Patent Abstract:
A hybrid powertrain system includes a combustion engine, a battery buffer for storing electric energy by converting it onto chemical energy, which can be converted back into electrical energy when need, a fuel cell unit having multiple fuel cells each of which is an electrochemical energy conversion device that converts hydrogen and oxygen into water, producing electricity and heat in the process, a power level control unit for capturing electrical energy from the fuel cell unit for delivering zero power, full power, or any power level in between, and an electric motor having inputs for receiving energy from the combustion engine, the battery buffer and the fuel cell auxiliary power unit, and an output for generating activation power to a transmission providing a driving force to a vehicle.

Full Description:
BACKGROUND OF THE INVENTION 
   Electric and hybrid electric vehicles have been available for many years. A hybrid electric vehicle is a vehicle that generally has two sources of energy. One of the sources of energy is electric, and the other source of energy is derived from an internal combustion engine that typically burns diesel or gasoline fuel. A hybrid electric vehicle typically has a greater range than that of an electric vehicle before the batteries need recharging. Moreover, a hybrid electric vehicle is typically equipped with means for charging the batteries through its onboard internal combustion engine. 
   Generally, a hybrid electric vehicle employs an internal combustion engine and an electric motor to either alternately or in combination provide a driving force for a vehicle. There are several types of electric propulsion systems for hybrid electric vehicles. For example, a pure electric drive system, a series hybrid system, a parallel hybrid system, and a combined series-parallel hybrid system are a few of the designs currently being considered. 
   Since many of the functions of a hybrid electric vehicle involve an energy storage system (e.g., batteries) and then using this energy at a later time, the performance of the hybrid system is highly dependent on the energy storage system. Some of the factors that are associated with the energy storage system requirements are: power capability, energy capacity, life, cost, volume, mass, temperature, characteristic, etc. 
   SUMMARY OF THE INVENTION 
   In an exemplary embodiment, a hybrid powertrain system comprises: an electric motor for providing a mechanical driving force to a vehicle; an engine mechanically coupled to the electric motor for providing mechanical power to drive the electric motor; a fuel cell unit electrically coupled to the electric motor for providing electrical power to power the motor, the fuel cell unit configured in a parallel relationship with respect to the engine; and a battery electrically coupled to the electric motor for providing electrical power to power the motor, the battery configured in a parallel relationship with the engine and the fuel cell. 
   The hybrid powertrain system further includes power conditioning electronics for conditioning, controlling and/or regulating the electrical power from the fuel cell unit provided to power the motor. 
   The hybrid powertrain system further includes a clutch disposed between the combustion engine and the motor for selectively providing pure electrical or mechanical propulsion power for a vehicle. 

   
     BRIEF DESCRIPTION OF THE DRAWINGS 
     The hybrid powertrain system will now be described, by way of example only, with reference to the accompanying drawings, which are meant to be exemplary, not limiting, and wherein like elements are numbered alike in several figures. 
       FIG. 1  is a schematic diagram illustrating a hybrid powertrain system according to an embodiment of the present invention; 
       FIG. 2  is a schematic diagram illustrating a solid oxide fuel cell used in the fuel cell auxiliary power unit in  FIG. 1 ; 
       FIG. 3  is a table showing fuel efficiency of the hybrid powertrain system of the present invention; and 
       FIG. 4  is a graph showing a propulsion power derived from the fuel cell power unit or the internal combustion engine in different hybrid powertrain systems of the present invention. 
   

   DETAILED DESCRIPTION OF INVENTION 
   Referring to  FIG. 1 , there is provided hybrid powertrain system according to an exemplary embodiment of the present invention, which is employed in a vehicle. Propulsion of the vehicle is powered by one of the energy sources: a combustion engine  111 , a battery buffer  113 , and a fuel cell unit  115 . The combustion engine  111  may be an internal engine using, as its fuel, gasoline, diesel, liquefied petroleum gas (LPG), alcohols, compressed natural gas (CNG), hydrogen and/or other alternative fuels. The combustion engine is coupled to a motor  119  to mechanically drive the motor  119 , rather than electrically power the motor  119 . The fuel cell auxiliary power unit  115  provides, through a power level control unit  117 , electric energy sufficient to power the motor  119 . The battery buffer  113  is provided to handle electrical transient responses, but may also be used to start the engine, to power electrical accessories, and other such uses. The battery buffer  113  may also be used to provide electric energy sufficient to power the motor  119 . 
   The fuel cell unit  115  (or fuel cell auxiliary power unit) is comprised of multiple fuel cells, which are often configure in a fuel cell stack, as is well known and is discussed in more detail below. The fuel cells provide the power level control unit  117  (or power conditioning electronics) with a DC (direct current) voltage to power a motor  119  for providing mechanical energy to a transmission  121  of the vehicle. The fuel cells may be any one of the various types of fuel cells such as polymer electrolyte membrane fuel cell, phosphoric acid fuel cell, direct methanol fuel cell, alkaline fuel cell, molten carbonate fuel cell, solid oxide fuel cell, regenerative fuel cell, etc. In the preferred embodiment, the fuel cell auxiliary power unit employs solid oxide fuel cells. 
   The power conditioning electronics  117  captures electrical energy from the fuel cell auxiliary power unit  115 . The power conditioning electronics  117  includes a controller (not shown) for delivering the electrical energy to the motor. The controller is designed to deliver zero power (e.g., when the vehicle is stopped), full power (e.g., when the vehicle is accelerated), or any power level in between. 
   The battery buffer  113  also provides electric power to the motor  119  to be used as the propulsion power. For example, the battery buffer  113  provides electric power to the motor  119  while the fuel cell auxiliary power unit  115  is warmed up to a selected temperature. The electric power from the battery buffer  113  may also be used to power electrical accessories such as headlights, radios, fans, wipers, air bags, computers and instruments inside the vehicle. 
   The motor  119  is mechanically coupled to the combustion engine  111  so that mechanical power generated by the combustion engine  111  is delivered through the motor  119 . The battery buffer  113  and the fuel cell auxiliary power unit  115  (through the power conditioning electronics  117 ) are connected to electrical inputs of the motor. The battery buffer  113  preferably provides a buffer of electrical energy such that when operated with the fuel cell auxiliary unit  115  reliable continuous electrical energy is provided to the motor  119 . The combustion engine  111 , the battery buffer  113 , and the fuel cell auxiliary unit  115  are arranged or connected in a parallel relationship with each other with respect to the motor  119 . The motor  119  is mechanically coupled to the transmission  121 , which provides a driving force to a drive shaft of the vehicle. The motor  119  may be a DC electric motor or an AC electric motor. In case of an AC motor, an AC controller (not shown) is provided to control a three-phase current to the inputs of the motor. 
   The electric motor  119  in this embodiment may also act as a generator as well as a motor. In other words, the electric motor  119  draws the electric energy from the battery buffer  113  and/or the fuel cell auxiliary power unit  115  (through the power conditioning electronics  117 ), for example, at the time of accelerating the vehicle. But the electric motor  119  also returns electric energy to the battery buffer  113 , for example; when powered by the combustion engine  111 , at the time of slowing down, or when braking the vehicle. 
   A power transfer control unit  123  is provided in the hybrid powertrain system between the combustion engine  111  and the motor  119  for selectively providing pure electric or mechanical propulsion power. In this embodiment, a clutch is employed as a power transfer control unit  123 . The clutch  123  when engaged provides for a direct connection of mechanical power to be transferred from the engine  111  through the motor  119  to the transmission  121 . When the clutch  123  is not engaged, only electrical power is available, whereby the motor  119  is powered by the electrical power, from the battery buffer  113  or the fuel cell auxiliary power unit  115 , which in turn delivers mechanical power through the transmission  121 . On the other hand, when the clutch  123  is engaged, the motor  119  is powered by the mechanical power from the combustion engine  111 . For example, when the engine  111  is in an active mode (i.e., turned-on mode), the clutch  123  is engaged so that the motor  119  receives the mechanical power from the engine  111 . When the engine is in an inactive mode (i.e., turned-off mode), the clutch  123  is not engaged so that the motor  119  receives the electrical power from either the fuel cell auxiliary power unit  115  (through the power conditioning electronics  117 ) or the battery buffer  113  or from both the fuel cell auxiliary power unit  115  and the battery buffer  113 . 
   Referring to  FIG. 2 , the fuel cell auxiliary power unit  115  in  FIG. 1  has solid oxide fuel cells each of which includes an anode  211 , a cathode  213  and an electrolyte  215  sandwiched between the thin electrodes, i.e., the anode  211  and cathode  213 . Hydrogen is fed to the anode  211  where a catalyst separates hydrogen&#39;s negatively charged electrons from positively charged ions as shown in the following reaction formula:
 
2H 2 →4H + +4e − 
 
   At the cathode  213 , oxygen combines with electrons and the negative ions travel through the electrolyte  215  to the anode  211  where they combine with hydrogen to produce water as shown in the following reaction formula:
 
O 2 +4H + +4e − →2H 2 O
 
   During the above reactions, the electrons from the anode side of the cell cannot pass through the electrolyte  215  to the positively charged cathode  213 . The electrons should travel around the electrolyte  215  via an electrical circuit to reach the other side of the cell. This movement of the electrons produces electrical current. 
   The amount of power produced by a fuel cell depends on several factors, such as fuel cell type, cell size, temperature, pressure at which the gases are supplied to the cell. The fuel cell auxiliary power unit contains multiple fuel cells which are combined in series into a fuel cell stack. 
   The fuel cells may also be fueled with hydrogen-rich fuels, such as methanol, natural gas, gasoline or gasified coal. In this case, a reformer (not shown) is additionally provided to extract hydrogen from the fuel. In other words, the reformer turns hydrocarbon or alcohol fuels into hydrogen, which is then fed to the fuel cells. 
   As describe above, the hybrid powertrain system of the present invention is provided with the hybrid power sources such as the combustion engine  111 , the battery buffer  113 , and the fuel cell auxiliary power unit  115 . Since the hybrid powertrain system draws electric energy from either the battery buffer  113  or the fuel cell auxiliary power unit  115 , or the combination thereof, it advantageously provides additional fuel efficiency and power electrification for propulsion and accessories of the vehicle. 
     FIG. 3  is a table showing fuel efficiency of the hybrid powertrain system of the present invention. In the first column of the table, different types of the hybrid powertrain systems are listed. In the first three lines, listed are the hybrid powertrain systems providing power only for propulsion (i.e., no electrical loads). In the next three lines, listed are the hybrid powertrain systems providing power for both the propulsion and electrical loads. The second column shows four different vehicle speeds, 40 MPH, 50 MPH, 60 MPH and 70 MPH. As shown in the table, the power for propulsion and electrical loads is derived from a solid oxide fuel cell unit alone at the lower vehicle speeds (here, 40 and 50 MPH), and derived from the combination of a solid oxide fuel cell unit and an internal combustion engine at the higher vehicle speeds (here, 60 and 70 MPH). 
   The data in  FIG. 3  shows that the hybrid powertrain system provides substantial improvement in fuel efficiency compared with those of the conventional powertrain system. For example, there is 34% improvement in fuel efficiency at vehicle speed 40 MPH when comparing the solid oxide fuel cell powertrain system for propulsion (50.4 MPG) with the conventional powertrain system for propulsion (37.6 MPG). Also, there is 16% improvement in fuel efficiency at vehicle speed 70 MPH when comparing the solid oxide fuel cell and internal combustion engine combined powertrain system (27.4 MPG) with the conventional powertrain system (23.6 MPG). 
     FIG. 4  is a graph showing a propulsion power derived from the fuel cell power unit or the internal combustion engine in different hybrid powertrain systems. In the graph, Option 1 represents a mild hybrid powertrain system, for example, a vehicle with a 2.5 liter cylinder gasoline engine, a 5 kw solid oxide fuel cell power unit, and a 42 volt generator for accessories; Option 2 represents a heavy hybrid powertrain system, for example, a vehicle with a 2.5 liter cylinder gasoline engine, a 20 kw ISG (integrated starter generator), a 20 kw solid oxide fuel cell power unit, and a 20 kw lithium battery; and Option 3 represents a “range extender” hybrid powertrain system, for example, a vehicle with a 10 kw solid oxide fuel cell power unit and 100 kg lithium battery. 
   In the hybrid powertrain system of Option 1, most propulsion power is derived from the gasoline engine as mechanical propulsion, and the fuel cell power unit makes little contribution to the propulsion power. In the hybrid powertrain system of Option 2, the propulsion power derived from the fuel cell power unit (i.e., electrical propulsion) substantially increases, while that derived from the gasoline engine (i.e., mechanical propulsion) decreases. Lastly, in the hybrid powertrain system of Option 3, most propulsion power is derived from the fuel cell power unit, and the gasoline engine makes little contribution to the propulsion power. 
   While the invention has been described with reference to the preferred embodiments, it will be understood by those skilled in the art that various changes may be made and equivalents may be substituted for elements thereof without departing from the scope of the invention. In addition, many modifications may be made to adapt a particular situation or material to the teachings of the invention without departing from the essential scope thereof. Therefore, it is intended that the invention may not be limited to the particular embodiment disclosed as the best mode contemplated for carrying out this invention.

Technology Classification (CPC): 1