Existing electrical machines provide the ability to capture power from a mechanically rotating source, such as a wind turbine or deliver power to load such as a pump or compressor. A synchronous machine may therefore comprise a synchronous motor or a synchronous generator. As an example, a synchronous motor includes a stator, which carries an armature winding, and a rotor, which carries a field winding and which rotates at a supply frequency or a submultiple of the supply frequency. The armature winding is spatially distributed for poly-phase alternating current (AC), which creates a rotating magnetic field inside the synchronous motor. The magnetic field on the rotor is either generated by current delivered through slip rings and brushes to the field winding of the rotor or by a rotor comprised of a permanent magnet. On excitation through carbon brushes connected to slip rings on the rotor shaft, the field winding behaves as the equivalent of a permanent magnet. A drawback to synchronous machines utilizing brushes and slip rings is that the slip rings and brushes present reliability and maintenance issues because they are often a source of mechanical failure. Conversely, embodiments utilizing a permanent magnet are becoming increasingly expensive due to the scarcity of the raw materials used to form the permanent magnet.
A brushless, synchronous motor is provided that includes a rotor, a stator extending around at least a portion of the rotor and separated from the rotor by an air gap, a first stator winding, a second stator winding, a third stator winding, a drive circuit, a first rotor winding, a second rotor winding, and a diode bridge. The first stator winding, the second stator winding, and the third stator winding are mounted to the stator to generate square waves. The drive circuit is configured to provide a current to the first stator winding, the second stator winding, and the third stator winding, wherein the current includes an alternating current (AC) component and a direct current (DC) component. The first rotor winding is mounted to the rotor to form a plurality of third harmonic coils. The second rotor winding is mounted to the rotor. The generated square waves induce a voltage in the first rotor winding that is applied to the second rotor winding to create a brushless, synchronous motor. The diode bridge is mounted to the rotor to rectify the voltage induced in the first rotor winding and to apply the resulting DC voltage to the second rotor winding.
A method of operating a brushless, synchronous motor is provided. A current is provided to a first stator winding, a second stator winding, and a third stator winding. The current includes an alternating current (AC) component and a direct current (DC) component. The first stator winding, the second stator winding, and the third stator winding are mounted to a stator. A first rotating magnetomotive force (MMF) is generated in an air gap between the stator and a rotor in response to the AC component. A second rotating MMF is generated in the air gap between the stator and the rotor in response to the DC component. A voltage is induced in a first rotor winding mounted to the rotor to form a plurality of third harmonic coils. The induced voltage is rectified using a rectifier. The rectified voltage is applied to a second rotor winding mounted to the rotor to cause rotation of the rotor.
Other principal features and advantages of the invention will become apparent to those skilled in the art upon review of the following drawings, the detailed description, and the appended claims.
Illustrative embodiments of the invention will hereafter be described with reference to the accompanying drawings, wherein like numerals denote like elements.
a depicts a first layout diagram of stator and rotor windings in accordance with a first illustrative embodiment of the synchronous machine of
b depicts a block diagram of a circuit represented by the first layout diagram of
a depicts a second layout diagram of stator and rotor windings in accordance with a second embodiment of the synchronous machine of
b depicts a field magnetomotive force (MMF) generated using the stator and rotor windings represented by the second layout diagram of
a depicts a third layout diagram of stator and rotor windings in accordance with a third embodiment of the synchronous machine of
b depicts a field MMF generated using the stator and rotor windings represented by the third layout diagram of
With reference to
As shown with reference to the illustrative embodiment of
As shown with reference to the illustrative embodiment of
In a synchronous motor, application of three-phase AC power to stator 102 causes a rotating magnetic field to be setup around rotor 104. In a conventional machine, rotor 104 may be energized with a direct current (DC) through slip rings and brushes. The rotating magnetic field attracts the rotor field activated by the DC resulting in a turning force on shaft 106.
The magnetomotive force (MMF) produced in air gap 134 for motor 100 can be expressed by the winding function
F(φ,i)=Σi=1mNi(φ)ii(t) (1)
where φ 130 denotes the angular measure around air gap 134 of machine 100, Ni(φ) is the winding function describing the position and polarity of all of the coil sides of the winding of interest 112, 118, 124, and ii(t) is the current in the respective winding. The MMF for a three phase winding can therefore be expressed as
F
ABC(φ,i)=NA(φ)iA(t)+NB(φ)iB(t)+NC(φ)iC(t). (2)
In conventionally wound three phase armatures, the three currents are considered to be a balanced three phase set and the three winding functions are configured to approximate sinusoidal functions of the angle which are also balanced (mutually displaced by 120° with respect to φ). The result can be shown to produce a constant amplitude uniformly rotating MMF along the air gap as known to a person of skill in the art.
If windings are instead configured to have a full pitch and concentrated layout as shown with reference to machine 100 of
A drive circuit generates three armature currents, iA(t), iB(t), iC(t), that are applied to first full pitch winding 112, second full pitch winding 118, and third full pitch winding 124, respectively, and have the form
Utilizing equation (2), the MMF becomes
Rearranging equation (10), the MMF becomes
The first of the four terms produces a rotating constant amplitude uniformly rotating vector corresponding to the fundamental component of the current I1. The second and third terms are zero because the sum of three balanced sine waves is zero. The fourth term is an additional term which is defined here as
As a result, neglecting harmonics higher than the third, first full pitch winding 112, second full pitch winding 118, and third full pitch winding 124, or the armature windings, produce two components of MMF that are decoupled from each other, a first MMF being the normal, constant amplitude, uniformly rotating MMF and a second MMF defined by equation (12), which is stationary in space. Of note, the “zero sequence” component or second MMF term, which normally is considered to involve only the third harmonic component with respect to time, can be a pulsating component the frequency of which is arbitrary and includes zero (DC).
If the second MMF term involves only a DC component I0, the additional stator component of stator MMF appears in the reference frame of rotor 104 as
where θr 132 is the angle of rotor rotation with respect to a defined stator reference point as shown in
Assuming synchronous speed, i.e. θr=ωt, as a result, at any spatial position around the air gap φ, the rotor 104 experiences a sinusoidal constant amplitude MMF waveform.
With reference to
With reference to
With reference to
Because the zero sequence stator current creating the DC field current is DC, no inductive drop in stator 102 occurs to limit the field current that can be induced. Also, the current on the DC side of rectifier 406 is limited only by a very small resistance drop. Therefore, the maximum field current is set essentially by the reactive drop across first rotor winding 400. The current on the DC side of rectifier 406 (i.e. the field current) is proportional to the current on the AC side (i.e. the spatial third harmonic current). However, since the MMF created by the field winding is the product of the field turns times the DC current, multiple field turns can be utilized to produce whatever field MMF is desired. The limit is determined by both the reactive drop of the AC side and the resistance of the DC field winding.
With reference to
With reference to
With reference to
With reference to
The brushless concept can be expanded to include operation as a generator 900 providing power to an AC grid 902 or other load. Generator 900 may provide a constant 60 Hz power to AC grid 902. The added DC current component in the stator can be implemented using three silicon controlled rectifiers (SCRs) 904, 906, 908 as shown with reference to
A disadvantage of a synchronous motor using this concept is that it cannot be started from a standstill by applying a component of DC power to stator 102. However, this problem can be overcome by first utilizing an AC component for the zero sequence current rather than a DC one. For example, if a third time harmonic component is chosen, the MMF impressed on rotor 104 is
sin 3ωt sin 3(φ−θr, where θr≅0. The MMF at zero speed is then simply a third time harmonic. When the rotor speed begins to increase, frequencies 3(ωt−θr) and 3(ωt+θr) appear causing the amplitude to slowly pulsate. Because the third time harmonic now induces a voltage in the first rotor winding the motor can be started. A pulsating component however, produces noise and torque pulsations. Before the pulsating effect becomes pronounced, the pulsating or single phase component of current, In, can be switched to a DC value through control of the power converter.
An important application area for the use of machine 100 is as a motor fed from a sinusoidal power source. However, this case requires a more sophisticated control algorithm in order to start machine 100. In this case, the best choice for the neutral current, In, is the use of a single phase current. Since induced rotor current must flow to produce induction motor type starting torque, the rotor circuits may be short circuited by switches 1000 as shown with reference to
The word “illustrative” is used herein to mean serving as an example, instance, or illustration. Any aspect or design described herein as “illustrative” is not necessarily to be construed as preferred or advantageous over other aspects or designs. Further, for the purposes of this disclosure and unless otherwise specified, “a” or “an” means “one or more”. Still further, the use of “and” or “or” is intended to include “and/or” unless specifically indicated otherwise.
The foregoing description of illustrative embodiments of the invention have been presented for purposes of illustration and of description. It is not intended to be exhaustive or to limit the invention to the precise form disclosed, and modifications and variations are possible in light of the above teachings or may be acquired from practice of the invention. The embodiments were chosen and described in order to explain the principles of the invention and as practical applications of the invention to enable one skilled in the art to utilize the invention in various embodiments and with various modifications as suited to the particular use contemplated. It is intended that the scope of the invention be defined by the claims appended hereto and their equivalents.