the plane and a coil on the left side where current flows out of the plane, in a manner different from the first half cycle. Since the coil of the second half cycle 2160 and the coil of the first half cycle 2150 are formed in opposite directions to each other in terms of current flow, a magnetic field between the two coils is formed in the opposite direction to the second coil array 2120, and magnetic flux is intensified.

The first coil array 2110 and the second coil array 2120 may be formed in a plurality of layers. The layer may be formed in a plurality of layers of 2 or more. The number of layers is exemplarily shown as 4 in fig. 10, but is not limited thereto, and the number of layers may be less or additional layers may be further included according to need.

The first coil array 2110 and the second coil array 2120 may be formed in 3 layers.

The first layer of the first half period 2150 may include at least 11 coils in which current flows in different directions from each other. For example, the left side coil of the first layer is a coil showing a current flowing into a plane, and the right side coil is a coil showing a current flowing out of the plane. The second layer of the first half period 2150 has the same coil current direction as the first layer, but is disposed relatively outside the coil of the first layer.

In addition, the third layer of the first half period 2150 has a coil current direction opposite to that of the second layer. That is, the left coil of the third layer is a coil showing a current flowing out of the plane, and the right coil is a coil showing a current flowing in the plane. On the other hand, the third layer coil is disposed relatively more inward than the second layer coil. The fourth layer of the first half period 2150 has the same coil current direction as the third layer, but is disposed relatively outside the coil of the third layer.

Alternatively, the first coil array 2110 and the second coil array 2120 may be formed as a lower layer and an upper layer. Wherein the lower layer may correspond to the first layer of fig. 10, and the upper layer may correspond to the third layer of fig. 10. The first layer and the third layer may be formed alone without including the second layer and the fourth layer.

On the other hand, the current directions of the first half period 2150 and the second half period 2160 shown in fig. 10 are exemplarily shown for illustration, but are not limited thereto, and may have the above-mentioned relationship in the current direction that varies with time, and the current direction in the coil may vary with time. The relative positions of the coils and the number of coils in each layer shown in fig. 10 are shown by way of example for illustrative purposes, but the present invention is not limited thereto, and the positions of the coils and the number of coils may be changed without departing from the scope of the present invention.

The first coil array 2110 may be formed in a coil structure having the above-described current distribution. Here, the first coil array 2110 and the second coil array 2120 are exemplarily shown as a stacked coil structure 2130, or a horizontally stacked coil structure 2140 and a vertically stacked coil structure 2145, but not limited thereto, and a planar structure having a current distribution as shown in fig. 10 may be substituted instead of the three-dimensional stacked structure as needed.

The coil array 2100 according to an embodiment of the present application has a structure in which Magnetic flux (Magnetic flux) is intensified in one direction and cancelled in the other direction. That is, if referring to fig. 10, the first coil array 2110 and the second coil array 2120 are intensified in the z-axis direction toward the sides facing each other, and in the other direction, the magnetic flux is relatively cancelled or appears to be almost negligible. Therefore, the coil array 2100 according to the present application has an effect that a leakage magnetic field can be minimized outside the region of interest.

Fig. 11 is a diagrammatic, schematic cross-sectional view showing a coil array in accordance with an embodiment of the present application in 2 phase difference coil array groups.

Referring to fig. 11, a coil array 2200 according to an embodiment of the present application includes a coil array group 2201 for phase a and a coil array group 2202 for phase B that are 90 degrees out of phase with each other. The two coil array groups may have phases different from each other or may have the same phase as each other. The coil array 2200 arranges the coil array group 2202 for phase B between the coil array groups 2201 for phase a so that the groups are arranged alternately.

Therefore, to the coil array group 2201 for phase a and the coil array group 2202 for phase B, a current that changes with time is sequentially supplied by phase difference, whereby a moving magnetic field (not shown in the figure) can be formed. If such a moving electromagnetic field is utilized, the same effect as that of the stator of the electromagnetic machine can be exhibited. On the other hand, in fig. 11, the phases of the coil array 2200 are shown in two phases, but the present invention is not limited thereto, and a coil array of three or more phases may be realized by adding groups and alternately overlapping them in sequence as necessary.

Fig. 12 is a schematic cross-sectional view schematically illustrating the magnitude of the magnetic flux and the current flow of a coil array according to an embodiment of the present application.

As shown in fig. 12, in the coil array 2300 according to the embodiment of the present application, a first coil array 2310 and a second coil array 2320 are included. At this time, the second coil Array 2320 is the same as the coil Array shown and described in detail in fig. 10, but the first coil Array 2310 may be configured in a Halbach Array (Halbach Array) as a specific structure of the coil Array shown and described in detail in fig. 12. Additionally, for such coil array 2300, the magnetic flux may be intensified between first coil array 2310 and second coil array 2320, where the magnetic flux may be reduced to a relatively negligible degree or cancelled out. On the other hand, in fig. 12, the first coil array 2310 is shown as a halbach array, but the present invention is not limited thereto, and the second coil array 2320 may be used as a halbach array, or both the first coil array 2310 and the second coil array 2320 may be used as a halbach array, as necessary.

Fig. 13 is a schematic perspective view of a coil array structure according to an embodiment of the present application.

As shown in fig. 13, in the coil array 2400 according to the embodiment of the present application, the first coil array 2410 and the second coil array 2420 repeat the same structure every spatial periodic time along the x-axis direction. In the periodic structure, the first coil array 2410 and the second coil array 2420 have a sectional toroidal (Toroid) or sectional Solenoid (Solenoid) current distribution, in which the length thereof is extended in the current flowing direction (i.e., the y-axis direction).

In addition, a mobile electromagnetic machine (not shown) including the coil array 2400 according to an embodiment of the present application may be embodied in a coreless structure or a minimal iron core. Therefore, the minimum core is used in the electromagnetic machine, so that efficiency can be maximized, weight and size can be minimized, and it is expected that core loss due to the use of the core can be reduced.

In addition, the magnetic field generated by the coil array according to the embodiment of the present application periodically changes in one direction. All these properties can be achieved even without the use of a core, only with the coil array according to the embodiments of the present application. In particular a magnetic field generated by a coil array according to embodiments of the present applicationCan be approximated as a sine wave as follows.

[ mathematical formula 11 ]

Wherein λ is_SIs the spatial period of the magnetic field. In the case of moving electromagnetic machines, λ_STo fix the spatial periodicity of the coils (in m), the spatial periodicity of the mover coil can be in λ_mAnd (4) expressing. This is one of the coil design elements of the stator of an electromagnetic machine. The stator coils may comprise multiple cycles of an electromagnetic machine. That is, the superscript (a) indicates the coil (phase) a. The magnetic flux density is mostly strengthened in the z-axis direction.

On the other hand, the other directional component of the magnetic flux density is assumed to be sufficiently negligible, and as shown in the coil array of one embodiment of the present application, the space between the complementary coil arrays, especially the other directional component, is sufficiently negligible. The magnetic field of the stator can be expressed in the following mathematical expression proportional to the stator current.

[ MATHEMATICAL FORMULATION 12 ]

B₀＝k_SI_S

In addition, for coil (phase) B, the coil array according to the embodiment of the present application may generate different magnetic fluxes. Coil (phase) B is physically shifted by λ from coil (phase) A_S/4, magnetic field of coil (phase) BCan be expressed as follows.

[ mathematical formula 13 ]

Wherein k is_SPropagating (2propagation) vectors, k, for the first coil array (stator)_S＝2π/λ_S. The propagation vector of the second coil array (mover) may be in k_m＝2π/λ_mAnd (4) showing.

The analysis of the coil array according to embodiments of the present application is exemplarily performed using a two-phase coil structure. Even if such a two-phase coil structure is assumed, the concept is the same and the generality is not impaired. The analysis can also be extended to multi-phase coil configurations, such as three-phase coil configurations, and the analysis results and conclusions can be applied equally to multi-phase systems. Differences between two-phase systems and three-phase systems may be mentioned if desired. On the other hand, three sets of coils, called U, V and W coils, are generally required for a three-phase system. The V and W coils are spatially phase shifted by λ compared to the U coil_S/3、2λ_S/3。

In the coil array according to the embodiment of the present application, the magnetic field generated by the complementary first and second coil arrays has the following characteristics:

the magnetic field between the first coil array and the second coil array is strengthened to one side in the z-axis direction (i.e., between the coil arrays). Except for the side where the magnetic field is intensified, it is almost cancelled out to the other side (i.e., outside the coil array).

On the other hand, the coil (phase) a of the coil array according to the embodiment of the present application independently occurs and overlaps with the magnetic field generated in the coil (phase) B. The coil a and the coil B are electrically driven with a phase difference of 90 degrees, and generate a traveling magnetic field. A magnetic field B modulated by overlapping the coil A and the coil B_Z(x) Can be expressed as follows.

[ CHEMICAL EQUATION 14 ]

On the other hand, if referring to equation 1 and equation 3, equation 4 above can be expressed as follows.

[ mathematical formula 15 ]

B_Z(x)＝B₀(k_Sx)cos(ω_St)+B₀(k_Sx)sin(ω_St)＝B₀cos(k_Sx-ω_St)

Wherein, ω is_SIs the period of the first coil array current and the frequency f of the first coil array current_SHas a relationship of ω_S＝2πf_S。

The waveform pattern of the magnetic flux density as described above is related to the velocity v_SA moving magnetic field moving in the same direction as the x-axis.

[ mathematical formula 16 ]

In the coil pair, the direction of the wave pattern moving in the negative x-axis direction can be changed by means of a change in the sign of the current or time modulation.

An electromagnetic machine can be fabricated by supplying a current through a stator coil including a coil array according to an embodiment of the present application to generate a magnetic field, and providing a mover along a coil in which a current can flow perpendicular to the magnetic field.

A moving electromagnetic machine can be constructed using an array of coils as described above. A moving electromagnetic machine according to an embodiment of the present application may include a stator and a mover, and the stator may include a first coil array, the first coil array may include at least one first half cycle and at least one second half cycle formed adjacent to each other, the first half cycle may include at least two coils having current flow directions different from each other, and the first half cycle and the second half cycle may have mirror images in the adjacent directions. The detailed description of the coil array included in the moving electromagnetic machine according to one embodiment of the present application corresponds to the detailed description of the coil array according to the embodiment of the present application described above, and the redundant description is omitted below.

Or, the stator may further include a second coil array formed at a predetermined interval from the first coil array, and having a mirror image in an interval direction, and the mover may be formed between the first coil array and the second coil array.

Alternatively, the mover may include a second coil array formed at a predetermined interval from the first coil array, and having a mirror image in the spaced direction. That is, the first coil array and the second coil array of the coil array according to the embodiment of the present application may be a stator or a mover, respectively.

In addition, the mover may be a rotor.

Assuming wires through which current can flow in both directions of the y-axis, it is assumed that the mover is allowed to move in the x-axis direction. The Lorentz force deltaF if the amount of current flowing through the wire is called i_x(x) The length of the electric wire 1 (the length of the region where 1 is preset for the magnetic flux) can be expressed by the following equation.

[ mathematical formula 17 ]

δF_x(x)＝lI_y(x)B_z(x)

Wherein, I_y(x) Is the current flowing from position x in the y direction. By a function of x, an array of wires through which current flows can be formed, in particular a current distributed over the mover, having the same (spatial) period as the stator.

[ 18 ] of the mathematical formula

Wherein x is_mMay be the x-direction coordinate of the second coil array (mover), and the x-direction coordinate of the first array (stator) may be represented by x_SAnd (4) showing.

Thus, it is meant that a current on the mover occurs, which current may be a situation in which the mover (or possibly the rotor) moves relatively. In principle, a sinusoidal wave distribution of current can be achieved by stacking with a very small circuit loop, and the number of wires per unit length can be expressed as follows.

[ mathematical formula 19 ]

When a small current i flows through the electric wire, it can be expressed as follows.

[ mathematical formula 20 ]

I₀＝n₀i

It is not easy to realize a sine wave current density distribution.

[ mathematical formula 21 ]

When is h (x)_m)＝1，When is h (x)_m)＝0。

Wherein, h (x)_m) Is of a period lambda_SIs used to determine the period function of (2). For example, φ is an arbitrary initial phase value of the mover.

Fig. 14 is a conceptual diagram schematically illustrating the interaction of magnetic fields and electric currents generated by a coil array structure according to one embodiment of the present application.

If referring to fig. 14, lorentz forces occurring in the electric wires through which the currents flow by means of the interaction of the magnetic field generated by the coil array according to one embodiment of the present application with the currents can be expressed in the x-axis direction as follows. On the other hand, the forces occurring in the stator, along the x-axis, occur in the same magnitude but in opposite directions every half period.

[ mathematical formula 22 ]

δF_x(x)＝lB_SI_mcos{k_Sx_S-ω_St}cos{k_S(x_S-v_mt)-ω_mt-φ}

Suppose x_mTo relative to x_SVelocity v of_mAnd (4) moving. The relationship is as follows.

[ mathematical formula 23 ]

x_m＝x_S-v_mt

The force per cycle can be calculated as follows.

[ mathematical formula 24 ]

δF_x(xs)＝lB_sI_mcos{k_sx_S-ω_St}cos{k_S(x_S-v_mt)-ω_mt-φ}

δF_x(x_S)＝lB_SI_mcos{k_Sx_S-ω_St}cos{k_Sx_S-(ω_m+k_Sv_m)t-φ}

Mathematical formula 14 may be organized as shown in the following formula.

[ mathematical formula 25 ]

The first term of equation 25 varies rapidly in both space and time. Regardless of time, if the force is accumulated over many spatial periods, the average value disappears. Each spatial period λ_SThe force of (M is sufficiently large to be combined over M cycles) can be expressed by the following equation.

[ 26 ] of the mathematical formula

The cycle average force for any periodic current distribution can be calculated. Harmonic components of the same fourier series expansion are generated as the current average value 0, thereby showing the same result.

The periodic relationship of the currents driven in the mover is as shown in the following equation.

[ mathematical formula 27 ]

(ω_m+k_Sv_m)＝ω_s

That is, the moving magnetic field occurring in the mover means that the resultant magnetic field is synchronized with the moving magnetic field generated by the stator. The spatial periods of the mover and the stator have the same value, and thus the magnetic poles (magnetic poles) of the mover and the stator are attracted to opposite sides, so that the magnetic flux paths are synchronized with each other and Field locked (Field lock).

If the mover and the stator are field-locked to each other, the position of the mover (rotor) is in a balanced position, and the average magnetic force between the mover and the stator is 0 in a balanced state. Phi denotes the electric field phase difference and is proportional to the position offset from the equilibrium between the mover and the stator.

[ mathematical formula 28 ]

When phi is 0, the external force or torque is unchanged, and the field lock positions the mover in the equilibrium position. If the mover moves from the balanced state, a magnetic force occurs and the mover moves to the balanced position. On the other hand, if an external force or torque is applied to the mover, the magnetic force generated by the attraction of the opposite-side magnetic poles corresponds to the external force. At this time, the position of the mover changes with the external force. The magnitude of the reaction is proportional to the product of the stator current and the mover current, and the total magnetic force or torque is proportional to the number of spatial periods.

Wherein, if cos φ is positive and preset, a steady force occurs in the mover due to the interaction of the stator and the mover (or the rotor), the force opposes friction, pushing the mover. At this time, the power supply mechanism of the stator and the mover supplies power to move the mover in order to maintain a slow acceleration or a steady state with respect to friction. When Φ is 0, the maximum force occurs.

When the moving electromagnetic machine according to one embodiment of the present application is used as a motor, during the supply of current, the conditions shown in the following formula are maintained.

[ mathematical formula 29 ]

cos{(ω_S-ω_m+k_Sv_m)t-φ}≥0

The condition of cos phi <0 is a steady state condition when the mover (rotor) is pushed by an external force. Negative force means that work is performed by external force. That is, the moving electromagnetic machine according to one embodiment of the present application operates as a generator. A current flows through the mover coil, thereby generating power.

In case of steady-state forces, the mover is at a speed v_mMoving, the current at the same speed v as the magnetic field generated by the stator_SAnd (4) moving. When the frequency of the mover is the same as that of the stator and no external force is applied, the mover maintains a fixed position. However, if the mover and the stator are driven at different frequencies and the magnetic field moves in the same direction, the mover (rotor) axis is driven at v_S-v_mAnd (4) moving. When the Field Rotation (2Field Rotation) is in the opposite direction, the rotor (rotor) shaft Rotation speed is the sum of the stator Field Rotation speed and the rotor (rotor) Field Rotation speed. Thereby, a fast rotation can be achieved.

Magnetic field in stator with velocity v_SWhen moving, it can be expressed as follows.

[ mathematical formula 30 ]

v_S＝ω_S/k_S

When a steady force is generated in the mover, it is the case that the mover (rotor) moves at an extremely slow acceleration or the force and the external force achieve equilibrium, and at this time, moves at a uniform speed.

Fig. 15 is a schematic sectional view schematically showing a coil array having a laminated coil and applied in a horizontal direction according to an embodiment of the present application.

Referring to fig. 15, the coil array 2600 according to the embodiment of the present application has a lamination type coil and is embodied in a periodic structure in the x-axis direction. At this time, the coil array 2600 is embodied by the first coil array 2610 and the second coil array 2620 spaced apart by a predetermined interval in the z-axis direction. In addition, the magnetic flux density is intensified in a direction between the first coil array 2610 and the second coil array 2620, and the magnetic flux density is offset in a direction facing each other in the first coil array 2610 and the second coil array 2620, thereby minimizing a leakage magnetic field in the outside.

Fig. 16 is a schematic sectional view schematically showing a coil array having a lamination type coil and applied in a three-dimensional structure according to an embodiment of the present application.

Referring to fig. 16, a coil array 2700 according to an embodiment of the present application has a lamination type coil, embodied in a circular shape. At this time, the coil array 2700 according to an embodiment of the present application is spaced apart by a predetermined interval in a radiation (radial) direction, and the first coil array 2710 and the second coil array 2720 repeat the same structure in each spatial period in a tangential direction. In addition, the first coil array 2710 and the second coil array 2720 are complementarily embodied with each other. That is, the first coil array 2710 can be regarded as a mirror image of the current distribution of the second coil array 2720 with respect to the tangential direction. In addition, the first coil array 2710 and the second coil array 2720 arranged in a circular shape are directed in the radiation direction, and the magnetic flux density is intensified to one side between them and cancelled to the other side outside them.

On the other hand, the first coil array 2710 and the second coil array 2720 are arranged on the circumference, and are shown to have a short size and almost the same size, but the present invention is not limited thereto, and the size of the coil array on the inner circumference may be reduced or the size of the coil array on the outer circumference may be increased as necessary within a range not to impair the spirit of the present invention.

Fig. 17 is a diagram of simulation results for a structure to which a coil array according to an embodiment of the present application is applied in a three-dimensional structure.

The graph of the simulation results was calculated based on the Biot Savart law using the python program (Biot-Savart). If referring to fig. 17, results obtained near the middle of the gap between the first coil array 2710 and the second coil array 2720 for the coil array 2700 shown in fig. 16 are shown. Thus, at the center of the gap between the first coil array 2710 and the second coil array 2720, the magnetic flux is intensified in the radial (radial) direction, and relatively little magnetic flux is present in the axial (axial) or tangential (tangential) direction.

Fig. 18 is a diagram of simulation results for a structure to which a coil array according to an embodiment of the present application is applied in a three-dimensional structure.

Referring to fig. 18, results obtained from the first coil array 2710 and the second coil array 2720 of the coil array 2700 of fig. 16 are shown near the outside of the region of interest that is half the size of the gap. Therefore, it was confirmed that there was almost no leakage magnetic flux in all directions. On the other hand, the region of interest means an inner portion including the first coil array 2710 and the second coil array 2720.

Fig. 19 is a schematic sectional view schematically showing a coil array having a planar coil structure and to which an embodiment according to the present application is applied.

If referring to fig. 19, the coil array 2800 of the present embodiment periodically embodies a planar coil structure in the x-axis and z-axis directions. At this time, the coil array 2800 is intensified in the + direction magnetic field of the z axis, and is relatively weakened in the-direction magnetic field.

Fig. 20 is a schematic sectional view schematically showing a coil array having a planar coil structure and applied in a three-dimensional structure according to an embodiment of the present application.

If referring to fig. 20, the coil array 2900 of the embodiment of the present application has a planar coil structure, embodied in a circle. At this time, the coil array 2900 according to the embodiment of the present application is embodied as the first coil array 2910 and the second coil array 2920 which are complementary to each other, with a predetermined interval in the radiation direction.

Fig. 21 is a diagram of simulation results for a structure having a planar coil structure and to which a coil array according to an embodiment of the present application is stereoscopically applied. Referring to fig. 19, if a strong magnetic field appears in the radiation direction near the center of the air gap in the region of interest, the magnetic field is cancelled to a negligible extent in the axial direction or the tangential direction. Although not shown, as shown in the results of fig. 16, it was confirmed that there was almost no leakage magnetic field outside the region of interest.

The moving electromagnetic machine using the coil array according to the embodiments of the present application intensifies the one-sided magnetic field within the region of interest, while almost eliminating the leakage magnetic field outside the region of interest. In addition, the moving electromagnetic machine according to an embodiment of the present application does not use or minimally uses the core, so that it is possible to minimize the size and weight thereof, reduce core loss, overcome performance limitations, and the like.