|Publication number||USRE39710 E1|
|Application number||US 10/802,119|
|Publication date||Jul 3, 2007|
|Filing date||Mar 16, 2004|
|Priority date||Feb 13, 2001|
|Also published as||DE10296295T5, US6465910, US20020109410, WO2002071572A1|
|Publication number||10802119, 802119, US RE39710 E1, US RE39710E1, US-E1-RE39710, USRE39710 E1, USRE39710E1|
|Inventors||Douglas Gibbons Young, Herbert C. Healy, Francis A. Fragola, Jr., Ricky M. Ross|
|Original Assignee||Utc Fuel Cells, Llc|
|Export Citation||BiBTeX, EndNote, RefMan|
|Patent Citations (15), Referenced by (10), Classifications (22), Legal Events (4)|
|External Links: USPTO, USPTO Assignment, Espacenet|
This invention relates generally to power systems, and more particularly to power systems for providing an assured, or uninterruptible, supply of electrical power to one or more critical loads. More particularly still, the invention relates to such power systems employing fuel cells as a source of electrical power.
By far, the most common source of electrical power for a great variety of loads is via the extensive power grid provided by the various electric utilities. The electrical power available on the utility grid is generally fairly reliable as to continuity and adherence to established standards of voltage, frequency, phase, etc. However, from time to time discontinuities and/or departure from those standards do occur. If they are brief or modest, most loads are relatively insensitive to those events. On the other hand, there are a growing number of loads which are relatively intolerant of even brief aberrations in the power supplied by the utility grid, with the principal example being computers and various types of electronic data processing devices. Even brief interruptions in the standardized supply of electric power by the utility grid may cause the computer to malfunction, with sometimes costly, and always bothersome, consequences.
In defining this concern, the Computer Business Equipment Manufacturers Association (formerly CBEMA, and not ITI) has developed a set of Power Acceptability Curves which establish the standards, or at least provide guidance, for determining the power norms which will assure continued operation of those types of loads. In that regard, a standard has been adopted indicating that a computer can tolerate a one half cycle or 8.3 ms power interruption. The power available on the utility grids is not presently capable of meeting this standard on a substantially continuous basis. Accordingly, it has been and is, necessary to provide supplemental mental power sources if it is important to assure that critical loads have a substantially continuous or uninterrupted supply of electrical power. For purposes of this application, a supply of power with interruptions or transfers of no greater than 8.3 ms duration, may be referred to as being “seamless”, “substantially continuous”, or “substantially uninterrupted”.
Another arrangement of a power system for providing substantially uninterrupted power to critical loads is described in PCT application US99/10833 for “Power System”, published on Nov. 25, 1999 as WO 99/60687. Referring to
While the Power System of the abovementioned PCT application may provide a substantially uninterrupted source of power to various critical loads and may advantageously employ fuel cells as one of the main sources of the power, it nevertheless requires the use of considerable additional equipment that is complex and costly. For example, the separate motor-generated 230, and the backup power source 216 which includes the flywheel 236/converter 238 combination, represent necessary, but expensive, components in order to assure the degree of power continuity sought and required.
Another type of UPS is of the “stand-by” type wherein the grid is directly connected to the loads and a stand-by UPS remains idle, even if connected to the loads, until a switch disconnects the grid from the loads. An example of such a system is disclosed in U.S. Pat. No. 6,011,324. The fuel cell and associated inverters are normally connected to the loads, but in an idle standby mode while the grid supplies power directly to the loads. When the grid fails, the fuel cell is rapidly brought to full output power and a solid state switch disconnects the grid. Here, too, a number of costly components are in use only during the intervals when the utility grid power is unsatisfactory. Accordingly, it is a principal object of the present invention to provide a power system for providing a substantially uninterrupted (seamless) supply of electric power to critical loads in a relatively economical manner.
It is a further object to provide such a power system in which one or more fuel cell power plant(s) are utilized to substantially continuously supply power to the loads.
According to the invention, there is provided a relatively economical and reliable power system for providing substantially uninterrupted electric power to one or more critical loads. A first power source, such as the utility grid, provides sufficient power to supply the critical loads. A second power source comprising at least one, and typically multiple, fuel cell power plants, provides sufficient power to supply at least the critical loads. The fuel cell power plant(s) is/are adapted to be, and is/are, substantially continuously connected to the critical loads and are substantially continuously providing significant power to at least the critical loads. A static switch operates to rapidly and seamlessly connect and disconnect the utility grid to the critical load(s) and to the fuel cell power plant(s), for economical continuous usage of the fuel cell power plant(s). Significant economy is realized by having the substantially continuously operating fuel cell(s) substantially continuously connected to the load, and normally also to the grid. In this way, the fuel cells may continuously deliver their rated power, with the requisite portion going to the critical loads and any excess being delivered to non-critical loads and/or the grid. The static switch may be one or more silicon controlled rectifiers (SCRs), or thyristors. Solid-state switch controls operate to rapidly switch the static switch in 4 ms, or less, to make seamless transfers between the first and second power sources. This switching speed is significantly faster than is obtained with conventional line commutation of thyristors. Further control electronics provide high-speed transitions (less than about 4 ms) in the operating modes of the power conditioning system (PCS) inverters associated with each of the fuel cell power plants. This assures that the fuel cell mode transitions, heretofore normally slow, are at a speed comparable to that of the static switch so as to provide substantially seamless power transfers of and between the first and second power sources. This allows continuous productive operation of the fuel cell power plants.
The foregoing features and advantages of the present invention will become more apparent in light of the following detailed description of exemplary embodiments thereof as illustrated in the accompanying drawings.
Referring to the Drawings,
The utility grid bus 10 normally provides power at 480 VAC and 60 Hz, as do the fuel cell power plants 18 via lead, or bus, 15. Switching gear, generally designated 12, serves to interconnect the fuel cell(s) 18, the load(s) 14 and the utility grid 10. In this way, the fuel cells 18 are available and connected for supplying electrical power on a full time basis to the loads 14 and/or to the utility grid 10, for economical usage of the fuel cells. The switching gear 12 includes a static switch module 17 for selectively connecting and disconnecting the utility grid bus 10 to the loads 14 and to the fuel cells 18, as will be described. The static switch module 17 includes a 3-pole electrically operated static switch 19 rated at 2000 amperes and capable of performing seamless switching transfer of power in about ¼ cycle (about 4 ms). The switching gear 12 further includes several inter-tie or breaker switches 21, 21A, 23, 23A, and isolation switch 25 for further selectively connecting and disconnecting the fuel cells 18, loads 14, utility grid bus 10 and static switch module 17, relative to one another, primarily to isolate the static switch 19 for servicing and continue to provide power to the load(s) 14. A secondary purpose is to allow large fault currents to flow through breaker 23A instead of static switch 19 if such a fault in the load 14 should occur.
The fuel cell(s) 18 may be a single power plant, or multiple (i.e., “n”) plants, connected to provide power to the loads 14 and/or to the utility grid 10. In an exemplary embodiment, there are five fuel cell power plants 18, each being a 200 kw ONSI PC25™C power plant, for collectively providing up to 1 megawatt of power. In addition to a fuel processor and the fuel cell stack itself, each power plant 18 also includes a power conditioning system (PCS) that contains a solid-state inverter which converts DC power to AC power at the desired voltage and frequency. Control of and by the PCS further enables conversion of the mode of operation of a fuel cell power plant 18 from G/C to G/I, and vice versa, as will be described in greater detail. When used in G/C mode, the variable controlled by the PCS is power delivered (both real and reactive). When used in the G/I mode, the variables controlled are output voltage and frequency, and, if multiple power plants 18 are involved, phase. The output voltage of a three-phase system is, of course, controlled to be at a phase angle of 120° between each phase. The outputs of the several fuel cell power plants 18 are collectively joined by bus 15, which is connected through a delta-to-wye transformer 27 and bus 15′ to the switching gear 12. The transformer 27 provides a separately derived neutral/ground system for the load 14, and also provides isolation between the fuel cell PCS and the load 14 and/or the utility grid bus 10.
A site supervisory control (SSC) 29 provides the operator interface for the system 8 and may be responsible for control of the system at a high level. The SSC 29 allows the operator to issue high level commands such as “start”, “stop”, and the like. The SSC 29 may include one or more programmable logic controllers, data processors, computers, sensors, etc. to effect the control of the various components and functions of the system 8. An operator console 32 provides a display and input capability for the SSC 29. The SSC 29 may provide limited control of switching gear 12, as through a link 52, although principal control of that switching gear occurs automatically by the static switch 19.
There is also provided a site management control (SMC) 31 for providing direct control of the PCS's of the fuel cells 18, in response to signals from the static switch module 17, as well as the grid voltage reference signal 10′ described below. The SMC 31 also may be composed of computers and associated sensors and control circuitry. The SMC 31 may be viewed and considered as an included portion of the SMS 11. Control bus 33 exchanges control signals between the SMC 31 and the PCS's of fuel cells 18. Control signals may also be exchanged between the SSC 29 and the fuel cells 18 via control bus 35, here shown in broken line. Control signals are exchanged between the SMC 31 and the static switch module 17 via control bus 40. A voltage, or potential, transformer 37 senses the 480 Vac grid voltage and communicates the stepped-down 120 Vac value, via bus 10′, to the SMC 31 and the static switch module 17 for the purpose of providing control signals indicative of the grid's voltage, phase and frequency. The depicted location and quantity of transformer(s) 37 is mainly symbolic, and it should be understood that such transformer(s) may, alternatively, be incorporated as part of the control circuit or module for which the control signal is provided. A current transformer 41 senses the load current in a power bus path 39 connected to the loads 14, and communicates the value to the static switch module 17 via bus 43. Similarly, current transformer 42 senses grid current and communicates the value to the static switch module 17 via bus 44, and voltage transformer 46 senses load voltage and transmits it to the static switch module 17 via bus 48.
Returning to further consideration of the switching gear 12, with reference additionally to
A bypass breaker switch 21A, connected from power bus 15′ to the power bus path 39 between the loads 14 and the isolation switch 25 and being normally open, serves, when closed, to bypass breaker switch 21 for purposes of maintenance or isolation. Similarly, a bypass breaker switch 23A, connected from the utility grid bus 10 to the power bus path 39 between the loads 14 and the isolation switch 25 and being normally open, serves, when closed, to bypass breaker switch 23 and static switch 19 to supply grid power to loads 14, in the event the static switch fails or during maintenance or during a load fault sufficiently large to exceed the rating of the static switch. Breakers 21, 23, and 23A are electrically operated and are automatically controlled by the static switch 19 to perform transfers in 5 or 6 cycles, e.g., about 80-100 ms. The breaker switch 21A and isolation switch 25 are manual. The switches 21, 23, and 23A can also be manually controlled by the SSC 29. Each of the switches 21, 21A, 23, 23a, and 25 is rated 2000 amperes, and the circuit breakers have a fault interrupting rating of 65 kaic. The general communication link 52, shown in broken line between the switching gear 12 and the SSC 29, serves to convey appropriate status and manual control signals therebetween for the static switch 19 and the several breakers 21, 23, 23A, etc. Control logic 49 associated with static switch module 17, and particularly a switchgear control logic portion 49B thereof, serves to control the several breakers and switches 21, 21A, 23, and 23A, as represented by the broken line control paths 21′, 21A′, 23′, and 23A′ extending thereto. The control logic 49 is generally comprised of a high-speed logic portion 49A for rapidly controlling the static switch 19, and a relatively slower-speed portion 49B for controlling the remainder of switchgear 12.
Referring still further to
The normal mode is G/C in which the utility grid 10 and the fuel cells 18 are connected. The module 17 includes circuitry 45 for sensing when the supply of power from the utility grid bus 10 is out of limits. Typically, these limits include a voltage and a current range relative to the standard or nominal values, and the sensing circuitry 45 provides a signal on lead 47 to control logic 49, and static switch control logic 49A thereof specifically, to indicate when the grid is outside those limits. The sensing or detection circuitry 45 is fast acting, providing a response in about 2 ms. Although not depicted, a separate fast acting frequency detector may monitor the grid frequency and provide an “in” or “out” “of limits” signal to the static switch control logic 49A. “Out of limit” grid signal values include, for example,: a) instantaneous and voltage magnitudes, on any phase, outside the range of 480 v+8% to −15%; b) instantaneous over-current, on any phase, greater than 2,000 amperes; c) frequency deviations from nominal 60 Hz value for more than 0.5 sec.; as well as others. The control logic 49A acts in response to the grid going out of limits, to provide a signal to the SCR gates 19G to disable them. The SCR's 19 will rapidly commutate off, thereby disconnecting the utility grid bus 10 from both the loads 14 and the fuel cells 18. A current sensor 42′ senses the current through the SCRs and provides an indication to the control logic 49A of the occurrence of zero current through the SCRs. This information is used by the logic 49A to make the SCR commutation faster. This entire action typically occurs in about ¼ cycle (4 ms), thus facilitating a seamless transfer of power sources from the grid 10 and the fuel cells 18, to the fuel cells 18 alone, with the fuel cells reconfiguring as rapidly, as will be explained. This is significantly faster than the 8 ms or more required to commutate an SCR using conventional line commutation.
The control logic 49B also uses the voltage and current sensors 37, 41, 42, and 46 to operate the switching gear devices 21, 23, and 23A under various grid, load, and fuel cell out of limit or fault, conditions. For example, if a load over-current condition exists such that the current rating of the static switch 19 may be exceeded, switch 23A is closed to conduct the fault current to the load 14, by-passing the static switch. As a further example, a fuel cell fault can be indirectly detected by observing a low load voltage and perhaps a high grid current but no load over-current. In such event, switch 21 is opened to isolate the fuel cell fault from the load 14. The control logic 49A also provides an M1 mode signal on lead 401 and an M2 mode signal on lead 402. For manual control from the SSC 29, a G/I status signal is provided by control logic 49 on lead 403, and a SW19 Enable signal is received on lead 404. The signals 401 and 402 are part of the control signal bus 40, and the signals on leads 403 and 404 may be conveyed via communications link 52. When the sensing circuitry 45 senses the grid to be out of limits, it causes the M2 mode signal on lead 402 to transition from an “Off” to an “On” state to signal a need for, and to initiate, a mode change. Similarly, but slightly delayed, when the static switch 19 has actually opened in response to the sensed out of limits condition of the grid, the M1 mode signal on lead 401 transitions from an “Off” to an “On” state to signal nominal completion of the mode change. The reverse occurs when the sensing circuitry determines that the grid power supply has been returned to within the acceptable limits, with the M2 signal again leading the M1 signal.
Synchronization of the fuel cell power plants 18 in either the G/C or the G/I mode is effected by a “sync” signal appearing on lead 53. The sync signal is provided through a phase-lock loop 55 receiving alternative inputs, through switch 57, from either a zero-crossing detector 59 connected to the stepped-down utility grid bus 10′ or an internal frequency source, such as crystal 61. A “loss of grid” detector 63, similar to circuit 45, is connected to the stepped-down utility grid bus 10′, and provides a control signal which actuates 3-pole switch 57 as a function of whether or not the grid power is within limits. The interface circuit 51 also is responsive to the M1 and M2 mode signals to provide a signal extended to switch 57 to toggle that switch as a function of the respective mode. It will be understood that detector 63 might be omitted and the output of detector circuit 45 from module 17 used in its stead to control the M1 and M2 mode signals applied to interface circuit 51, which in turn controls the switch 57. The switch is depicted in the normal G/C mode in which the synchronization signal provided to the PCS of the fuel cells 18 is that of the utility, such that the frequency and phase of the outputs from the fuel cell inverters are controlled to become and be, the same as it.
When the system 8 operates in the G/I mode, the frequency and phasing of the outputs of fuel cells 18 is determined by the crystal 61. When the utility grid power source returns to within limits and the system 8 is to be returned to the G/C mode, the phase and frequency sources are similarly returned. The phase lock loop 55 slews the sync signal in its transition from one mode to the other to avoid steps or discontinuities.
The solid state inverters of the PCSs of the respective fuel cell power plants 18, and the high speed solid state gates (not shown) which control them, are capable of responding in the ½ cycle (4 ms) needed for the seamless transfer of power sources. Thus, these inverters, through control of their gates by the mode control signals D1 and D2, are able to effect mode changes of the fuel cells 18 rapidly enough to accomplish the seamless transfers. This enables the fuel cell power plants 18 to operate substantially continuously in a power generating mode, either G/C or G/I, with but a momentary (less than 4 ms) interruption as they are reconfigured for operating in the opposite mode. The power conditioning systems (PCSs), and particularly their inverters and associated gating logic and control, for each fuel cell power plant 18 are of a type manufactured by Magne Tek Inc. of New Berlin, Wis.
Reference to the Table depicted in
Specifically, M2 rapidly transitions to “On”, while M1 remains “Off” for the brief interval required for switch 19 to transition from “On” to “Off”. The discrete signals D1 and D2 have the same states as M1 and M2, respectively. The transition of signal M2 (and thus D2) to the “On” state serves to briefly turn “Off” the inverter gates in the PCSs such that, for a brief interval less than 4 ms, the PCSs of the fuel cells 18 do not provide an electrical power output while they are being reconfigured to the G/I mode of operation. During this interval, the PCS output regulators are being reconfigured, such that in the G/C mode they regulate power (real) and VARs and in the G/I mode they regulate voltage and frequency. The sync is also being reconfigured during this interval. This interruption is sufficiently brief and the switch 19 sufficiently fast, that there is little or no chance for an overload on grid 10 to adversely impact the remainder of power system 8.
After this brief interval of 4 ms, or less, the system 8 is reconfigured and operating in the G/I mode. The mode signals M1 and M2 (and thus also, D1 and D2) are both “On”, the switch 19 is “Off” (open) such that the system is disconnected from the utility grid bus 8, and the inverter gates in the PCSs are again on to provide power to the load(s) 14 from the fuel cells 18. At this time, the output from the PCSs is being “clocked”, or synchronized, by the crystal 61. In the G/I mode, the fuel cell power plants 18 supply, or continue to supply, power to the loads 14 at regulated voltage and frequency without involvement of the utility grid, at least to the maximum capacity of the collective fuel cells.
At such time as the utility grid bus 10 comes back within acceptable limits as determined by sensor 45, the control logic 49 of the static switch module 17 reverses the prior mode change sequence and begins the transition from the G/I mode back to the G/C mode. Mode signal M2 first goes “Off” while M1 briefly remains “On”, the switch 19 quickly transitions from “Off” to “On” such that the utility grid bus 10 is once again connected to the loads 14 together with the fuel cells 18, the PCS inverter gates are again briefly “Off” during reconfiguring, and the PCS synchronization is changing from reliance on crystal 61 to that of the utility grid supply. The internal PCS output regulation changes from voltage and frequency to power and VARs. Following the brief interval (less than 4 ms) for reconfiguring, the system 8 has been returned to the G/C state, or mode.
Although the invention has been described and illustrated with respect to the exemplary embodiments thereof, it should be understood by those skilled in the art that the foregoing and various other changes, omissions and additions may be made without departing from the spirit and scope of the invention. For example, the static switch module 17, and particularly switch 19 therein, is/are depicted as being separate from and external to, the fuel cells 18 and their respective PCS's, thus providing the economy of singular control elements responsible for controlling multiple fuel cells. However, it will be appreciated that these controls could be integral with or internal to the respective fuel cells, particularly if there is but a single fuel cell power plant. Moreover, although the static switch 19 is described in the context of pairs of SCRs, it will be appreciated that other static switching devices capable of similar switching speeds and current ratings may also be used. It will also be understood that a greater or lesser number of fuel cell power plants may be employed, and both the voltage and the current ratings associated with the elements discussed herein may be greater or less than described. Similarly, the control circuits described herein as being in the static switch module 17 could reside in the SMC 31.
|Cited Patent||Filing date||Publication date||Applicant||Title|
|US4004947||Feb 12, 1975||Jan 25, 1977||United Technologies Corporation||Pressurized fuel cell power plant|
|US5401589||Nov 22, 1991||Mar 28, 1995||Vickers Shipbuilding And Engineering Limited||Application of fuel cells to power generation systems|
|US5573867||Jan 31, 1996||Nov 12, 1996||Westinghouse Electric Corporation||Purge gas protected transportable pressurized fuel cell modules and their operation in a power plant|
|US5579197||Jan 24, 1995||Nov 26, 1996||Best Power Technology, Incorporated||Backup power system and method|
|US5750278||Aug 10, 1995||May 12, 1998||Westinghouse Electric Corporation||Self-cooling mono-container fuel cell generators and power plants using an array of such generators|
|US5783932||Mar 21, 1996||Jul 21, 1998||Hitachi, Ltd.||Power generation plant and control apparatus therefor|
|US5986354||Apr 24, 1996||Nov 16, 1999||Canon Kabushiki Kaisha||DC source system with solar cell, and its operation method|
|US6011324||Oct 7, 1996||Jan 4, 2000||Aeg Energietechnik Gmbh||Arrangement for ensuring uninterrupted current supply to an electrical consumer|
|US6198176||Feb 16, 1999||Mar 6, 2001||Statordyne Llc||UPS/CPS system|
|US6198177 *||Jan 7, 2000||Mar 6, 2001||Lucent Technologies Inc.||Power supply providing backup AC voltage and method of operation thereof|
|US6288456||May 18, 1999||Sep 11, 2001||Sure Power Corporation||Power system|
|US6583523||Aug 9, 2000||Jun 24, 2003||Inverters Unlimited, Inc.||Parallel DC power sources with different characteristics|
|US6602627||Mar 20, 2001||Aug 5, 2003||Alpha Technologies, Inc.||Uninterruptible power supplies using fuel cells|
|US20030012038 *||Oct 29, 2001||Jan 16, 2003||Welches Richard S.||Inverter DC link volts "tooth" modulation scheme|
|WO1999060687A1||May 17, 1999||Nov 25, 1999||Sure Power Corp||Power system|
|Citing Patent||Filing date||Publication date||Applicant||Title|
|US7646113 *||Sep 13, 2006||Jan 12, 2010||Cummins Power Generation, Inc.||Method of providing generator set standby power|
|US7973533||Feb 27, 2008||Jul 5, 2011||Vertical Power, Inc.||In-circuit testing for integrity of solid-state switches|
|US8212401||Jul 31, 2008||Jul 3, 2012||Stratascale, Inc.||Redundant isolation and bypass of critical power equipment|
|US8294297 *||Jul 31, 2008||Oct 23, 2012||Ragingwire Enterprise Solutions, Inc.||Scalable distributed redundancy|
|US8803350 *||Jun 26, 2012||Aug 12, 2014||Siemens Aktiengesellschaft||Method and controller for controlling an electric power production unit, in particular a wind turbine|
|US20080061629 *||Sep 13, 2006||Mar 13, 2008||Cummins Power Generation Inc.||Method of providing generator set standby power|
|US20090033153 *||Jul 31, 2008||Feb 5, 2009||Ragingwire Enterprise Solutions, Inc.||Scalable distributed redundancy|
|US20090033154 *||Jul 31, 2008||Feb 5, 2009||Ragingwire Enterprise Solutions, Inc.||Redundant isolation and bypass of critical power equipment|
|US20110278921 *||Nov 17, 2011||Erik Jon Fretheim||Adaptive Power Bus|
|US20130001946 *||Jan 3, 2013||Kaj Skov Nielsen||Method and controller for controlling an electric power production unit, in particular a wind turbine|
|U.S. Classification||307/64, 307/45, 307/80, 307/70, 307/44, 307/43|
|International Classification||H02J7/00, H01M8/00, H02J3/32, H02J9/06|
|Cooperative Classification||Y10T307/615, Y10T307/50, Y10T307/505, Y10T307/696, Y10T307/511, Y10T307/647, H02J9/062, H02J2001/004, H02J3/32, Y02B90/14|
|European Classification||H02J9/06C, H02J3/32|
|Apr 8, 2010||FPAY||Fee payment|
Year of fee payment: 8
|Feb 25, 2014||AS||Assignment|
Owner name: CLEAREDGE POWER, LLC, CONNECTICUT
Free format text: CHANGE OF NAME;ASSIGNORS:UTC FUEL CELLS, LLC;UTC POWER CORPORATION;CLEAREDGE POWER CORPORATION;SIGNING DATES FROM 20070101 TO 20140122;REEL/FRAME:032332/0836
|Mar 19, 2014||FPAY||Fee payment|
Year of fee payment: 12
|Aug 5, 2014||AS||Assignment|
Owner name: DOOSAN FUEL CELL AMERICA, INC., GEORGIA
Free format text: ASSIGNMENT OF ASSIGNORS INTEREST;ASSIGNOR:CLEAREDGE POWER, INC., CLEAREDGE POWER, LLC, CLEAREDGE POWER INTERNATIONAL SERVICE, LLC;REEL/FRAME:033472/0094
Effective date: 20140718