US20120229060A1 - Variable coil configuration system, apparatus and method - Google Patents

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Classifications

• • H—ELECTRICITY
  • H02—GENERATION; CONVERSION OR DISTRIBUTION OF ELECTRIC POWER
  • H02M—APPARATUS FOR CONVERSION BETWEEN AC AND AC, BETWEEN AC AND DC, OR BETWEEN DC AND DC, AND FOR USE WITH MAINS OR SIMILAR POWER SUPPLY SYSTEMS; CONVERSION OF DC OR AC INPUT POWER INTO SURGE OUTPUT POWER; CONTROL OR REGULATION THEREOF
  • H02M7/00—Conversion of AC power input into DC power output; Conversion of DC power input into AC power output
  • H02M7/02—Conversion of AC power input into DC power output without possibility of reversal
  • H02M7/04—Conversion of AC power input into DC power output without possibility of reversal by static converters
  • H02M7/06—Conversion of AC power input into DC power output without possibility of reversal by static converters using discharge tubes without control electrode or semiconductor devices without control electrode
• • H—ELECTRICITY
  • H02—GENERATION; CONVERSION OR DISTRIBUTION OF ELECTRIC POWER
  • H02P—CONTROL OR REGULATION OF ELECTRIC MOTORS, ELECTRIC GENERATORS OR DYNAMO-ELECTRIC CONVERTERS; CONTROLLING TRANSFORMERS, REACTORS OR CHOKE COILS
  • H02P25/00—Arrangements or methods for the control of AC motors characterised by the kind of AC motor or by structural details
  • H02P25/16—Arrangements or methods for the control of AC motors characterised by the kind of AC motor or by structural details characterised by the circuit arrangement or by the kind of wiring
  • H02P25/18—Arrangements or methods for the control of AC motors characterised by the kind of AC motor or by structural details characterised by the circuit arrangement or by the kind of wiring with arrangements for switching the windings, e.g. with mechanical switches or relays
• • H—ELECTRICITY
  • H02—GENERATION; CONVERSION OR DISTRIBUTION OF ELECTRIC POWER
  • H02P—CONTROL OR REGULATION OF ELECTRIC MOTORS, ELECTRIC GENERATORS OR DYNAMO-ELECTRIC CONVERTERS; CONTROLLING TRANSFORMERS, REACTORS OR CHOKE COILS
  • H02P25/00—Arrangements or methods for the control of AC motors characterised by the kind of AC motor or by structural details
  • H02P25/16—Arrangements or methods for the control of AC motors characterised by the kind of AC motor or by structural details characterised by the circuit arrangement or by the kind of wiring
  • H02P25/18—Arrangements or methods for the control of AC motors characterised by the kind of AC motor or by structural details characterised by the circuit arrangement or by the kind of wiring with arrangements for switching the windings, e.g. with mechanical switches or relays
  • H02P25/188—Arrangements or methods for the control of AC motors characterised by the kind of AC motor or by structural details characterised by the circuit arrangement or by the kind of wiring with arrangements for switching the windings, e.g. with mechanical switches or relays wherein the motor windings are switched from series to parallel or vice versa to control speed or torque
• • H—ELECTRICITY
  • H02—GENERATION; CONVERSION OR DISTRIBUTION OF ELECTRIC POWER
  • H02P—CONTROL OR REGULATION OF ELECTRIC MOTORS, ELECTRIC GENERATORS OR DYNAMO-ELECTRIC CONVERTERS; CONTROLLING TRANSFORMERS, REACTORS OR CHOKE COILS
  • H02P29/00—Arrangements for regulating or controlling electric motors, appropriate for both AC and DC motors
  • H02P29/02—Providing protection against overload without automatic interruption of supply
  • H02P29/032—Preventing damage to the motor, e.g. setting individual current limits for different drive conditions
• • H—ELECTRICITY
  • H02—GENERATION; CONVERSION OR DISTRIBUTION OF ELECTRIC POWER
  • H02P—CONTROL OR REGULATION OF ELECTRIC MOTORS, ELECTRIC GENERATORS OR DYNAMO-ELECTRIC CONVERTERS; CONTROLLING TRANSFORMERS, REACTORS OR CHOKE COILS
  • H02P9/00—Arrangements for controlling electric generators for the purpose of obtaining a desired output
  • H02P9/02—Details of the control
• • Y—GENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
  • Y02—TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
  • Y02B—CLIMATE CHANGE MITIGATION TECHNOLOGIES RELATED TO BUILDINGS, e.g. HOUSING, HOUSE APPLIANCES OR RELATED END-USER APPLICATIONS
  • Y02B70/00—Technologies for an efficient end-user side electric power management and consumption
  • Y02B70/10—Technologies improving the efficiency by using switched-mode power supplies [SMPS], i.e. efficient power electronics conversion e.g. power factor correction or reduction of losses in power supplies or efficient standby modes
• • Y—GENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
  • Y02—TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
  • Y02E—REDUCTION OF GREENHOUSE GAS [GHG] EMISSIONS, RELATED TO ENERGY GENERATION, TRANSMISSION OR DISTRIBUTION
  • Y02E10/00—Energy generation through renewable energy sources
  • Y02E10/70—Wind energy
  • Y02E10/72—Wind turbines with rotation axis in wind direction

Definitions

• This application generally relates to electric machines with coils or windings (e.g., generators, motors), and more particularly to systems, apparatus and methods that configure coils or windings of multistage electric machines.
• coils or windings e.g., generators, motors
• the amount of energy captured from the energy source may only be a fraction of the total of the capturable energy. For example, in a typical wind farm, that fraction may be one half, or less of the total capturable energy.
• variable-speed conventional turbine/generator/transformer system The power flow though a variable-speed conventional turbine/generator/transformer system is restricted in the range of power that can be output, i.e., from a minimum output power to a rated output power, due to limitations of the generator, the power converter (if present), and/or the output transformer used within the system.
• This restriction arises because conventional electromagnetic generators have reduced efficiency at lower power levels, as does the power converter (if present) and particularly the transformer that couples power to the electrical load.
• an engineering design decision is usually made to limit the power rating of the generator (and any associated power converter, power conditioner or power filter, if present) and the associated output transformer so as to optimize efficiency over a restricted range of power.
• a multi-stage generator may be used in the turbine system.
• a multi-stage generator is an electric machine operating as an electrical generator that takes mechanical energy from a prime mover and generates electrical energy, usually in the form of alternating current (AC) power.
• AC alternating current
• Such a multi-stage generator is disclosed in U.S. Pat. No. 7,081,696 and U.S. Patent Application Publication No. 2008088200.
• An advantage of a multi-stage generator over a conventional generator is that a multi-stage generator can be dynamically sized depending on the power output of the turbine.
• a conventional generator is effective at capturing energy from the energy source over a limited range of fluid speeds, whereas a multi-stage generator is able to capture energy over an extended range of fluid speeds of the energy source, due to staged power characteristics.
• the electrical power that is generated from a multi-stage generator is variable in nature, meaning the output power waveforms produced may vary from time to time, for example in: voltage amplitude; current amplitude; phase; and/or frequency.
• a multi-stage generator may include a plurality of induction elements, each of which generates its own power waveform, which may differ in voltage amplitude, current amplitude, phase, and/or frequency, from that generated by other induction elements within the generator.
• An electrical load such as an electric utility power grid may not be capable of directly consuming the electrical power that is generated by a multi-stage generator, as the power generated may not be in a suitable form, for example with respect to waveform shape as a function of time, voltage amplitude, current amplitude, phase, and/or frequency, as may be required by the electrical load.
• An electrical load such as a utility power grid typically expects from a turbine electrical generation system a single-phase, or split-phase, or 3-phase voltage or current waveform that is usually sinusoidal, and relatively stable.
• a multi-stage generator typically generates varying waveforms.
• U.S. Pat. No. 3,984,750 is directed to an alternator-rectifier unit in which separate three-phase windings are connected to individual rectifiers arranged for series-parallel switching to improve current-voltage characteristics. Notably, such employs switching on the direct current (DC) side of the rectifier. Such circuit is associated with relatively high losses, experiencing four diode voltage drops. Such is not extended beyond a single coil configuration switch.
• U.S. Patent Application No. 2007/0182273 describes circuitry for configuring generator coils in various series/parallel combinations. This disclosure has 4 coils configured using 14 switches. Each switch carries multiple coil loads, up to full section current in parallel case. The system uses 12 switches in circuit for a series case, and up to 10 switches in circuit in parallel case.
• Embodiments of the present system and method include a variable configuration controller (referred to as a “VCC”) system and method to connect multiple generator coil windings in varying series or parallel combinations to maintain a relatively consistent output voltage (for example, within a 2:1 range) in response to varying input shaft speeds.
• VCC variable configuration controller
• the VCC may be used with various electric machines, for instance single or multi-phase generators, and provides a rectified DC output from each AC phase input from an induction element.
• the DC output may optionally be used with a Power Factor Correction (“PFC”) circuit to increase the efficiency of generator operation by smoothing the current wave shape to a near sinusoid.
• PFC Power Factor Correction
• the systems, apparatus and methods allow the configuration of multiple coils or windings in variable series/parallel combinations.
• the systems, apparatus and methods may also allow switching series and parallel coils or windings in tandem with rectification, rather than switching on the DC side, post-rectification. This may be accomplished using fewer switches than in previously described systems. In fact, parallel configuration can be achieved with no switches or with the switches open.
• a variable coil configuration system may be summarized as including a plurality of bridge rectifiers, the bridge rectifiers each having a pair of AC nodes on an AC side of the respective bridge rectifier and a pair of DC nodes on a DC side of the respective bridge rectifier; and a first number of switches, each of the switches of the first number of switches on the AC side of a respective one of the bridge rectifiers, wherein each of the bridge rectifiers couple at least two coils electrically in parallel with one another when a respective switch of the first number of switches is open and the at least two coils are not subject to an open circuit condition, a low voltage condition or a short circuit condition, and each of the switches of the first number of switches is operable to selectively electrically couple the at least two coils electrically in series with one another when the switch is closed.
• the bridge rectifiers may automatically electrically isolate a respective one of the coils of the electric machine from a parallel combination with at least one other one of the coils of the electric machine when the respective one of the coils experiences either a short circuit condition, a low voltage condition or an open-circuit condition.
• the bridge rectifiers may automatically electrically couple the respective one of the coils of the electric machine in series with at least one other one of the coils of the electric machine when the respective one of the coils experiences either the short circuit condition, the low voltage condition or the open-circuit condition.
• the first number of switches may be semiconductor based switches (e.g., TRIACS, IGBTs, FETs, SSRs).
• variable coil configuration system may further include a controller configured to switch the triacs at a respective zero crossings of a respective current.
• the variable coil configuration system may include one semiconductor based switch for each of the coils of the electric machine, and may further include a second number of switches, each of the switches of the second number of switches operable to selectively couple the at least two coils between being electrically in parallel with one another when the switch is open and electrically in series with one another when the switch is closed, the switches of the second number of switches on the AC side of the respective bridge rectifier and electrically in parallel with respective ones of the first number of switches, wherein the switches of the first number of switches are faster acting than the switches of the second number of switches and the switches of the second number of switches have a lower associated electrical loss than an electrical loss associated with the switches of the first number of switches.
• the second number of switches may be mechanical switches (e.g., mechanical relays, contactors). There may be one mechanical switch for each of the coils of the electric machine. All of the bridge rectifiers of the plurality of bridge rectifiers may be coupled to a common heat sink.
• variable coil configuration system may further include a power factor correction circuit applying a power factor correction at a DC output of the variable coil configuration system.
• a number of active switches may be selectively operable to reverse a current flow from a DC bus to the coils to operate the electric machine as a motor.
• the variable coil configuration system may further include an additional bridge rectifier coupled to an end of a string formed by the bridge rectifiers of the first number of bridge rectifiers to couple the variable coil configuration electrically in parallel with a second variable coil configuration system; at least one additional switch operable to selectively couple the variable coil configuration electrically in series with the second variable coil configuration system; and a coupler configured to detachably electrically couple the second variable coil configuration system to the variable coil configuration system.
• a method of operating a variable coil configuration system that comprises a plurality of bridge rectifiers, the bridge rectifiers each having a pair of AC nodes on an AC side of the respective bridge rectifier and a pair of DC nodes on a DC side of the respective bridge rectifier and a first number of switches, each of the switches of the first number of switches on the AC side of a respective one of the bridge rectifiers, may be summarized as including selectively coupling at least two coils of the electric machine electrically in parallel with one another via a respective one of the bridge rectifiers; and selectively coupling at least two coils of the electric machine electrically in series with one another via a respective one of the first number of switches.
• Selectively coupling at least two coils of the electric machine electrically in parallel with one another via a respective one of the bridge rectifiers may include selectively coupling a first two coils electrically in parallel with one another at a first time and wherein selectively coupling at least two coils of the electric machine electrically in series with one another via a respective one of the first number of switches may include selectively coupling the first two coils electrically in series with one another at a second time, different from the first time.
• Selectively coupling at least two coils of the electric machine electrically in parallel with one another via a respective one of the bridge rectifiers may include selectively coupling a first two coils of a first pair of coils electrically in parallel with one another at a first time and wherein selectively coupling at least two coils of the electric machine electrically in series with one another via a respective one of the first number of switches may include selectively coupling a second two coils, different from the first two coils, electrically in series with one another during the first time.
• the method may further include switching a state of the switches of the first number of switches by a controller at a respective zero crossings of a respective current.
• the method may further include automatically electrically isolating a respective one of the coils of the electric machine from a parallel combination with at least one other one of the coils of the electric machine by a respective one of the bridge rectifiers when the respective one of the coils experiences either a short circuit condition, a low voltage condition or an open-circuit condition.
• the method may further include automatically electrically coupling the respective one of the coils of the electric machine in series with at least one other one of the coils of the electric machine when the respective one of the coils experiences either the short circuit condition, the low voltage condition or the open-circuit condition.
• the variable coil configuration system may further include a second number of switches, each of the switches of the second number of switches on the AC side of a respective one of the bridge rectifiers and electrically in parallel with a respective one of the switches of the first number of switches, wherein the switches of the first number of switches are faster acting than the switches of the second number of switches and the switches of the second number of switches may have a lower associated electrical loss than an electrical loss associated with the switches of the first number of switches, and the method may further include for the coils of the electric machine that are electrically coupled in series with one another by the respective switch of the first number of switches, further coupling the coils of the electric machine electrically in series with one another by a respective one of the switches of the second number of switches immediately following the coupling electrically in series of the coils by the respective switch of the first number of switches.
• the method may further include correcting a power factor of a current at a DC output of the variable coil configuration system.
• the method may further include selectively reversing a current flow from a DC bus to the coils to operate the electric machine as a motor.
• the method may further include detachably electrically coupling a second variable coil configuration system to the variable coil configuration system.
• Selectively coupling at least two coils of the electric machine electrically in series with one another via a respective one of the first number of switches may include selectively coupling at least two coils of the electric machine electrically in series with one another via a respective triac, an insulated gate bipolar transistor, a field effect transistor or a solid state relay.
• a variable coil configuration system may be summarized as including a plurality of bridge rectifiers, at least one bridge rectifier for each pair of coils of an electric machine, the bridge rectifiers each having a pair of AC nodes on an AC side of the respective bridge rectifier and a pair of DC nodes on a DC side of the respective bridge rectifier; and a first number of switches, each of the switches of the first number of switches operable to selectively electrically couple respective pairs of coils from being electrically in parallel when the switch is open to electrically in series with one another when the switch is closed, each of the switches of the first number of switches on the AC side of a respective one of the bridge rectifiers.
• a variable coil configuration system may be summarized as including a plurality of bridge rectifiers, at least one bridge rectifier for each pair of coils of an electric machine, the bridge rectifiers each having a pair of AC nodes on an AC side of the respective bridge rectifier and a pair of DC nodes on a DC side of the respective bridge rectifier; and a first number of switches, each of the switches of the first number of switches on the AC side of a respective one of the bridge rectifiers, wherein each of the bridge rectifiers couple the coils of a respective pairs of coils electrically in parallel with one another when a respective switch of the first number of switches is open and the coils of the respective pair are not subject to an open circuit condition, a low voltage condition or a short circuit condition, and each of the switches of the first number of switches is operable to selectively electrically couple the coils of the respective pair of coils electrically in series with one another when the switch is closed.
• a method of operating a variable coil configuration system that comprises a plurality of bridge rectifiers, at least one bridge rectifier for each coil of an electric machine, the bridge rectifiers each having a pair of AC nodes on an AC side of the respective bridge rectifier and a pair of DC nodes on a DC side of the respective bridge rectifier and a first number of switches, each of the switches of the first number of switches on the AC side of a respective one of the bridge rectifiers, may be summarized as including selectively coupling at least one pair of coils of the electric machine electrically in parallel with one another via a respective one of the bridge rectifiers; and selectively coupling at least one pair of coils of the electric machine electrically in series with one another via a respective one of the first number of switches.
• Selectively coupling at least one pair of coils of the electric machine electrically in parallel with one another via a respective one of the bridge rectifiers may include selectively coupling two coils of a first pair of coils electrically in parallel with one another at a first time and wherein selectively coupling at least one pair of coils of the electric machine electrically in series with one another via a respective one of the first number of switches may include selectively coupling the two coils of the first pair of coils electrically in series with one another at a second time, different from the first time.
• Selectively coupling at least one pair of coils of the electric machine electrically in parallel with one another via a respective one of the bridge rectifiers may include selectively coupling two coils of a first pair of coils electrically in parallel with one another at a first time and wherein selectively coupling at least one pair of coils of the electric machine electrically in series with one another via a respective one of the first number of switches may include selectively coupling two coils of a second pair of coils, different from the first pair of coils, electrically in series with one another during the first time.
• the VCC system advantageously employs AC-side parallel/series switching, combined with AC/DC rectification, and DC/DC blocking capabilities of the bridge rectifiers. While the AC side switches (e.g., relay, IGBT, SSR, or any other switch) perform part of the switching action, the diode rectifier bridges perform series combination, isolation of intermediate step points, and connection of the appropriate coil terminals, and only those terminals, to the output. Thus, the diode rectifier bridges allow not only AC-DC rectification, but parallel current sharing, intermediate step isolation, and conduction of the ‘end point’ terminals to the DC bus output.
• AC side switches e.g., relay, IGBT, SSR, or any other switch
• VCC system described herein avoids the high losses associated with other devices. For example, the VCC system produces only two diode drops no matter how many series/parallel coils are used or configured, compared to four diode drops of the device described in U.S. Pat. No. 3,984,750.
• the VCC system described herein also employs a relatively simple switching scheme. Such advantageously avoids the complex switching scheme using a large number of switches, and associated losses, such as that described in U.S. Patent Application Publication No. 2007/0182273. That device uses 4 to 12 series switch elements for four coils, in contrast to the 1:1 ratio achievable using the VCC system described herein. Additionally, device of the U.S. Patent Application Publication No. 2007/0182273 requires the switch contacts to carry the parallel current of all coils. In contrast, VCC system described herein requires the switch contacts to carry the series current of only one coil per switch. This is a significant advantage since such reduces power losses, as well as allowing use of lower rated switches.
• the VCC system described herein provides some inherent fault tolerance against both open and shorted coils. For example, if a given coil is short-circuited, or has a lower output voltage than other coils, the diode bridge rectifiers will isolate that coil from parallel combination. In the case that the shorted coil is series combined with other coils, the whole string may be isolated from the output if there are other series-parallel circuits or the output voltage may be reduced if there is only one series coil string (i.e., all coils series mode). Importantly, in no case is the output loaded down by the shorted coil, as would occur in AC-side switching type devices described in U.S. Patent Application Publication No. 2007/0182273. Also for example, if a given coil is open-circuited, the diode bridge rectifiers will isolate that coil from parallel combination. In the case that the open coil is series combined with other coils, the whole string containing the open coil will be isolated from the output.
• a dual-element TRIAC/relay switch combination provides further advantages.
• fast switching of the semiconductor element e.g., TRIAC, or IGBT, or FET, or SSR
• the semiconductor element e.g., TRIAC, or IGBT, or FET, or SSR
• low power loss of relay contacts means significantly higher switching efficiency of the VCC system.
• This combination adds additional cost and complexity, but the VCC system is unique in requiring as few as a single (i.e., one) switch element per coil and only requiring the switch carry the series current for that coil only. Hence, this extra cost and complexity is acceptable.
• the VCC system may advantageously employ a common heat exchange structure (e.g., heat sink) for all diode bridge rectifiers in a given VCC.
• a common heat exchange structure e.g., heat sink
• a common heat exchange structure maintains an approximately equal temperature of all diodes so that their forward voltage drop also remains equal. This equal forward voltage drop helps maintain equal current sharing.
• FIGS. 1A-1H are a schematic circuit diagram showing power circuits of a variable configuration controller system according to one illustrated embodiment, including a plurality of bridge rectifiers, a first number of switches in the form of triacs and a second number of switches in the form of relays connected in parallel with the triacs between respective pairs of coils, and an associated sixth switch circuit for coupling to another circuit board in a modular fashion.
• FIG. 2A-2F are a schematic circuit diagram showing a partial representation of control circuit for a variable configuration controller system according to another illustrated embodiment.
• FIG. 3 is a schematic circuit diagram showing two 2-coil variable configuration controller systems configured to output to a common load, according to one illustrated embodiment.
• FIG. 4 is a top plan, partially broken, view showing a circuit board and a heat sink and illustrating a physical layout of various element of the variable configuration controller system on a circuit board, according to one illustrated embodiment.
• FIG. 5 is a flow diagram showing a method of operating a variable configuration controller system to accomplish series/parallel switching and rectification, according to one illustrated embodiment.
• VCC System 1 Bridge rectifiers D1-D5, collectively 10 Coil connector blocks J1-J6, collectively 20
• Semiconductor switches e.g. Triacs Q1-Q5, collectively 30 Snubber network 40 Relay 50 Expansion port 55
• Gate drive 70
• DC bus output connection 80
• Controller 90
• Analog multiplexer 100 RS485 interface 110 Power source 120 Amplifiers 130 Heat sink 140
• a VCC system 1 ( FIGS. 1A-1H , 2 A- 2 F) is a power electronics system configured to adjust multiple induction elements, such as coil windings of an electric machine (e.g., generator, electric motor), in various series and parallel combinations to maintain a relatively constant output voltage in response to varying input shaft speeds.
• the electric machine may use permanent magnets, electromagnets, a hybrid, and be core or coreless.
• a VCC system 1 may be used with a multi-phase electric machine, although each phase is managed in isolation by a separate circuit embodiment.
• a VCC system 1 can provide rectified DC output from each AC phase input, where the VCC system 1 is primarily intended for use with a subsequent Power Factor Correction (PFC) circuit.
• PFC Power Factor Correction
• VCC system 1 may also be used without PFC on the DC outputs.
• a VCC system 1 could be used with a PFC at the DC output, or a non-PFC with a single DC output.
• An alternative embodiment of a VCC system 1 could output AC.
• the VCC system 1 may operate using a number of devices or elements separately or in cooperation to connect the coils in the electric machine electrically in series and/or parallel. These devices or elements may include triacs, relays (e.g., solid state relays), bridge rectifiers, transistors and combinations thereof.
• the series coil configuration can be achieved by connecting the top side of one coil winding to the bottom side of the next coil winding by any suitable means.
• a VCC system 1 may work in conjunction with a power conversion system, such as the power conversion system and method described in U.S. Provisional Patent Application No. 60/094,007.
• FIG. 1 shows a VCC system 1 a , according to one illustrated embodiment.
• the VCC system 1 a includes a plurality of bridge rectifiers D 1 -D 6 (collectively 10 ).
• Each bridge rectifier 10 corresponds to a coil, from which bridge rectifier 10 is electrically coupled to receive AC input.
• the coils may be connected by suitable connectors J 1 -J 6 (collectively 20 ).
• six bridge rectifiers 10 may be present, as illustrated in FIGS. 1A and 1B .
• Bridge rectifiers 10 may provide several functions for the VCC system 1 a , including:
• AC to DC conversion i.e., rectification
• AC to DC conversion is needed if a subsequent PFC circuit is used.
• bridge rectifier 10 acts as switch in conjunction with a series switch, such as a semiconductor type switch (e.g., triode for alternating current (triacs), insulated gate bipolar transistors (IGBTs), field effect transistors (FETs), or solid state relays (SSR)) Q 1 -Q 5 (collectively 30 ) or relay K 1 -K 5 (collectively 50 ).
• a semiconductor type switch e.g., triode for alternating current (triacs), insulated gate bipolar transistors (IGBTs), field effect transistors (FETs), or solid state relays (SSR)
• Q 1 -Q 5 collectively 30
• relay K 1 -K 5 collectively 50 .
• Coil current sharing in conjunction with coil resistances Bridge rectifiers 10 initially maintain the coils in parallel. If the coil voltages are approximately equal, the current is shared between the coils to the outputs. If one coil has a higher voltage than the others, that coil then provides all of the current to the output, and the coils having lower voltages are isolated from the output. Given that the coils will not have precisely the same voltages, the load current sharing between coils can be maintained if they have approximately equal resistances.
• bridge rectifiers 10 may be GBU8U devices, each capable of 8 A, 600V operation. Such requires an adequate heat sink.
• a maximum output power of 420V RMS (600VDC peak) at 48 A RMS (6 ⁇ 8 A), or 20.2 kW is possible. If only six coils are present, the six parallel coil mode represents the maximum output power possible from the VCC system 1 a .
• the maximum output in six parallel coil mode is 10.6 kW (per phase).
• the bridge rectifiers 10 are therefore involved in providing the coil series and parallel switching function.
• the bridge rectifiers 10 also convert the AC current to DC current for receipt by a DC bus for transmission to an electrical load. Also, if a coil has an internal short, its lower output voltage causes the bridge rectifier 10 to which it is connected to be reverse biased, automatically isolating that coil from the output circuit. Likewise, while all coils are normally active, should a coil be switched off, the appropriate bridge rectifier 10 will automatically isolate that coil from the output circuit.
• the six parallel coil mode can be used for over-speed or over-torque operation for peak load handling.
• the operating point current at the nominal operating point should be lowered from 8 A to allow higher currents at peak load to be within the bridge diode ratings.
• bridge rectifiers 10 diode ratings may be at least 15 A.
• Active switches may be placed across one or more of bridge rectifiers 10 .
• These switches may be FETs, IGBTs, bipolar transistors, or any other suitable DC switching devices with high speed operation.
• These switches may be pulse-width modulated (PWM) to apply a variable DC voltage from the output bus to the coil connector blocks 20 , thereby capable of reversing or changing the operation of the generator to that of a speed-controlled motor.
• PWM pulse-width modulated
• the switches may reverse current flow from the DC bus to the coils of the electric machine at appropriate times in order to provide a rotating magnetic field suitable for motor operation.
• the semiconductor switches 30 may take a variety of forms, for example triacs, IGBTs, FETs, SSRs.
• Triacs are a bidirectional electronic switches for AC current that conducts current in either direction. The triac conducts and latches (i.e., stays ON) until the current load is removed, which for example may occur at zero crossing or a minimal level of current.
• five semiconductor switches 30 such as triacs, individually labeled as Q 1 through Q 5 , may be used to control six coils of an electric machine.
• These triacs Q 1 -Q 5 can be individually controlled by controller 90 ( FIG. 2D ) to enable series and parallel coil combinations in a six coil machine as follows:
• triacs Q 1 , Q 3 , Q 5 are ON; triacs Q 2 and Q 4 are OFF.
• triacs Q 1 , Q 2 , Q 4 , and Q 5 are ON, triac Q 3 is OFF.
• triacs Q 1 , Q 2 , Q 3 , Q 4 ; or triacs Q 2 , Q 3 , Q 4 , Q 5 are ON. The other triac is OFF.
• triacs Q 1 , Q 2 , Q 3 , Q 4 , Q 5 are ON.
• Coil series configuration controlled by triacs 30 provides enhanced operation due to lower current waveform distortion achieved by ‘zero cross switching’ of triac 30 , i.e., when the AC current waveform drawn from the switched coil is at its minimum value.
• the VCC system 1 may also include a number of relay switches 50 , which may operate independently, or in conjunction with triacs 30 .
• the VCC system illustrated in FIG. 1 includes five relay switches, individually labeled K 1 -K 5 , each electrically in parallel with a respective one of the triacs Q 1 -Q 5 .
• Relay switches 50 provide for a low level of losses when switching, but are slow to switch (i.e., change state) in reaction to a switch command.
• Triacs 30 react to switch commands quickly but have higher losses when compared to relay switches 50 .
• using both triacs 30 and relay switches 50 advantageously allows a multi-step switching process to be used.
• the appropriate triac 30 reacts first and switches state accordingly. Then, the corresponding relay switch 50 switches or changes state, taking over the load. The corresponding triac 30 is disengaged for this purpose, until the next switching or change takes place.
• the VCC system 1 may employ a number of box headers (e.g., 10 ⁇ 2) J 11 ( FIG. 1D ), J 12 ( FIG. 1E ) to provide selectively detachable communicative coupling between a controller 90 ( FIG. 2D ) and various other VCC system elements, for example the triacs Q 1 -Q 5 ( FIGS. 1A , 1 B) and relays K 1 -K 5 ( FIGS. 1A , 1 B).
• box headers e.g. 10 ⁇ 2
• J 11 FIG. 1D
• J 12 FIG. 1E
• Respective gate drive circuits 70 a - 70 f are repeated at each zero cross to ensure triac 30 “ON” control. Changing triac 30 drive signals G Q 1 -G Q 5 only at zero cross also prevents unintended series configurations (the zero cross detection ensures all triacs 30 except those with a gate drive are “OFF”).
• the zero cross detection circuits may use A/D conversion of both voltage and current inputs, and a digital filter for averaging and zero cross estimation to increase robustness and frequency range. Zero crossing detection may be performed in digital signal processing in controller 90 (e.g., U 101 , FIG.
• a current monitor circuit may be present for zero cross detection.
• the current monitor circuit could be used for zero cross trigger switching of triacs 30 .
• current monitoring resistors R 49 -R 54 FIGS. 1A and 1B present a voltage drop proportional to current flow in each coil, selected by multiplexers 100 (e.g., U 4 , U 5 , FIGS. 2A and 2B ), amplified by amplifiers 130 , and converted to digital representation by an A/D converter within controller 90 (e.g., U 101 , FIG. 2D ).
• snubber networks 40 Within the 100 Ohm and 0.1 uF networks, across each triac 30 are snubber networks 40 (only one called out in FIG. 1A and FIG. 4 ).
• the snubber networks 40 absorb voltage transients which otherwise might cause false triggers of triacs 30 at turn-OFF or zero-cross points.
• Snubber network 40 may use a carbon-composition resistor that has high pulse handling capabilities (many kW for short pulses), but is only 1 ⁇ 2 W continuous rated.
• the 100 ohm 0.1 uF combination may be limited to 110VAC at 1 kHz or 220VAC at 500 Hz due to continuous power dissipation in the snubber resistance.
• the snubber could be designed for greater voltage, e.g., a 47 ohm and 0.033 uF snubber would allow for 500VAC at 1 kHz.
• Bridge rectifiers 10 when connected to a load, may also act as snubbers for transient energy across the switching elements, whether those elements be triacs 30 , relay contacts 50 , or transistors. Such a configuration may eliminate the need for the snubber network 40 . Additionally, there are triacs 30 available (for example those sold in association with the trademark ALTERNISTOR®), that do not require snubber networks 40 .
• Gate drive 70 circuits may include isolation transformers T 1 -T 6 ( FIG. 1H ), coupling capacitors (not shown), such as 0.47 uF AC coupling capacitors, and coupling discharge resistances (not shown), typically 10 k, coupled across a primary side of the isolation transformers T 1 -T 6 .
• the digital control output circuits are isolated from the high voltage at the triac gates by transformers T 1 -T 6 .
• a 2:1 winding ratio provides a 4:1 impedance transformation so that controller 90 may supply up to the required 50 mA triac gate drive level.
• 74HCT574 buffer/driver/level converter circuits U 102 , U 103 may be included within gate drive circuit 70 ( FIG. 1H ).
• circuits U 102 , U 103 isolate the gate drive circuit 70 power supply noise from controller 90 , allow a level convert to a 5V drive, and free input/output (I/O) pins.
• these circuits U 102 , U 103 may translate the 3.3 processor or controller 90 (e.g., U 1 , FIG. 2D ) logic levels to 5V levels at higher current capacity suitable for driving relay drivers U 2 of the power circuit board (i.e., VCC_PWR), LEDs D 101 -D 104 ( FIG. 2F ) of the control circuit board (i.e., VCC_MCU), and triac transformers T 1 -T 6 of the power circuit board (i.e., VCC_PWR).
• Relay contacts may be added across the triacs 30 to reduce loss, at the cost of additional complexity.
• Such contacts may be +24V coil, 10 A SPST contacts.
• An expansion port 55 may be provided within the VCC system 1 .
• an extra triac Q 6 and/or relay switch (as appropriate) K 6 at one ‘end’ allows connection to another VCC system module to expand the coil series switching capability.
• This ‘switch’ expansion port 55 may be coupled to the ‘unswitched’ side of the next VCC system module (i.e., the ‘top’ of one coil stack connected to the ‘bottom’ of the next coil stack).
• the VCC system 1 may include a heat exchange structure (e.g., heat sink, heat spreader and/or heat pipe) 140 .
• a heat exchange structure e.g., heat sink, heat spreader and/or heat pipe
• the heat exchange structure 140 can provide at least three functions.
• the heat exchange structure 140 may remove heat from bridge rectifiers 10 .
• the heat exchange structure 140 may remove heat from triacs 30 .
• the heat exchange structure 140 may equalize bridge rectifier 10 temperatures, which may facilitate proper parallel mode current sharing between bridge rectifiers 10 .
• a relatively small heat exchange structure 140 such as a small heat sink may be capable of less than 50 W of dissipation, which is suitable for greater than 2 kW of output power per phase.
• Amplifiers 130 may provide differential amplification of the low-voltage current monitoring signal produced in the low-value (approximately 0.004 ohms) current shunt resistances formed by small lengths of wire or printed circuit board traces.
• Amplifiers 130 may have a differential gain of 100 and an output range of about 4V which results in a full scale current capability of about 10 A. These amplifier circuits need not be precise due to variations in current shunt resistance values, but are intended to give representative current measurement results, which is useful for zero cross detection (digital signal processing mode), fault detection, and operational reporting.
• the controller 90 may take a variety of forms.
• the controller 90 may take the form of a microcontroller, microprocessor, application specific integrated circuit or programmable gate array.
• the controller 90 may take the form of a PIC16F883 microcontroller (U 101 ).
• the controller 90 is the core of the VCC system 1 , controlling operation, providing a memory, a processor, A/D conversion, digital I/O, timing functions, as well as serial communications.
• a 20 MHz clock crystal may result in 5 MIPS instruction execution speed.
• Firmware may be programmed in approximately 1500 lines of assembly code.
• the microcontroller code may have a C source, which would improve portability and readability and increase the capability of the VCC system 1 to deal with more complex systems.
• Controller 90 may take the form of a higher performance device, for example a PIC18, which would provide faster processing (10+ MIPS), a hardware multiplier for signal processing, a faster A/D converter, and C code support, providing more memory and speed.
• a higher performance device for example a PIC18, which would provide faster processing (10+ MIPS), a hardware multiplier for signal processing, a faster A/D converter, and C code support, providing more memory and speed.
• Root-Mean-Square (RMS) current and voltage measurements may be added to the code to support power and power factor (PF) reporting, allow zero cross detection at non-unity PF, provide fault detection support, measure input cycle frequency, and automatically adjust triac 30 gate drive circuit 70 timeouts.
• PF power factor
• a daughterboard configuration could be used for controller 90 , which would allow the main power board (VCC_PWR) to have 3 oz or 4 oz copper, with associated large trace/space design rules and through-hole construction, while the controller board (VCC_MCU) can be standard 1 oz copper with surface mount device (SMD) components and finer design rules.
• the controller 90 or main power board (VCC_PWR) could each be re-designed separately and firmware updates could be handled by easy replacement of the module rather than the entire power circuit.
• Analog multiplexers 100 may be added to select inputs to measure additional analog inputs to controller 90 .
• two 74HC4051 8-1 analog multiplexers may be added, which requires 15 analog inputs. Such may advantageously provide for a simpler layout and fewer connections to a controller daughterboard.
• a configuration expansion port 55 may be used, as seen in FIG. 1B , wherein an extra relay K 6 and/or triac Q 6 on one end of the diode bridge string allows for the connection of two or more board units to larger coil configuration arrays via a connector J 7 .
• An associated controller connection between daughterboards would also be used for control synchronization.
• the CCV system 1 may include a first temperature sensor R 17 ( FIG. 1D ) on the power board (VCC_PWR) to monitor temperature of or on the heat exchange structure (e.g., heat sink).
• the CCV system 1 may include a second temperature sensor R 19 ( FIG. 2B ) on the control board (VCC_MCU) to monitor temperature in the ambient surroundings. Voltages across the temperature sensors R 17 , R 19 represent temperature. These voltages are also multiplexed by analog multiplexers 100 , buffered by buffer U 7 , and converted by an ND converter within controller 90 (e.g., U 101 , FIG. 2D ).
• the VCC system 1 may include a power supply 120 ( FIG. 1C ) to provide a stable on-board 5V supply, for example from an input voltage of about 8V to 20V.
• the power supply 120 may, for example, include a peak boost/buck/inverting switching regulator, for instance an MC33063A switching regulator commercially available from Texas Instruments.
• the power supply may include a 7805 voltage regulator. Current consumption may be less than 0.2 A.
• a battery-backed power supply (not shown) may be provided on a separate board, which provides a capability to manage temporary low input periods without configuration restart, is self powered from generator output, and if +24V, is nominal for industrial controller standards compatibility.
• Another suitable power supply could be one that accepts a +24VDC nominal input and provides a +5VDC 0.25 A output, which is an industrial controller standard that provides +40V input voltage range.
• the VCC system 1 may include an RS485 serial interface 110 ( FIG. 2E ).
• RS485 serial interface 110 may be a common, standard, industrial control bus used for digital control of coil configuration as well as status reporting from the VCC system 1 .
• RS485 serial interface 110 provides some noise immunity, which is useful to address ground noise issues which may be common in high power installations.
• the serial format used may be the common 9600 baud, 8 bit, 1 stop bit, no parity.
• Firmware may be updated via serial interface U 6 .
• FIG. 5 shows method 500 of operation of the VCC system 1 , according to one illustrated embodiment.
• the VCC 1 system typically starts with the coils in a default parallel pattern, arrangement or configuration. Current is generated as output from the coils to the bridge rectifiers 10 .
• the controller 90 sends switching commands to triacs 30 and/or relays 50 .
• triacs 30 e.g., Q 1 -Q 5
• appropriate states e.g., ON, OFF
• the controller 90 causes the relays 50 (e.g., K 1 -K 5 ) to change states after the triacs 30 have taken up the load.
• the triacs 30 cease carrying current flow at 510 .
• bridge rectifiers 10 adjust diodes to isolate current at 512 .
• bridge rectifiers 10 may isolate coils on occurrence of various conditions such as an open circuit, low voltage or electrical short conditions.
• a VCC system 1 may retain the single-phase circuit configuration, with a three-phase implementation created with three separate circuits. This has various advantages, including simplifying the individual phase circuits, providing the required phase isolation, easing construction of the combined circuit, and also allowing poly-phase implementations.
• a coil step control may be included for overvoltage protection. This may have a manual or automatic control to prevent overvoltage output and protect the circuit elements.
• a voltage output monitor may be present for fault detection.
• the VCC system 1 provides redundancy, in that if a coil fails (either short or open), the action of the associated bridge rectifier 10 is to isolate that coil from the rest of the circuit, while the rest of the circuit operates normally. Note that any coils connected in series modes with the failed coil will also be isolated in such a case, but will re-connect to the circuit if the VCC system 1 disconnects those coils from the failed coil (as long as the re-connection is of equivalent series connection level to the rest of the coils).
• each induction element is connected to a VCC system 1
• a methodology for containing the wiring outputs of each stack independently may be used.
• this design has all wires from each stack treated independently such that there is a dedicated VCC system 1 a (only one identified by broken line and called out in FIG. 4 ) for each stator, or stator pair (that may be employed when a double sided stator is used).
• the wiring from each stack that is directed to the VCC system 1 a will be managed by respective controller 90 .
• each VCC unit (each stack) is then rectified to a single DC output such that only a common DC bus BUS ⁇ , BUS+ is required for connecting a multitude of independent machine stacks.
• This common DC bus BUS ⁇ , BUS+ may significantly reduce the need for tracking the wiring coming from each stack of the generator, may reduce the labor requirements in manufacture, may reduce the wiring cost (as less wire is needed), and may reduce the electrical losses that would otherwise result should that additional wire be used.
• this manufacturing methodology lends itself well to a modular construction that allows easy customization for various generator designs.
• a generator design might have a rated output of 500 kW for each independent stator.
• For a two stator stack electric machine it would be a one megawatt machine design, for a four stack machine, a 2 MW machine design and so on, so that independent single stacks can be mated together easily and connected to a common DC bus.
• This modular design may allow a single set of components, required for a single stack, to be employed in such a way as to make a multitude of different sized machines, thereby reducing manufacturing costs.
• Aligning generator phases i.e., AC waveforms synchronized, mechanically aligned in the machine.
• the phases may be purposefully offset, but then there is phase switching due to rectifier action rather than current sharing between coils.
• Consistency in temperature may be obtained by using a common heat sink within the VCC system for the power components.
• the PFC circuit actively controls the current drawn from each stack, and so may enforce sharing between multiple generator connections when multiple PFC circuits are used.
• Each PFC circuit controls the current level from the total of the units connected to it. The outputs of multiple PFC circuits may then be connected to a single DC output bus.
• a “motor mode” operation for the generator may be employed to obviate the need for a clutch.
• This circuit can operate by applying voltage from the bus ‘output’ to one or more of the coils of the electric machine to run the electric machine it as a motor instead of as a generator.
• This operation ‘spins up’ (using active stages) the unloaded stages in a multi-stack electric machine from the DC bus power, but also may be used in other applications.
• such may be used in electric vehicles where the primary mode of the electric machine is as a motor, but the electric machine also operates in a ‘regenerative braking’ generator mode.
• Such fits well with a VCC system configured with switches on all bridge rectifiers. When a new stage begins, with low energy production, the new stage is isolated from the bus by bridge rectifiers 10 .
• the output voltage may be returned to AC from the rectified DC.
• Switches triac 30 , solid state relays 50 , or other switches fast enough and with AC capability
• the output AC waveform will have a small ‘zero-cross dead-zone distortion’ due to voltage drops in the bridge rectifiers 10 and DC to AC switch bridge, but the waveform would be suitable for connection to a transformer or motor.
• FIG. 3 shows two 2-coil electric machines (e.g., generators, motors) linked to a common bus using respective VCC systems 140 , 145 .
• This arrangement can be expanded to a number of coils on each VCC system 140 , 145 , and a number of VCC units connected to the common bus output point.

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