`Umted States Patent
`
`[19]
`
`USOOSS43970A
`[11] Patent Number:
`
`5,343,970
`
`Se'verinsky
`
`[45] Date of Patent:
`
`Sep. 6, 1994
`
`[54] HYBRID ELECTRIC VEHICLE
`.
`Inventor: Alex J: Sevenneky, 10904 Pebble
`Run, Sllver Sprmg, Md. 20902
`
`[76]
`
`,
`[21] APPL No" 947,691
`[22] Filed:
`Sep, 21, 1992
`
`6
`[5 1
`
`
`
`Int. Cl.5 ................................................ B60K 6/04
`[51]
`[52] US. Cl. .................................. 180/65.2;180/65.6;
`p
`180/165; 60/718; 475/2; 475/5
`[58] Field of Search .................... ISO/65.2, 65.3, 65.4,
`ISO/65.6, 165; 60/716, 718; 475/2, 5, 8, 9
`.
`References 0““
`US. PATENT DOCUMENTS
`180/65 2
`3 525 874 8/1970 T
`.
`oy ........................
`,
`,
`ISO/65.2
`3,566,717
`3/1971 Berman et a1.
`..
`180/652
`3,650,345
`3/1972 Yardney ..........
`£823:
`3:31.57; 323;: £222? et 31
`180”55:4
`3:837:419 9/1974 Nakamiiraiw
`180/65.4
`3,874,472 4/1975 Deane .........
`ISO/65.2
`3,923,115 12/1975 Helling
`ISO/65.2
`4,042,056 8/1977 Horwinski
`180/654
`4,095,664 6/1978 Bray ------------
`180/65-2
`4,148,192 4/1979 Cummings-
`180/65.2
`4,180,138 12/1979 Shea............
`
`2,332,322 15/1981 Rosen .................
`ISO/65.2
`,
`,
`2/1981 Kawakatsu et a].
`.. ISO/65.2
`4,306,156 12/1981 Monaco et a1.
`.....
`.. 180/65.2
`
`1/1982 Park ................
`4,313,080
`180/65.2
`
`4,335,429 6/1982 Kawakatsu...
`ISO/65.2
`9/1982 Fields et a1.
`4,351,405
`ISO/65.2
`
`4,354,144 10/1982 McCarthy
`ISO/65.4
`4,400,997
`8/1983 Fiala --------
`- .. 180/65.2
`4,405,029
`9/1983 Hum.-
`130/653
`
`4’407'132 10/1983 Kawakatsu 5" a1
`180/65'4
`4,438,342 3/1984 Kenyon ..............
`.... ISO/65.2
`
`4,439,989 4/1984 Yamakawa ..
`....... 60/718
`4,470,476 9/1984 Hunt .......................
`ISO/65.2
`
`8/1985 Heidemeyer et a1.
`.
`I: 180/65.2
`4,533,011
`1/1986 Yang ......................
`.. 180/65.2
`4,562,894
`
`1.80/654
`4,578,955 4/1986 Medina
`
`4,593,779 6/1986 Krohling ............................ 180/65.4
`4,611,466 9/1986 Keedy ................ 60/718
`
`. 180/65.2
`4,697,660 10/1987 Wu etal.
`4,815,334 3/1989 Lexen ............. 74/661
`
`5/1990 Ellers .............. 180/652
`4,923,025
`
`8/1990 Kawamura .......... 180/65.4
`4,951,769
`
`5,053,632 10/1991 Suzuki et a1.
`..
`..... ISO/65.2
`
`6/1992 Nishida ............... ISO/65.2
`5,117,931
`6/1992 Fjallstrom ...................... 180/65.4x
`5,120,282
`
`.
`
`9 PP
`
`OTHER PUBLICATIONS
`SAE Technical Paper Series 891659, Bullock, pp.
`11—26, Aug. 7—10, 1989.
`SAE Technical Pa er Series 910247 Kalberlah
`P
`2
`69—78, Feb. 25—Mar. 1, 1991.
`.
`_
`.
`Przmary Exammer—Margaret A. Focarmo
`-
`-
`__
`-
`AssurantExammer Peter C‘ EnghSh
`[57]
`ABSTRACT
`An improved hybrid electric vehicle includes an inter-
`nal combustion engine and an electric motor. Both the
`motor and the engine provide torque t0 drive the vehi-
`cle directly through a controllable torque transfer unit.
`Typically at low speeds or in traffic, the electric motor
`alone drives the vehicle, using power stored in batteries;
`under acceleration and during hill climbing both the
`engine and the motor provide torque to drive the vehi-
`cle; and in steady State highway cruising, the internal
`.
`.
`.
`.
`.
`combusno“ ,engme €110“? arms the veh‘de‘ The mt?"
`“a1 9°mbusn°n engine 15 mad t0 PPerate at at, near “5
`maXImum fuel effieleney dunng highway ermsmg- The
`motor is operable as a generator to charge the batteries
`as needed and also for regenerative braking. No trans-
`mission is employed. The motor operates at Signifi-
`cantly lower currents and higher voltages than conven-
`tionally and has a rated power at least equal to that of
`the internal combustion engine. In this manner a COSt
`efficient vehicle is
`rovided sufferin no
`If
`P
`1
`g
`Pe °man°e
`disadvantage GOmPal'eC1 to conventional vehides-
`
`40 Claims, 12 Drawing Sheets
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`DIRECTION
`DECElERATlON
`
`ENGINE SPEED
`
`MOTOR SPED
`WW VOW“
`BATTERY CHARGE
`AMBIENT TEMP.
`
`DATA INPUT
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`1
`
`HYBRID ELECTRIC VEHICLE
`
`BACKGROUND OF THE INVENTION
`
`5,343,970
`
`2
`tween the diesel engine and the wheels of the locomo-
`tive. More particularly, an internal combustion engine
`produces zero torque at zero engine speed (RPM) and
`reaches its torque peak somewhere in the middle of its
`operating range. Accordingly, all vehicles driven di-
`rectly by an internal combustion engine (other than
`certain single-speed vehicles using friction or centrifu-
`gal clutches, and not useful for normal driving) require
`a multiple speed transmission between the engine and
`the wheels, so that the engine’s torque can be matched
`to the road speeds and loads encountered. Further,
`some sort of clutch must be provided so that the engine
`can be decoupled from the wheels, allowing the vehicle
`to stop while the engine is still running, and to allow
`some slippage of the engine with respect to the drive
`train while starting from a stop. It would not be practi-
`cal to provide a diesel locomotive with a multiple speed
`transmission, or a clutch. Accordingly, the additional
`complexity of the generator and electric traction mo-
`tors is accepted. Electric traction motors produce full
`torque at zero RPM and thus can be connected directly
`to the wheels; when it is desired that the train should
`accelerate, the diesel engine is simply throttled to in-
`crease the generator output and the train begins to
`move.
`
`The same drive system may be employed in a smaller
`vehicle such as an automobile or truck, but has several
`distinct disadvantages in this application. In particular,
`it is well known that a gasoline or other internal com-
`bustion engine is most efficient when producing near its
`maximum output torque. Typically, the number of die-
`sel locomotives on a train is selected in accordance with
`the total tonnage to be moved and the grades to be
`overcome, so that all the locomotives can be operated at
`nearly full torque production. Moreover, such locomo-
`tives tend to be run at steady speeds for long periods of
`time. Reasonably efficient fuel use is thus achieved.
`However, such a direct drive vehicle would not achieve
`good fuel efficiency in typical automotive use, involv-
`ing many short trips, frequent stops in traffic, extended
`low-speed operation and the like.
`So-called “series hybrid” electric vehicles have been
`proposed wherein batteries are used as energy storage
`devices, so that the engine can be operated in its most
`fuel-efficient output power range while still allowing
`the electric traction motor(s) powering the vehicle to be
`operated as required. Thus the engine may be loaded by
`supplying torque to a generator charging the batteries
`while supplying electrical power to the traction mo-
`tor(s) as required, so as to operate efficiently. This sys-
`tem overcomes the limitations of electric vehicles noted
`
`above with respect to limited range and long recharge
`times.
`However, such series hybrid electric vehicles are
`inefficient and grossly uneconomical, for the following
`reasons. In a conventional vehicle, the internal combus-
`tion engine delivers torque to the wheels directly. In a
`series hybrid electric vehicle, torque is delivered from
`the engine via a serially connected generator, battery
`charger, inverter and the traction motor. Energy trans-
`fer between those components consumes at least ap-
`proximately 25% of engine power. Further such com-
`ponents add substantially to the cost and weight of the
`vehicle. Thus, series hybrid vehicles have not been
`immediately successful.
`A more promising “parallel hybrid” approach is
`shown in US. Pat. Nos. 3,566,717 and 3,732,751 to
`
`10
`
`15
`
`20
`
`25
`
`30
`
`35
`
`1. Field of the Invention
`This invention is in the field of hybrid electric vehi-
`cles incorporating both an internal combustion engine,
`such as a gasoline engine, and an electric motor as
`sources of torque to drive the vehicle. More particu-
`larly, this invention relates to a hybrid electric vehicle
`that is fully competitive with presently conventional
`vehicles as regards performance, operating conve-
`nience, and cost, while achieving substantially im-
`proved fuel economy and reduced pollutant emissions.
`2. Discussion of the Prior Art
`For many years great attention has been given to the
`problem of reduction of fuel consumption of automo-
`biles and other highway vehicles. Concomitantly very
`substantial attention has been paid to reduction of pol-
`lutants emitted by automobiles and other vehicles. To a
`degree, efforts to solve these problems conflict with one
`another. For example, increased thermodynamic effi-
`ciency and thus reduced fuel consumption can be real-
`ized if an engine is operated at higher temperatures.
`Thus there has been substantial interest in engines built
`of ceramic materials withstanding higher combustion
`temperatures than those now in use. However, higher
`combustion temperatures in gasoline-fueled engines
`lead to increase in certain undesirable pollutants, typi-
`cally NOx.
`Another possibility for reducing emissions is to burn
`mixtures of gasoline and ethanol (“gasoho ”) or straight
`ethanol. However, to date ethanol has not become eco-
`nomically competitive with gasoline and consumers
`have not accepted ethanol to any great degree.
`One proposal for reducing pollution in cities is to
`limit the use of vehicles powered by internal combus-
`tion engines and instead employ electric vehicles pow-
`ered by rechargeable batteries. To date, all such electric
`cars have a very limited range, typically no more than
`150‘miles, have insufficient power for acceleration and
`hill climbing except when the batteries are fully
`charged, and require substantial time for battery re-
`charging. Thus, while there are many circumstances in
`which the limited range and extended recharge time of 45
`the batteries would not be an inconvenience, such cars
`are not suitable for all the travel requirements of most
`individuals. Accordingly, an electric car would have to
`be an additional vehicle for most users, posing a sub-
`stantial economic deterrent. Moreover, it will be appre-
`ciated that in the United States most electricity is gener-
`ated in coal-fired power plants, so that using electric
`vehicles merely moves the source of the pollution, but
`does not eliminate it. Furthermore, comparing the re-
`spective net costs per mile of driving, electric vehicles
`are not competitive with ethanol-fueled vehicles, much
`less with conventional gasoline-fueled vehicles.
`Much attention has also been paid over the years to
`development of electric vehicles including internal
`combustion engines powering generators, thus eliminat-
`ing the defect of limited range exhibited by simple elec-
`tric vehicles. The simplest such vehicles operate on the
`same general principle as diesel-electric locomotives
`used by most railroads. In such systems, an internal
`combustion engine drives a generator providing electric
`power to traction motors connected directly to the
`wheels of the vehicle. This system has the advantage
`that no variable gear ratio transmission is required be-
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`Berman et al. In Berman et al an internal combustion
`engine and an electric motor are matched through a
`complex gear train so that both can provide torque
`directly to the wheels.
`In Berman et al, the internal combustion engine is run
`in several different modes. Where the output of the
`internal combustion engine is more than necessary to
`drive the vehicle (“first mode operation”) the engine is
`run at constant speed and excess power is converted by
`a first generator (“Speeder”) to electrical energy for
`storage in a battery. In “second mode operation”, the
`internal combustion engine drives the wheels directly,
`and is throttled. When more power is needed than the
`engine can provide, a second motor generator or
`“torquer” provides additional torque as needed.
`The present invention relates to such a parallel hybrid
`vehicle, but addresses certain substantial deficiencies of
`the Berman et a1 design. For example, Berman et al
`show two separate electric motor/generators powered
`by the internal combustion engine to charge batteries
`and to drive the vehicle forward in traffic. This arrange-
`ment is a source of additional complexity, cost and
`difficulty, as two separate modes of engine control are
`required, and the operator must control the transition
`between the several modes of operation. Further the
`gear train shown by Berman et a1 appears to be quite
`complex and diffith to manufacture economically.
`Berman et al also indicate that one or even two variable-
`speed transmissions may be required; see col. 3, lines
`19—22 and 36—38.
`Hunt U.S. Pat. Nos. 4,405,029 and 4,470,476 also
`disclose parallel hybrids requiring complex gearing
`arrangements, including multiple speed transmissions.
`More specifically,
`the Hunt patents disclose several
`embodiments of parallel hybrid vehicles. Hunt indicates
`(see col. 4, lines 6-20 of the ’476 patent) that an electric
`motor may drive the vehicle at low speeds up to 20
`mph, and an internal combustion engine used for speeds
`above 20 mph, while “in certain speed ranges, such as
`from 15—30 mph, both power sources may be energized.
`.
`.
`. Additionally, both power sources could be utilized
`under heavy load conditions.” Hunt also indicates that
`“the vehicle could be provided with an automatic
`changeover device which automatically shifts from the
`electrical power source to the internal combustion
`power source, depending on the speed of the vehicle”
`(col. 4, lines 12—16).
`However, the Hunt vehicle does not meet the objects
`of the present invention. Hunt’s vehicle in each embodi-
`ment requires a conventional manual or automatic
`transmission. See col. 2, lines 6—7. Moreover, the inter-
`nal combustion engine is connected to the transfer case
`(wherein torque from the internal combustion engine
`and electric motor is combined) by a “fluid coupling or
`torque converter of conventional construction”. Col. 2,
`lines 16-17. Such transmissions and fluid couplings or
`torque converters are very inefficient, are heavy, bulky,
`and costly, and are to be eliminated according to one
`object of the present invention.
`Furthermore, the primary means of battery charging
`disclosed by Hunt involves a further undesirable com-
`plexity, namely a turbine driving the electric motor in
`generator configuration. The turbine is fueled by waste
`heat from the internal combustion engine. See col. 3,
`lines 10-60. Hunt’s internal combustion engine is also
`fitted with an alternator, for additional battery charging
`capability, adding yet further complexity. Thus it is
`clear that Hunt fails to teach a hybrid vehicle meeting
`
`4
`the objects of the present invention—that is, a hybrid
`vehicle competitive with conventional vehicles with
`respect to performance, cost and complexity, while
`achieving substantially improved fuel efficiency.
`Kawakatsu U.S. Pat. No. 4,335,429 shows a parallel
`hybrid involving a single internal combustion engine
`and two electric motors to allow efficient use of the
`electric motors, and is directed principally to a complex
`control scheme.
`
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`Numerous patents disclose hybrid vehicle drives
`tending to fall into one or more of the categories dis-
`cussed above. A number of patents disclose systems
`wherein an operator is required to select between elec-
`tric and internal combustion operation; for example an
`electric motor is provided for operation inside buildings
`where exhaust fumes would be dangerous. In several
`cases the electric motor drives one set of wheels and the
`internal combustion engine drives a different set. See
`generally, U.S. Pat. Nos.; Shea (4,180,138); Fields et al
`(4,351,405); Kenyon (4,438,342); Krtihling (4,593,779);
`and Ellers (4,923,025).
`Numerous other patents show hybrid vehicle drives
`wherein a variable speed transmission is required. A
`transmission as noted above is typically required where
`the electric motor is not capable of supplying sufficient
`torque at
`low speeds. See U.S. Pat. Nos.; Rosen
`(3,791,473); Rosen (4,269,280); Fiala (4,400,997); and
`Wu et a1 (4,697,660). For further examples of series
`hybrid vehicles as discussed above, see generally Bray
`(4,095,664); Cummings (4,148,192); Kawakatsu et a1
`(4,305,254 and 4,407,132); Monaco et a1 (4,306,156);
`Park (4,313,080); McCarthy (4,354,144); Heidemeyer
`(4,533,011); Kawamura (4,951,769); and Suzuki et a1
`(5,053,632). Other patents of general relevance to this
`subject matter
`include Toy (3,525,874); Yardney
`(3,650,345); Nakamura (3,837,419); Deane (3,874,472);
`Horwinski
`(4,042,056); Yang
`(4,562,894); Keedy
`(4,611,466); and Lexen (4,815,334).
`U.S. Pat. No. 4,578,955 to Medina shows a hybrid
`system wherein a gas turbine is used as the internal
`combustion engine to drive a generator as needed to
`charge batteries. Of particular interest to certain aspects
`of the present invention is that Medina discloses that the
`battery pack should have a voltage in the range of 144,
`168 or 216 volts and the generator should deliver cur-
`rent in the range of 400 to 500 amperes. Those of skill in
`the art will recognize that these high currents involve
`substantial resistance heating losses, and additionally
`require that all electrical connections be made by posi-
`tive mechanical means such as bolts and nuts, or by
`welding. More specifically, for reasons of safety and in
`accordance with industry practice, currents in excess of
`about 50 amperes carmot be carried by the conventional
`plug-in connectors preferred for reasons of convenience
`and economy, but must be carried by much heavier,
`more expensive and less convenient fixed connectors (as
`used on conventional starter and battery cable connec-
`tions). Accordingly, it would be desirable to operate the
`electric motor of a hybrid vehicle at lower currents.
`U.S. Pat. No. 4,439,989 to Yamakawa shows a system
`wherein two different internal combustion engines are
`provided so that only one need be run when the load is
`low. This arrangement would be complex and expen-
`sive to manufacture.
`
`Detailed discussion of various aspects of hybrid vehi-
`cle drives may be found in Kalberlah, “Electric Hybrid
`Drive Systems for Passenger Cars and Taxis”, SAE
`Paper No. 910247 (1991), and in Bullock, “The Techno-
`
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`logical Constraints of Mass, Volume, Dynamic Power
`Range and Energy Capacity on the Viability of Hybrid
`and Electric Vehicles”, SAE Paper No. 891659 (1989).
`Further related papers are collected in Electric and
`Hybrid Vehicle Technology, volume SP—915, published
`by SAE in February 1992. Reference herein to the latter
`volume does not concede its effectiveness as prior. art
`with respect to the claims of the present application.
`It can thus be seen that while the prior art clearly
`discloses the desirability of operating an internal com-
`bustion engine in its most efficient operating range, and
`that a battery may be provided to store energy to be
`supplied to an electric motor in order to even out the
`load on the internal combustion engine, there remains
`substantial room for improvement. In particular, it is
`desired to obtain the operational flexibility of a parallel
`hybrid system, while optimizing the system’s opera-
`tional parameters and providing a substantially simpli-
`fied parallel hybrid system as compared to those shown
`in the prior art.
`
`OBJECTS AND SUMMARY OF THE
`INVENTION
`
`It is an object of the invention to provide an im-
`proved hybrid electric vehicle realizing substantially
`increased fuel economy and reduced pollutant emis-
`sions as compared to present day vehicles while suffer-
`ing no significant penalty in performance, operating
`convenience, cost, complexity, or weight.
`It is a more particular object of the present invention
`to provide an improved parallel hybrid electric vehicle
`wherein an internal combustion engine and an electric
`motor can separately or simultaneously apply torque to
`the driving wheels of the vehicle, controlled to realize
`maximum fuel efficiency at no penalty in convenience,
`performance, or cost.
`It is a further object of the invention to provide a
`parallel hybrid electric vehicle wherein the electric
`motor provides output power equal to at least 100 per-
`cent of the rated output power of the internal combus-
`tion engine, and more preferably up to about 150-200
`percent thereof, so that the engine operates under sub-
`stantially optimum conditions in order to realize sub-
`stantial fuel economy of operation.
`More particularly, it is an object of the invention to
`provide a parallel hybrid electric vehicle wherein the
`internal combustion engine is sized to efficiently pro-
`vide the average power required for operation at mod-
`erate and highway speeds, with the electric motor sized
`to deliver the additional power needed for acceleration
`and hill climbing.
`Still another object of the invention is to provide a
`hybrid electric vehicle wherein the electric motor and
`battery charging circuits operate at no more than about
`30—50 amperes maximum current, whereby resistance
`heating losses are greatly reduced, and whereby inex-
`pensive and simple electrical manufacturing and con-
`nection techniques can be employed.
`It is a further object of the invention to provide a
`solid-state switching power converter for converting
`DC power provided by the batteries of a parallel hybrid
`electric vehicle to AC power of higher frequency than
`conventionally employed for supply to an AC induction
`motor for powering the vehicle as needed, and for con-
`verting mechanical energy provided to the induction
`motor when operated as a generator to DC energy for
`charging the batteries as required.
`
`6
`Other aspects and objects of the invention will be-
`come clear as the discussion below proceeds.
`The present invention satisfies the needs of the art
`and objects of the invention mentioned above by provi-
`sion of an improved parallel hybrid electric vehicle. An
`internal combustion engine and an AC induction motor
`are arranged to supply torque through a controllable
`torque transfer unit to the driving wheels of the vehicle.
`The motor is driven at relatively high voltage, rela-
`tively high frequency, and relatively low maximum
`current. Energy stored in batteries is transformed into
`AC drive pulses of appropriate frequency and shape by
`a solid state switching unit comprising metal oxide semi-
`conductor (MOS) controlled thyristors. No variable
`gear ratio transmission is required by the vehicle of the
`present invention, as the AC electric motor provides
`adequate torque at low RPM. Inefficiencies particularly
`inherent in automatic transmissions are thus eliminated.
`A microprocessor receives control inputs from the
`driver of the vehicle and monitors the performance of
`the electric motor and the internal combustion engine,
`the state of charge of the battery, and other significant
`variables. The microprocessor determines whether the
`internal combustion engine or the electric motor or
`both should provide torque to the wheels under various
`monitored operating conditions. Typically, the electric
`motor operates under battery power during low speed
`Operation, e.g., in traffic, during reverse operation, or
`the like. In this mode of operation, the energy transfer
`efficiency from the batteries to the wheels is very high.
`By comparison, it will be appreciated that a vast amount
`of fuel is wasted as internal combustion engines of con-
`ventional vehicles idle uselessly at stop lights or in traf-
`fic. This source of inefficiency and pollution is elimi-
`nated according to the invention.
`As the road speed increases, the internal combustion
`engine is started, using torque provided by the electric
`motor through the torque transfer unit, such that no
`separate starter is required. The internal combustion
`engine is sized to operate near maximum efficiency
`during steady state cruising on the highway, at between
`about 35 and 65 mph; at these times the electric motor is
`not powered. When necessary for acceleration or hill
`climbing, the electric motor is operated to add its torque
`to that provided by the internal combustion engine.
`Under braking or coasting conditions,
`the electric
`motor may be operated as a generator to charge the
`batteries.
`
`For comparison to an example of the hybrid electric
`vehicle of the invention, a conventional 3,300 pound
`sedan is typically powered by a 165 horsepower internal
`combustion engine driving the rear wheels through an
`automatic transmission. However, during highway
`cruising and in traffic, that is, under the most common
`operating conditions, only 2—30 hp is required. There-
`fore, the internal combustion engine of a conventional
`vehicle rarely operates near maximum efficiency. More-
`over, as noted, such vehicles are normally driven
`through notoriously inefficient automatic transmissions;
`specifically, such transmissions are typically only about
`60% efficient during operation in the indirect gears, i.e.,
`during acceleration.
`A comparable 3,300 pound sedan according to the
`invention has an internal combustion engine of about 45
`horsepower working in concert with a 65 horsepower
`electric motor, without a transmission. This combina-
`tion provides acceleration and hill climbing perfor-
`mance equivalent to a conventional vehicle with a 165
`
`5
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`10
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`15
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`20
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`25
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`30
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`35
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`45
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`50
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`55
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`65
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`
`DESCRIPTION OF THE PREFERRED
`EMBODIMENTS
`
`7
`hp internal combustion engine with automatic transmis-
`sion, while yielding a ZOO—300% improvement in net
`fuel efficiency and at least a similar reduction in pollut-
`ants emitted. Moreover, the vehicle of the present in-
`vention is no heavier, no more bulky and no more ex-
`pensive to manufacture than conventional vehicles
`using standard internal combustion engines.
`More particularly, according to the invention, the
`internal combustion engine is operated only under the
`most efficient conditions of output power and speed.
`When the engine can be used efficiently to drive the
`vehicle forward, e.g. in highway cruising, it is so em-
`ployed. Under other circumstances, e.g. in traffic, the
`electric motor alone drives the vehicle forward and the
`internal combustion engine is used only to charge the
`batteries as needed. No transmission is required, thus
`effecting a very substantial saving in both weight and
`cost. The AC electric motor is controlled to operate as
`a constant torque source at low motor speeds, and as a
`constant power source at higher speeds. The motor
`operates at relatively low currents and relatively high
`voltage and frequency, as compared with conventional
`practice. Connections between the battery and the elec-
`tric motor are substantially simplified through the use of
`relatively low maximum current, and at relatively resis- 25
`tance heating losses are likewise reduced substantially.
`The above and still further objects, features and ad-
`vantages of the present invention will become apparent
`upon consideration of the following detailed description
`of a specific embodiment thereof, especially when taken
`in conjunction with the accompanying drawings
`wherein like reference numerals in the various figures
`are utilized to designate like components.
`BRIEF DESCRIPTION OF THE DRAWINGS
`
`5
`
`10
`
`15
`
`20
`
`30
`
`35
`
`Referring specifically to FIG. 1, curve 10 represents
`the output power versus engine speed (RPM) of a typi-
`cal spark ignition gasoline-fueled internal combustion
`engine as used with an automatic transmission in a typi-
`cal sedan of 3,300 pounds. As can be seen, the maximum
`engine power available is about 165 horsepower at
`about 5,000 RPM. Also shown in FIG. 1 by curve 12
`are the average power requirements of such a vehicle.
`Points C, S and H on curve 12 show average fuel con-
`sumption in city, suburban and highway driving, re-
`spectively. Point C on curve 12 shows that the average
`power required in typical city driving is less than 5 hp.
`Point S shows that the average power consumed in
`suburban driving is 10 hp, and point H shows that the
`power needed for steady-speed highway driving is only
`about 30 hp. Thus, the vehicle is vastly overpowered at
`all times except during acceleration or hill-climbing.
`FIG. 1 also includes curves indicating the relative
`fuel consumption of the engine. As can be seen, reason-
`able fuel efficiency, that is, at least about 105 percent
`relative fuel consumption (100% being ideal), is reached
`only when the engine is operated at between about
`2,000 and 4,000 RPM, when producing between about
`75 and 150 horsepower. FIG. 1 thus indicates that the
`typical internal combustion engine operates with rea-
`sonable efficiency only when producing between about
`50 and about 90% of its maximum output power. The
`typical automobile only requires such substantial power
`under conditions of extreme acceleration or hill climb-
`ing. Thus, only during relatively brief intervals is the
`engine operating efficiently. As can be seen, during
`typical highway driving, shown by point H on curve 12,
`the relative fuel consumption is on the order of 190
`percent of that required during the most efficient opera-
`tion of the engine. The situation is even worse in subur-
`ban driving, where the relative fuel consumption is
`nearly 300 percent of the most efficient value, and in
`city driving, where the relative fuel consumption is
`almost 350 percent of that required at most efficient
`operation.
`FIG. 1 thus demonstrates that an internal combustion
`engine having sufficient horsepower for adequate accel-
`eration and hill climbing capability must be so oversized
`with respect to the loads encountered during most nor-
`mal driving that the engine is grossly inefficient in its
`consumption of fuel. As noted, FIG. 1 further shows
`that only about 30 horsepower is needed to cruise on
`the highway even in a relatively large car.
`FIG. 2 is similar to FIG. 1, and illustrates the opera-
`tional characteristics of the same 3,300 pound car if
`driven by a relatively small engine having a maximum
`horsepower rating of about 45 horsepower at 4,000
`RPM. The power requirement of the vehicle during
`highway cruising, shown by point H on curve 14, is in
`the center of the most efficient region of operation of
`the engine. However, even with this small engine thus
`optimized for highway cruising, there is a substantial
`gap between the engine operating power line 16 and the
`average power requirement line 14. That is, even this
`small engine produces substantially more power at low
`RPM than needed for city driving (point C) or for sub-
`urban driving (point S). Accordingly, even with a small
`engine sized appropriately for highway cruising, sub-
`stantial inefficiencies at lower speeds persist. Moreover,
`of course, such a vehicle wou