CELL VOLTAGE MONITORING CONNECTOR SYSTEM FOR A FUEL CELL STACK
The present invention relates to electrical connector systems used in fuel cell stacks to
make electrical connections to a plurality of individual cells within a fuel cell stack.
Conventional electrochemical fuel cells convert fuel and oxidant into electrical and
thermal energy and a reaction product. A typical fuel cell comprises a membrane electrode
assembly (MEA) sandwiched between an anode flow field plate and a cathode
flow field plate. Gas diffusion layers may be disposed between each flow field plate and
the MEA. Gaskets may be used to separate various layers and to provide requisite
seals. The flow field plates typically include one or more channels extending over the
surface of the plate adjacent to the MEA for delivery of fluid fuel or oxidant to the active
surface of the MEA.
In a conventional fuel cell stack, a plurality of cells are stacked together, so that the
anode flow field plate of one cell is adjacent to the cathode flow field plate of the next cell
in the stack, and so on. In some arrangements, bipolar flow plates are used so that a
single flow field plate has fluid flow channels in both sides of the plate. One side of the
bipolar plate serves as an anode flow plate for a first cell and the other side of the flow
plate serves as a cathode flow plate for the adjacent cell. Power can be extracted from
the stack by electrical connections made to the first and last flow plate in the stack. A
typical stack may comprise many tens or even hundreds of cells. The present invention
is relevant to all of these various fuel cell stack constructions.
In many fuel cell stacks, it is important to be able monitor the voltage of individual cells in
the stack. Thus, it is necessary to provide electrical connection to many (and often to all)
of the flow plates in the stack. Conventionally, this has been achieved by providing
electrical connector tabs to at least some of the flow plates in the stack. These cell
voltage monitoring tabs extend from edges of the flow plates, laterally outward from the
stack thereby forming an array of tabs along an edge face of the stack, so that individual
electrical connectors may be coupled to each tab. One arrangement of cell voltage
monitoring tabs extending from each flow plate is shown in figure 1.
The fuel cell stack 1 in figure 1 has a plurality of physically parallel cells 2 each of which
has an anode flow plate with a respective tab 3 extending outwards from a face 4 of the
fuel cell stack. To decrease the packing density of the tabs (i.e. to increase the
separation of adjacent tabs) or to provide additional connection points to the same or
different plates in the stack, the tabs 3 may be formed in two (or more) rows 5, 6.
These male tabs 3 can typically be used with standard female electrical connectors, such
as blade receptacles well known in the art. Use of individual blade receptacles for each
tab 3 is practical for manufacture of small stacks and small volumes of cells, but is not
ideal for mass production of cells in view of the high labour content of connecting
individual receptacles.
It would be desirable to use multi-way or multi-pole connectors to simultaneously connect
to a number of tabs. Industry standard connectors have a predetermined pitch, e.g.
based on dimensions of 0.1 inch or 2 mm or divisions / multiples thereof. In connecting
to the tabs of fuel cell stacks, one potential problem is that the spacing (or pitch) of the
fuel cells is determined by the compressed size of the various layered components
discussed above, and this might not match a standard connector pitch. Another problem
can be that standard connectors may have a positional accuracy for each terminal, for
example + 0.2 mm, and this level of precision might not be appropriate to the variation in
tab spacing in many fuel cell designs.
Thus, a multi-way receptacle connector (i.e. a unitary connector that simultaneously
engages with many tabs) can be difficult to implement in a fuel cell stack.
It is an object of the present invention to overcome or mitigate some or all of these
problems.
According to one aspect, the present invention provides a fuel cell stack comprising a
plurality of layers and a plurality of electrically conductive connection tabs extending
outwardly from at least one face of the stack, the electrically conductive connection tabs
each being formed as a laterally extending free portion of a flexible sealing gasket, other
portions of the gasket being disposed to provide sealing engagement between at least
two layers of the fuel cell stack.
Each said gasket may comprise a manifold gasket disposed laterally adjacent to a flow
field plate. Each said gasket may be disposed between a membrane-electrode
assembly of the fuel cell and an electrode plate. Each said gasket may be disposed
between a cathode electrode and an anode electrode. A first portion of each gasket may
be electrically insulating and a second portion of the gasket that is in contact with an
adjacent electrode may be electrically conductive and in electrical contact with the
electrically conductive connection tab. The connection tab may be integrally formed with
the rest of the gasket. The gasket may be formed from a material that imparts electrical
conductivity to the bulk of the gasket material. At least a portion of the gasket including
the connection tab may have an electrically conductive layer formed on at least one
surface thereof. The connection tab may have a resistance in the range 10 ohms to
1000 ohms. Each connection tab may extend outwardly from a side face of the fuel cell
stack so as to form at least one row of connection tabs along the side face. The fuel cell
stack may include a tab guide comprising a plurality of channels, each channel having
received therein a respective one of the connection tabs, the channels being configured
to fan the connection tabs from a first spacing at a proximal end of the connection tabs
to a second spacing at a distal end of the connection tabs. The fuel cell stack may
include an electrical connector assembly coupled to the connection tabs in the tab guide,
at their distal ends. The fuel cell stack may include an electrical connector assembly
coupled to the row of connection tabs. Selected ones of the connection tabs may have a
different electrical resistance to other ones of said connection tabs.
Embodiments of the invention will now be described by way of example and with
reference to the accompanying drawings in which:
Figure 1 is a perspective view of a fuel cell stack with a side face having an array
of cell voltage monitoring electrical connection tabs extending out of the side face from
each cell;
Figure 2 is a perspective exploded view of components of a fuel cell showing
schematically the disposition of flow plates, gaskets and membrane electrode assembly;
Figure 3 is a perspective exploded view of components of a fuel cell showing
schematically the disposition of flow plates, gaskets and membrane electrode assembly
incorporating a manifold gasket with a connection tab extending laterally outward
therefrom;
Figure 4 is a perspective exploded view of components of a fuel cell showing
schematically the disposition of flow plates, gaskets and membrane electrode assembly
incorporating an anode gasket with a connection tab extending laterally outward
therefrom;
Figure 5 is a schematic plan view of a portion of an anode gasket having a
connection tab extending laterally outward therefrom;
Figure 6 is a schematic plan view of a portion of an anode gasket having an
alternative configuration of connection tab extending laterally outward therefrom;
Figure 7 is a schematic end view of an electrical connector assembly suitable for
coupling to the gasket connection tabs;
Figure 8 is a plan view of a tab guide suitable for receiving the gasket connection
tabs to modify the pitch thereof; and
Figure 9 is a perspective view of an electrical connection assembly for coupling
the gasket connection tabs to a ribbon cable connector.
Figure 2 shows a schematic diagram of components of a fuel cell for an open cathode
type fuel cell stack in exploded form for clarity. Each cell 20 includes an anode flow plate
21, an anode gasket 23, a membrane-electrode assembly (MEA) 24, a cathode gasket
25 and a cathode flow plate 27. The anode gasket 23 provides a fluid tight seal between
the anode flow plate 2 1 and the MEA 24 and defines a frame around an anode diffuser
22. Similarly, the cathode gasket 25 provides a fluid tight seal between the cathode flow
plate 27 and the MEA 24 and defines a frame around a cathode diffuser 26. In the
particular arrangement of figure 2, the cathode flow plate is provided as a corrugated
cathode separator plate 27 and a pair of manifold gaskets 28a, 28b are provided at each
end thereof.
In other arrangements, the fuel cell could be a closed cathode system, for example in
which the cathode flow plate could be a flat plate with channels extending in a surface
thereof. In other arrangements, the cathode flow plate of one cell could be combined
with the anode flow plate of an adjacent cell as a bipolar plate.
In the design of fuel cell shown in figure 2, the anode flow plate 2 1 includes exemplary
electrical connection tabs 15 (e.g. cell voltage monitoring tabs) each extending laterally
outward from an edge of the flow plate 2 1. These tabs would have a rigidity and spacing
determined by the structure and position of the anode flow plate. The potential
disadvantages of such tabs have been discussed above.
In the present invention, it has been recognised that the gaskets used in fuel cells such
as that described in connection with figure 2 can be modified to provide tab electrical
connectors on the gaskets instead of the tabs currently provided on the anode, cathode
or bipolar electrode plates exemplified by tabs provided on the anode flow plate 2 1 in
figure 2.
Figure 3 shows a schematic diagram of components of a fuel cell 32 similar to that of
figure 2, but with a modified manifold gasket 30 including an electrical connection tab 35
(e.g. a cell voltage monitoring tab) formed on or formed as an integral part of the
manifold gasket 30. The gasket 30 comprises an elastomeric or other compressible and
flexible material suitable for providing a fluid tight seal against the cathode separator
plate 27 and against an adjacent cathode gasket 25 and against an adjacent anode plate
from the next cell (not shown in figure 3). The gasket 30 should be sufficiently
compressible so as to absorb any minor variations in thickness of the adjacent
components and to absorb any distortion in the fuel cell stack assembly while
maintaining an adequate fluid seal against adjacent components. The gasket 30 may
also define apertures (not shown) for allowing fluid flow in galleries extending through the
depth of the stack.
The gasket 30 and electrical connection tab 35 are formed from an electrically
conductive material and the connection tab 35 extends laterally outward beyond the
main, generally rectangular, perimeter of the fuel cell such that it will extend outwardly
from a face of the fuel cell stack when multiple cells are constructed into a stack. Thus,
the length L of the connection tab 35 is sufficiently long that it extends beyond the
perimeter of an adjacent anode flow plate 2 1 (and beyond the perimeter of the MEA 24
and any other flow plates and gasket arrangements).
In a general aspect, the gasket 30 includes an electrically conductive connection tab 35
that extends laterally outward beyond the perimeter of the fuel cell 32 such that when the
cell is incorporated into a fuel cell stack, the connection tab provides a laterally extending
free portion of a flexible sealing gasket. Other portions of the gasket are disposed to
provide sealing engagement between layers of the fuel cell stack. The portion of the
connection tab 35 immediately adjacent to the main body of the gasket 30 will be
referred to hereinafter as the "proximal end" and the portion of the connection tab
furthest from the main body of the gasket will be referred to hereinafter as the "distal
end". The expression "tab" or "free portion" of the gasket is intended to encompass any
form of projection from the general line of the gasket perimeter edge suitable for
projection from the face of a fuel cell stack into which the gasket is incorporated such
that it can be received into a connector assembly.
The connection tab 35 is preferably fabricated together with the other features of the
gasket by stamping out the required gasket shape from a sheet of suitable material. In
other words, the connection tab 35 is preferably integrally formed with the gasket. Thus,
in this case, the tab thickness will be equal to the thickness of the gasket sheet. The
connection tab width W can be made to any suitable width as required for connection
purposes or conductivity purposes as discussed hereinafter.
In the example shown, the entire gasket 30 and tab 35 can be formed from electrically
conductive material. This is because the adjacent components (cathode separator plate
27 and anode flow plate 2 1 of the adjacent cell) have electrical continuity and the other
adjacent component (cathode gasket 25) can be electrically insulating. Thus, there is no
problem with the gasket 30 being entirely electrically conducting. The tab 35 therefore
has electrical continuity with the necessary electrically conductive parts of the fuel cell.
The gasket 30, and in particular the connection tab part 35 of the gasket 30 must be
sufficiently electrically conducting for the tab to be able to function as a cell voltage
monitoring tab.
Thus, the entire gasket 30 can be formed from an electrically conductive compressible
material such as an elastomer that has been treated with an electrically conductive
material. The electrically conductive material could be distributed throughout the gasket
material such that the gasket is electrically conductive throughout its bulk. The
electrically conductive material could be disposed as a film or surface layer on the gasket
such that only one or both surfaces of the gasket material are electrically conductive. In
principle, it would only be necessary for the surface facing the anode flow plate 2 of the
adjacent cell, or the surface contacting the separator plate 27 to be electrically
conductive.
A connection tab as described above may be provided on different gaskets than the
example shown in figure 3. Figure 4 shows a modified anode gasket 43 in which a cell
voltage monitoring tab 45 is formed on the anode gasket 43. The anode gasket 43
comprises an elastomeric or other compressible and flexible material suitable for
providing a fluid tight seal against the anode flow plate 2 1 and against the adjacent MEA
23. As shown in more detail in figure 5, the tabbed anode gasket 43 defines a frame 40
around a central aperture 4 1 into which may be received the anode diffuser 22. The
gasket 43 should be sufficiently compressible so as to absorb any minor variations in
thickness of the adjacent components and to absorb any distortion in the fuel cell stack
assembly while maintaining an adequate fluid seal to contain anode fuel. The gasket 43
may also define apertures (not shown) for allowing fluid flow in galleries extending
through the depth of the stack.
The gasket 43 and electrical connection tab 45 are formed from electrically conductive
material and the connection tab 45 extends laterally outward beyond the main, generally
rectangular, perimeter of the gasket 43. The length L of the connection tab 35 is
sufficiently long that it extends beyond the perimeter of the adjacent anode flow plate 2 1
(and beyond the perimeter of the EA 24). It will be understood, therefore, that if the
gasket 43 has an outer perimeter that is coterminous with the anode flow plate 2 1 (at
least along the gasket edge 42 as shown), then the length L of the connection tab need
only be long enough to form an electrical connection thereto, using any one of various
techniques that are exemplified hereinafter. If the gasket 43 area is somewhat smaller
than the anode flow plate 2 1 (i.e. so that the edge 42 of the gasket is somewhat
recessive compared to the flow plate 21), then the length L must be sufficient to extend
out of the face of the fuel cell stack of which the cells 20 form a part.
In a general aspect, the gasket 43 includes an electrically conductive connection tab 45
that extends laterally outward beyond the perimeter of the anode plate 2 1 such that when
the cell is incorporated into a fuel cell stack, the connection tab provides a laterally
extending free portion of a flexible sealing gasket. Other portions of the gasket are
disposed to provide sealing engagement between other layers of the fuel cell stack.
Other aspects of the tab may be exactly as described in connection with figure 3.
The connection tab 45 is preferably fabricated together with the other features of the
gasket (e.g. central aperture 41) by stamping out the required gasket shape from a sheet
of suitable material. In other words, the connection tab 45 is preferably integrally formed
with the gasket. Thus, in this case, the tab thickness will be equal to the thickness of the
gasket sheet. The connection tab width W can be made to any suitable width as
required for connection purposes or conductivity purposes as discussed hereinafter.
Other configurations of connection tab can be used, such as a right angle bend tab 46 as
shown in the gasket 44 of figure 6 . Other features of the gasket 44 correspond to those
already described in connection with figure 5 or figure 3.
The connection tabs 35, 45, 46 could alternatively be attached to a pre-formed gasket.
As discussed earlier, connection tabs 35, 45, 46 of the gaskets 30, 43, 44 must include
sufficiently electrically conductive material to be able to function as a cell voltage
monitoring tab. The tab must also have electrical continuity with at least a portion of the
gasket that comes into contact with the electrically conductive parts of the fuel cell, so as
to provide an electrical current path from the cell. In the examples of figures 4 to 6, this
electrically conductive part of the fuel cell could be the anode plate 21.
The entire gasket could be formed from the electrically conductive compressible material
distributed throughout the gasket material or the electrically conductive material could be
disposed as a film or surface layer on, for example, the lower surface of the gasket that
lies adjacent to the anode plate 21. In principle, it would only be necessary for a surface
contacting an anode flow plate 21, or cathode flow plate, or bipolar flow plate to be
electrically conductive, as well as at least a surface of the tab.
If an entire gasket is formed from electrically conductive material, then care must be
taken to prevent conduction of electricity either around a flow plate or around the MEA. If
a gasket is formed from electrically insulating material, then the risk of an unwanted
current path can be minimised. If only one face of the gasket material (e.g. that which is
facing an appropriate flow plate) is electrically conductive, then the risk of an unwanted
current paths can also be minimised.
In another arrangement, it might generally be desirable to reduce or minimise areas of
the gasket 35, 43, 44 that are electrically conductive. In this example, generally depicted
on the gasket 44 of figure 6, the gasket may be divided into a first portion 47 and a
second portion 48. The first portion 47 may be electrically insulating and the second
portion 48 may be electrically conductive. The second portion is in electrical
communication with the connection tab 46. In this way, the second portion 48 can
provide an electrical connection to, for example, the anode flow plate 2 1 and an
electrically conductive path to the connection tab 46. The second portion 48 can be
formed by treating the gasket material with a suitable electrically conductive material to
locally define a conductive portion, either in the bulk of the gasket or only on one or both
surfaces.
Although the first and second portions 47, 48 have been shown in connection with the
embodiment of figure 6, it will be understood that the first and second portions can
generally be applicable to the other forms of gasket described, e.g. in connection with
that shown in figures 3 , 4 and 5.
The connection tabs 35, 45, 46 and conductive portions of the gasket are preferably
highly conductive so as to provide minimal losses and measurement errors when
sampling the voltage at the end of the tab 35, 45, 46. However, because the connection
tabs are flexible, there may be an increased risk of two gasket connection tabs becoming
shorted together during operation of the cell, for example if an electrical connection
assembly coupled to the connection tabs 35, 45, 46 is removed from the cell stack whilst
it is operating. Such an electrical short could cause current to flow that might damage a
cell. Thus, in an alternative arrangement, the resistivity of the gasket material forming
the second portion 48 and/or the connection tab 35, 45, 46 may be arranged to result in
a connection tab having a resistance that prevents or inhibits cell damage in the event of
a short circuit between tabs. A preferred range of connection tab resistance is between
10 to 1000 ohms.
Too high a resistance can result in measurement inaccuracies. Thus, an upper
resistance value is preferably chosen so that cell voltage measurement is acceptably
accurate, while a lower resistance value is chosen to prevent cell damage in the event of
a short circuit. Exact values depend on the circuitry that is used to monitor the cell
voltage.
Not all connection tabs in a stack need have the same resistance. It may be desirable to
make some connection tabs with lower resistance for low measurement error, and other
intervening connection tabs with higher resistance for short circuit protection. Lower
resistance tabs could be formed by providing a metallic coating to the surface of the
gasket 30, 43, 44 at the appropriate places. Some circuits draw low level power from the
stack at selected cells, and these particular connection tabs may benefit from being of
lower resistance. Any number of connection tabs could be provided, e.g. one or more
per cell, or only every n cells, where n is an integer greater than 1.
The connection tabs 35, 45, 46 could be formed in multiple locations on one or more
edges of the fuel cell stack. The fuel cell stack could be constructed using gaskets of two
types to form two or more rows of connection tabs 35, 45, 46 on a face of the stack,
similar to the pattern shown for anode flow plate tabs in figure 1 . The connection tabs of
each row could be spaced every other cell, thus being configured with a spacing that is
larger than the spacing between adjacent cells, the two rows being offset by one cell so
as to facilitate a connection to every cell.
With reference to figures 7, 8 and 9, we now describe various examples of electrical
connector assemblies suitable for coupling to the gasket connection tabs. A desirable
objective is to conform (i.e. flex) the connection tabs to a predetermined regular spacing,
so as to allow their connection to a standard sized connector.
In a first arrangement, each connection tab is connected in to a respective element in a
connector assembly of fixed pitch. This can be achieved as shown in figure 7a by
sequentially capturing each successive connection tab into a respective element 52 of a
serial clip. Each clip element 52 is located into a dovetail channel 53 to form a clip
assembly 50. Alternatively, it can be achieved as shown in figure 7b by sequentially
capturing each successive connection tab into a respective hermaphroditic clip element
55 which engage with each other in a stack to form a clip assembly 51. The flexibility of
the gasket connection tabs means that any difference in pitch of, or spacing between, the
gaskets 30, 43, 44 and the clip elements 52 or 55 can be absorbed by the flexibility of the
gasket connection tabs, at least over a significant number of cells, e.g. 12 cells, for a
single connector assembly.
In an alternative arrangement shown in figure 8, a tab guide 60 is used to adjust the pitch
of, or spacing between, the gasket connection tabs from a first spacing at the proximal
ends where they emerge from the stack face 4 to a second spacing at the distal ends.
As seen in figure 8, the tab guide 60 comprises a set of channels 6 1 extending from a
first edge 62 to a second edge 63. The pitch and spacing of the channels 6 1 changes
from the first edge 62 to the second edge 63. Each successive gasket connection tab is
introduced into successive channels 6 1 to guide the tabs from a first pitch to a second
pitch. In one example, the first edge 62 is proximal to the point at which the tabs emerge
from the side face 4 of the fuel cell stack 1 and the second edge 63 is distal to the point
at which the tabs emerge from the side face 4 of the fuel cell stack . In such a case, the
tab guide reduces the pitch of the tabs from a first value to a second value. In one
example, the pitch of the tabs at their proximal ends in first edge 62 corresponds to the
cell pitch of between 2.3 and 2.6 mm and the pitch of the tabs at their distal ends in
second edge 63 corresponds to a standard connector pitch of 2 mm. In a typical
example, 2 connection tabs are accommodated in a connector assembly for monitoring
11 cells, although this number and the dimensions are entirely exemplary. The tab guide
60 can be used to "fan in" (i.e. decrease the tab spacing) or "fan out" (i.e. increase the
tab spacing).
In a preferred arrangement, the tab guide 60 is laid flat along the face 4 of the stack with
the channels 6 1 facing up. The first edge 62 is aligned with the points where the gasket
connection tabs emerge from the stack face 4. Each gasket connection tab is bent
through 90 degrees so that it is parallel to the face 4 of the stack and is laid into a
respective channel 61. The channels 6 1 may be flared at the first edge 62 to make this
easier. With reference to figure 9, a flexible flat cable 7 1 is then used to make contact
with the gasket connection tabs near or at the second edge 63 and a clamp 72 is used to
press the cable 7 1 against the gasket connection tabs. The clamp 72 may be a screw
clamp as shown or any other suitable clamp such as a toggle clamp or cam-based
clamp. A connector assembly 70 is thereby formed.
Many variations to the embodiments described can be made. Gasket connection tabs
could be formed on each and every gasket, including both anode gaskets 23 and
cathode gaskets 25, or manifold gaskets 28a, 28b or could be formed on only selected
ones of the anode and/or cathode and/or manifold gaskets. The connection tabs can
emerge from any suitable edge of the gaskets, and may be formed on multiple edges for
maximum flexibility in forming connections. Unwanted gasket tabs at the time of
assembling a fuel cell stack could be severed from the gasket.
The gasket connection tabs 35, 45, 46 can be made of any suitable width W to provide
adequate conductance along the tab, taking into account the bulk or surface conductivity
of the gasket material and the thickness of the gasket material. The gasket connection
tabs can be used as cell voltage monitoring tabs having a very low current requirement,
or can be used for other purposes in extracting current from one or more cells within a
stack (e.g. providing a low voltage, low current output for a specific circuit). Higher
current requirements could, for example, be provided with a metallic layer deposited or
otherwise formed on the surface of a gasket to form the tab 35, 45, 46 and, if applicable,
the second portion 48.
The flexibility of the gasket connection tabs 35, 45, 46 allows considerable flexibility in
adapting rows or part rows of tabs to any suitable standard connector assembly pitch,
e.g. 1 mm, 2 mm, 0.1 inch, etc.
The gasket connection tabs described can form part of any suitable intra-cell gasket as
exemplified above, or could even form part of any inter-cell gasket, e.g. a gasket residing
between individual cells, such as between the anode flow plate and cathode flow plate of
adjacent cells.
Other embodiments are intentionally within the scope of the accompanying claims.
CLAIMS
1. A fuel cell stack comprising a plurality of layers and a plurality of electrically
conductive connection tabs extending outwardly from at least one face of the stack, the
electrically conductive connection tabs each being formed as a laterally extending free
portion of a flexible sealing gasket, other portions of the gasket being disposed to
provide sealing engagement between at least two layers of the fuel cell stack.
2. The fuel cell stack of claim 1 in which each said gasket comprises a manifold
gasket disposed laterally adjacent to a flow field plate.
3. The fuel cell stack of claim 1 in which each said gasket is disposed between a
membrane-electrode assembly of the fuel cell and an electrode plate.
4. The fuel cell stack of claim 1 in which each gasket is disposed between a
cathode electrode and an anode electrode.
5. The fuel cell stack of claim 1 in which a first portion of each gasket is electrically
insulating and a second portion of the gasket that is in contact with an adjacent electrode
is electrically conductive and in electrical contact with the electrically conductive
connection tab.
6. The fuel cell stack of claim 1 in which the connection tab is integrally formed with
the rest of the gasket.
7. The fuel cell stack of claim 1 in which the gasket is formed from a material that
imparts electrical conductivity to the bulk of the gasket material.
8 . The fuel cell stack of claim 1 in which at least a portion of the gasket including the
connection tab has an electrically conductive layer formed on at least one surface
thereof.
9 . The fuel cell stack of claim 1 in which the connection tab has a resistance in the
range 10 ohms to 1000 ohms.
The fuel cell stack of claim 1 in which each connection tab extends outwardly
from a side face of the fuel cell stack so as to form at least one row of connection tabs
along the side face.
11. The fuel cell stack of claim 10 further including a tab guide comprising a plurality
of channels, each channel having received therein a respective one of the connection
tabs, the channels being configured to fan the connection tabs from a first spacing at a
proximal end of the connection tabs to a second spacing at a distal end of the
connection tabs.
12. The fuel cell stack of claim further including an electrical connector assembly
coupled to the connection tabs in the tab guide, at their distal ends.
13. The fuel cell stack of claim 10 further including an electrical connector assembly
coupled to the row of connection tabs.
14. The fuel cell stack of claim 10 in which selected ones of said connection tabs
have a different electrical resistance to other ones of said connection tabs.
15. A fuel cell substantially as described herein with reference to the accompanying
drawings.