Abstract:
A rotating fuel cell has a mounting with bearing means defining a rotary axis. A shaft with a longitudinally-extending bore is supported for rotation on the bearings. At least one PEM fuel cell assembly is mounted on the shaft and insulated therefrom, and also has a gas passageway in register with a radially-extending port in the shaft. Connections are provided for admitting hydrogen gas to the hollow bore. Air (oxygen) is supplied to the exterior of the PEM fuel cell assembly. The shaft and the PEM fuel cell assembly is rotated about the axis.

Description:
BACKGROUND AND SUMMARY OF THE INVENTION  
         [0001]    A fuel cell is an electrochemical device that utilizes a fuel (hydrogen) that is combined with oxygen to produce electric power, water, and heat. Importantly, there are no combustion processes taking place, so emissions such as CO 2  and NOX are eliminated. Further, fuel cells are particularly efficient compared to combustion engines.  
           [0002]    No matter what type, Solid Oxide, Proton Exchange Membrane (PEM), etc., all fuel cells have the same basic constituents: the anode, the electrolyte and the cathode. The anode is in contact with the hydrogen fuel and the cathode is in contact with the oxidant. As the fuel cell&#39;s reverse electrolysis takes place through the electrolyte wherein electric power is produced, water is formed on the surface of the cathode as oxygen combines with the ionized hydrogen (protons) that cross the electrolyte. The entire assembly also becomes heated due to the exothermal chemical process as it creates electricity.  
           [0003]    Conventional fuel cells are static devices wherein numerous anode/electrolyte/cathode cells are connected, generally in series, because the voltage produced by each fuel cell element is low, about a volt. Each fuel cell stack element is about 0.1 inches thick and, typically 5 to 10 inches square. Within each of these stack elements are various structural components that facilitate the supply of air (oxygen) and hydrogen as well as means to circulate cooling water within the fuel cell stack and remove water formed during operation.  
           [0004]    The present invention reveals a new type of fuel cell configuration that offers many attributes, especially in association with PEM fuel cells At its core, the rotating fuel cell, as its name implies, is a dynamic stack of fuel cell elements, called PEM “blades” hereinafter, that rotate within the surrounding air (oxidant stream) This dynamic fuel cell configuration has numerous advantages:  
           [0005]    Direct cathode exposure to the ambient air at a relative slow velocity, dissipates fuel cell waste heat readily; conventional fuel cell stack require complex internal water-cooling systems. The present invention simply transfers the heat directly to the ambient (or pressurized) air (much as in an air cooled engine) and not only eliminates the internal stack cooling system, but also eliminates the entire heat transfer system required to reject the heat gathered in the stack.  
           [0006]    The centrifugal force that arises due to the rotation of the fuel cell assembly readily rids the cathode of the accumulation of water that occurs to produce electricity (and heat). Keeping the exposed cathode surface free of water (“slinging it away”) improves the performance of the fuel cell because the surrounding air (oxygen) is always in contact with the cathode; the presence of liquid water gets in the way of air.  
           [0007]    Because the fuel cell blades of the rotating fuel cells are constantly in contact with new and turbulent air, the cathodic surface oxygen concentration will always be maximized.  
           [0008]    Perhaps most important, the fuel cell blades can be arranged in a fashion such that the rotating fuel cell assembly causes its own aspiration (much like a fan).  
         SUMMARY OF THE INVENTION  
         [0009]    The present invention, in broad terms, provides a rotating fuel cell comprising a housing means having bearing means which define a longitudinally-extending rotary axis. The fuel cell further includes an elongated shaft rotatably supported on the bearing means; the shaft has a hollow bore extending from one end thereof to a preselected length. The shaft further has a radially-extending port connecting the hollow bore to the outer surface of the shaft. A radially-extending PEM fuel cell assembly is positioned on the shaft to rotate therewith. The PEM fuel cell assembly has a gas passage therein which is in register with the port of the shaft. Means are provided for supplying hydrogen gas to the hollow bore of the shaft. Air (oxygen) is supplied to the exterior of the PEM fuel cell assembly. Motor means are connected to one end of the shaft and is adapted to rotate the shaft and the PEM fuel cell assembly about the axis in the oxidant. Electrical output means are connected to the PEM fuel cell assembly, e.g., slip rings, rotating transformer, etc.).  
           [0010]    In a preferred embodiment of the invention depicted in the drawings, a plurality of radially-extending PEM fuel cell assemblies are arranged in a stack and positioned on the shaft in side-by-side longitudinally-spaced-apart relationship; each of the assemblies having a gas passageway in register with one of a plurality of radially-extending and longitudinally-spaced-apart ports in the shaft. In all embodiments, the PEM fuel cell assemblies comprise a blade which is adapted, when rotated, to cause air, i.e., oxidant, to flow longitudinally against and around the assembly(ies). Also in the preferred embodiment, the shaft is electrically conductive and insulative means are positioned between the outer periphery of the shaft and the plurality of PEM assemblies. The PEM assemblies are electrically connected in series relationship to produce a total output voltage which is a function of the multiple of the output voltage of one assembly. 
       
    
    
     BRIEF DESCRIPTION OF THE DRAWINGS  
       [0011]    [0011]FIG. 1 is a longitudinal cross-sectional view of a preferred embodiment of my invention as viewed along section lines  1 - 1  of FIG. 2;  
         [0012]    [0012]FIG. 2 is cross-section of the apparatus shown in FIG. 1 as viewed along section lines  2 - 2  of FIG. 1;  
         [0013]    [0013]FIG. 3 is a plan view, partly in section, of a PEM fuel cell blade assembly  32 ;  
         [0014]    [0014]FIGS. 4 and 5 are cross-sectional views of the apparatus shown in FIG. 3 as viewed respectively along section lines  4 - 4  and  5 - 5  thereof;  
         [0015]    [0015]FIG. 6 is an enlargement of the apparatus shown in FIG. 1, showing the connection of a motor means  50  to one end of the rotatable hollow shaft  26 ;  
         [0016]    [0016]FIG. 7 is an enlargement of the apparatus shown in FIG. 1, more specifically the other end of the hollow shaft  26  with clarifying detail of features, including the slip rings  60  and  62  and their respective associated wipers  70  and  72 ;  
         [0017]    [0017]FIG. 8 is an isometric view of the fuel cell blade assembly  32 ;  
         [0018]    [0018]FIG. 9 is an isometric cross-section of the assembly  32  as viewed along section lines  9 - 9  of FIG. 8;  
         [0019]    [0019]FIG. 10 is an isometric view of an alternate-shaped fuel cell blade assembly. 
     
    
     DETAILED DESCRIPTION OF THE INVENTION  
       [0020]    [0020]FIGS. 1 and 2 show a rotating fuel cell apparatus AA comprising an elongated hollow housing means  10  having first and second longitudinally-spaced-apart open ends  12  and  14 . An auxiliary housing member  16  is also hollow and has one end  16 ′ dimensioned so as to register with the open end  14  of housing  10 , and a second end  16 ″ of somewhat increased diameter so as to receive a circularly-shaped air filter means  18  having an outer periphery  18 ′ dimensioned so as to snugly fit within the inner surface  17  of housing member  16 .  
         [0021]    A base portion  10 AA is provided for supporting the rotating fuel cell.  
         [0022]    Shaft supporting means are provided within the housing  10 . More specifically, at the left end of the housing as depicted in FIG. 1 are a set of three transversely or radially-extending bearing supports  22 ,  22 ′, and  22 ″ which, as shown in FIG. 2, are equally circumferentially spaced apart around a longitudinally-extending rotary axis LRA within the housing. A similar bearing support  24 ,  24 ′, and a third (not shown) are provided at the other end of the housing  10 . The bearing supports  22 , etc. and  24 , etc., respectively support bearing means  22 A and  24 A which jointly define the longitudinally-extending rotary axis LRA.  
         [0023]    An electrically conductive elongated shaft  26  having first and second ends  26 ′ and  26 ″ are rotatably supported by the inner races of the bearing means  22 A and  24 A. The  5  elongated outer surface of the shaft is identified by reference numeral  26 OS. Shaft  26  has a centrally positioned bore  26 B extending longitudinally from end  26 ″ a preselected length along the shaft  26  but does not extend the full length, as is clearly shown in FIG. 1. The shaft  26  further has a plurality of longitudinally-spaced-apart, radially-extending ports  26 P connecting the hollow bore  26 B to the outer surface  26 OS.  
         [0024]    Electrical insulative means  30  are layered on said outer surface  26 OS of shaft  26  and includes openings  30 P therein which are in register with the radially-extending ports  26 P of the shaft. A plurality of PEM fuel cell blade assemblies  32  are mounted on and secured to the shaft so as to rotate therewith. A representative fuel cell blade assembly is shown in FIGS. 3, 4,  5 ,  8 , and  9 . FIG. 1 depicts a stack of five (5) separate PEM fuel cell blade assemblies arranged on the shaft  26  in axially spaced-apart relationship; they are identified from left to right as shown in FIG. 1 by reference numerals  32 ′,  32 ″,  32 ′″,  32   iv , and  32   v . The fuel cell blade assemblies are spaced apart by electrically conductive tubular spacers  34  as shown in FIG. 1.  
         [0025]    Referring to FIGS.  3 - 5 ,  8 , and  9 , a typical PEM fuel cell blade assembly comprises an anodic metallic frame  36  having a preselected shaped periphery P. longitudinal thickness t (see FIG. 4), and opposed axial faces  32 AA and  32 BB. The top or outer end (as measured from the LRA) of anodic frame  36  is identified by reference  36 T, and the bottom portion of  36  which is concentric with the LRA is identified by reference  36 B. In addition, each PEM fuel cell blade assembly comprises a pair of PEMs, i.e., PEM′ and PEM″ having peripheries shaped to be substantially identical to the periphery P of the anodic frame and further are respectively abutted against and attached to the opposed faces  32 AA and  32 BB of the anodic frame so as to define therebetween a radially-extending gap G, shown in FIG. 4. The blade assemblies further comprise an electrically conductive sealing rim R which connects said pair of PEMs at their peripheries. Sealing rims R are not in electrical contact with the anodic frame  36 . Further, a hydrogen gas passageway  36 P extends between the gap G and an inner bore  36 B of the anodic frame  36 . The diameter of the bore  36 B is identified by reference D′ and it is preselected so that it will snugly embrace the outer periphery of the insulative means  30  surrounding shaft  26 . PEM′ has a bore therein in register with and the same diameter as bore  36 B. PEM″ has a larger bore diameter D″ in register with bore  36 , the diameter D″ being preselected so as to snugly fit the outer diameter of conductive spacers  34 .  
         [0026]    Each PEM comprises an anode A, a cathode C, with an electrolyte E positioned therebetween (see FIGS. 4 and 9).  
         [0027]    Means are provided for supplying hydrogen gas from a suitable source to the hollow bore  26 B of shaft  26  and thence through ports  26 P,  30 P, and  32 P to flow into engagement with the anodes A of the PEMs. The means for supplying the hydrogen gas, as depicted in FIG. 1 as a representative but not limiting arrangement, is a rotary coupling means  40  which is stationary and has an inner bore  40 B sized so as to receive the extreme left end  26 ′ of shaft  26 , this being a rotary connection. Coupling  40  further includes a passageway  42  and appropriate nipple or the like for a tubular coupling  44  for a piping means  44 H connected to a source of Hydrogen (H 2 ). A valve  44 V may be provided for regulating and/or controlling the flow of hydrogen through the coupling  40  to the bore  26 B of the shaft  26 . The valve  44 V is optional; in some cases it may be manually controlled or automatically controlled by apparatus  44 C. Another or alternate arrangement for providing hydrogen is to have bore  26 B extend throughout the entire shaft  26  (in a closed-loop configuration) to provide a circulatory path for the hydrogen, and thus the proper H 2  concentration throughout.  
         [0028]    Referring to FIG. 6, the right end of shaft  26  as shown in FIG. 1 has a threaded portion  26 T axially adjacent to the end  26 ″ which fits within the inner race of bearing means  24 ′. An electrically conductive tubular spacer  34 ′ abuts against face  32 AA of the anodic frame  36  of PEM  32   v . An electrically conductive washer  26 W has an axial face abutting the outboard axial end of spacer  34 ′; a jam nut  26 N threaded on the threads  26 T of the shaft is rotated to maintain the washer  26 W in tight good electrical contact with the spacer  34 ′. At the other end of the stacked PEM fuel cell blade assemblies, the shaft  26  has a radially-extending flange or shoulder  26 S (see FIGS. 1 and 7) inboard of the bearing support  22 . A pair of slip rings  60  and  62  are mounted on the insulative sleeve  30 . Slip ring  60  is in abutment and electrical contact with shoulder  26 S of the shaft. The slip rings are separated from one another by an insulative washer  64 . Slip ring  62  has its inboard axial face in electrical contact with the cathode C of PEM′ of assembly  32 ′.  
         [0029]    The jam nut  26 N is effective to provide axial pressure along the shaft so as to keep all of the assemblies and the slip rings under sufficient axial pressure so that they will rotate with the shaft  26  when it is rotated, as will be discussed below.  
         [0030]    Slip ring wiper means  70  and  72  are mounted on the housing as by suitable means  10 BB and respectively engage the slip rings  60  and  62 . Slip ring wiper means  70  and  72  are respectively connected by output leads  70 A and  72 A for supplying a load, not shown, and, usually, also supplying power to the electric motor means  50  which functions to rotate the shaft  26 . As shown in FIGS. 1 and 6, the motor means  50  comprises a housing  52  which is connected by suitable means  54  to the bearing support means  24 . The housing  52  is depicted as being somewhat cup-shaped to provide on the inner periphery thereof a support for a stator  50 ST having appropriate windings  50 W, the stator co-acting with a rotor member  50 R attached or connected to the shaft  26  by a stub-shaft  50 S. The motor stator windings  50 W are connected to a suitable power supply which, when current is applied to the winding  50 W, functions to cause the rotor  50 R to rotate the shaft  26  relative to the housing  10 . In a preferred embodiment, the winding  50 W is connected to the leads  70 A and  72 A, i.e., the power output from the fuel cell. Thus, the fuel cell not only generates power for an external load, but also provides the small requisite power for operating the motor means  50 .  
         [0031]    An adjustable shutter means  20  is provided adjacent the outboard surface of the air filter means  18 ; an adjustable means  20 A is shown linked or connected to the shutters  20  so as to regulate the amount of air which is permitted to flow through the filter  18  and thence across and around the individual fuel cell blade assemblies. The air flow control means provides a means for controlling the temperature of the stack of fuel cell blade assemblies.  
         [0032]    A port or bore  22 AA is provided at the bottom of bearing support as shown in FIG. 1, i.e., adjacent to the juncture of the bearing support with the housing or shroud  10 ; the function of the port  22 AA is to permit water centrifugally thrown off from the fuel cell blade assemblies to be removed from within the housing. The water is represented in FIG. 1 by droplets H 2   0  flowing away from the housing.  
       OPERATION  
       [0033]    The PEM fuel cell blade assemblies  32 ′- 32 V′ are assembled as a stack as indicated above on the assembled shaft  26  and insulative sleeve  30 , the conductive sleeve spacers  34  providing electrical connections between adjacent PEM blade assemblies so that they are connected “in series”. Each of the conductive sleeves  34  and  34 ′ abuts at the left axial end thereof as shown in FIGS. 1, 6, and  7 , against the axial face  32 AA of anodic frame  36  of the assembly immediately to the left thereof.  
         [0034]    The functioning of the apparatus is simple and very effective. Hydrogen is supplied to the bore  26 B of shaft  26  whenever it is desired that the cell provides electrical power. The hydrogen flows through the bore  26 B and thence to the individual fuel cell assemblies by way of the aligned ports  26 P,  30 P and  36 P as is clearly shown in FIG. 7. The hydrogen entering the gap G then reacts with the inside structure (anodes) of the PEMs, the outside surfaces (cathodes) of which are exposed to air (oxidant) which enters the housing through the filter means  18 , with the air flowing against and around the individual blades of the fuel cell assemblies. Thus there is direct cathode exposure to the ambient air. Further, since the motor  50  is rotating the entire stack, there is a fan effect created by the blade rotation to increase the flow of air across the stack. The airflow is extremely important so as to remove heat from the unit to avoid excessive temperatures. As indicated, the shutters  20  are adjusted to provide desired temperature of the stack. Auxiliary air can also be introduced between the PEM blades (or disks) by a fan or compressor and a suitable air distribution system interposed therebetween.  
         [0035]    The centrifugal force from the rotating stack also has the advantage of readily ridding the cathodes of the accumulation of water that occurs at its surface as a result of combining hydrogen and oxygen to produce electricity (and heat). Keeping the exposed cathode surfaces free of water (“slinging it away”) improves the performance and efficiency of the fuel cell because the surrounding air (oxygen) is always in contact with the cathode. In other words, the overall efficiency is improved because the liquid water which would otherwise get in the way of the air is removed rapidly through centrifugal action which thereby also maximizes the opportunity of the oxygen in the air coming in contact with the cathode. Thus, the rotating fuel cell blades are constantly in contact with new and turbulent high-O 2 -concentration air. Again, the cathodic surface oxygen concentration will always be maximized. Very importantly, the fuel cell blades can be arranged in a fashion such that the rotating fuel cell assembly causes its own aspiration and does not require an air compressor to supply oxidant. This fan function can be controlled by the design of the shape of the blade. The blades shown in FIGS. 1 and 8 are essentially planar, whereas an alternate configuration is shown in FIG. 10 wherein the outer portion of the blade has a twist away from the planar, as can be noted from a comparison thereof with the blade shown in FIG. 8.  
         [0036]    As indicated, the stator windings  50 W of motor  50  are typically connected to the output from the fuel cell so that the unit is self-contained, i.e., does not require external electrical power for start-up. In a typical operation, as soon as the hydrogen is admitted to the bore  26 B, then the unit will begin to function and generate electrical outputs at leads  70 A and  72 A; concurrently, this output voltage will be applied to the motor  50  to bring the motor up to a desired speed of rotation.  
         [0037]    Those skilled in the art will understand that the shape of the periphery P of the blades  32  may vary greatly within the scope of this invention. For example, a full diameter disk “blade” would resemble a phonograph record.  
         [0038]    While the preferred embodiment of the invention has been illustrated, it will be understood that variations may be made by those skilled in the art without departing from the inventive concept. Accordingly, the invention is to be limited only by the scope of the following claims.