Patent Grant
7521145
The present invention relates generally to fuel cells for use in a portable electronic device and, more particularly, to the method for fabricating such fuel cells.
A fuel cell works like a battery but does not run down or need recharging so long as the fuel is continually fed to the cell. In a direct methanol fuel cell (DMFC), methanol is used as a fuel, which is put in on one side of the fuel cell while air circulates on the other side. The two sides are separated by a membrane electrode assembly (MEA), which has a proton exchange membrane (PEM) sandwiched between two electrodes. As shown in
A major advantage of fuel cells over rechargeable batteries is that fuel cells can generally operate for longer periods of time without recharging. Furthermore, “recharging” a fuel cell can be accomplished almost instantaneously by refueling with liquid methanol. In contrast, recharging a battery takes hours to complete.
Currently, a DMFC is made of a single MEA, wherein a single PEM is used. The MEA and the PEM are usually designed to suit the dimensions of the portable device. If the PEM in a fuel cell is defective, rendering the fuel cell non-functioning, the MEA or the entire PEM must be replaced. It is thus advantageous and desirable to provide a fuel cell wherein the MEA can be repaired without discarding the entire PEM in order to reduce the associated cost.
It is a primary objective of the present invention to reduce the cost in fabricating and repairing a fuel cell for use in a portable device, such as a laptop PC, notebook PC or tablet PC. This objective can be achieved by disposing a plurality of PEM segments such that only the defective segments will be replaced in a non-functioning direct methanol fuel cell.
Thus, according to the first aspect of the present invention, there is provided a method of fabricating a fuel activation assembly for use in a fuel cell, the fuel cell comprising a first cell compartment for containing a first fuel component and a second cell compartment for containing a second fuel component, wherein the fuel activation assembly is disposed between the first cell compartment and the second cell compartment so as to activate the first fuel component for producing protons in the first cell compartment and for channeling the protons to the second cell compartment. The method comprises the steps of:
providing a substrate having a plurality of apertures; and
securely attaching a plurality of membrane electrode assembly segments to the substrate over the apertures, wherein each membrane electrode assembly segment has a first side and an opposing second side, the second side adjacent to the second cell compartment, the first side adjacent to the first cell compartment for activating the first fuel component in order to produce the protons and for channeling at least part of the protons from the first cell compartment to the second cell compartment via the apertures through the membrane electrode assembly segments.
The attachment of the membrane electrode assembly segments to the substrate can be achieved by a heat bonding process or by applying an adhesive layer, creating a barrier separating the first side from the second side of each membrane electrode segment, thereby preventing the first fuel component from entering the second cell compartment and the second fuel component from entering the first cell compartment. The adhesive is resistant to the fuel components.
According to the second aspect of the present invention, there is provided a fuel cell, which comprises:
a first cell compartment for containing a first fuel component;
a second cell compartment for containing a second fuel component; and
a fuel activation assembly disposed between the first cell compartment and the second cell compartment, the fuel activation assembly comprising:
The activation process produces an electrical current, and the fuel cell further comprises:
a first electrically conducting terminal operatively connected to the first cell compartment; and
a second electrically conducting terminal operatively connected to the second cell compartment, so as to allow a current load to connect to the first and second electrically conducting terminals to use the electrical current.
The first fuel component comprises substantially a mixture of water and alcohol, and the substrate is resistant to water and alcohol. The alcohol comprises substantially methanol. The second fuel component comprises substantially air.
Each membrane electrode assembly segment comprises a proton exchange membrane disposed between two electrode layers.
Each membrane electrode assembly segment further comprises two diffusion layers, each covering one of the electrode layers.
According to the third aspect of the present invention, there is provided a membrane electrode assembly for use in a fuel cell. The fuel cell comprises:
a first cell compartment containing a first fuel component; and
a second cell compartment containing a second fuel component, said membrane electrode assembly comprising:
a substrate having a plurality of apertures; and
a plurality of fuel activation segments securely attached to the substrate over the apertures, wherein each fuel activation segment has a first side and an opposing second side, the second side adjacent the second cell compartment, the first side adjacent the first cell compartment, for activating the first fuel component in order to produce protons in an activation process, and for channeling at least part of the protons from the first cell compartment to the second cell compartment via the apertures through the membrane electrode assembly segments.
Advantageously, each fuel activation segment comprises:
a first electrode layer on the first side;
a second electrode layer on the second side; and
a proton exchange membrane disposed between the first and second electrode layers.
The first electrode layer and the second electrode layer of each fuel activation segment are operatively connected to the first electrode layer and the second electrode layer, respectively, of other fuel active segments such that the fuel activation segments are electrically connected in parallel.
Advantageously, at least some of the fuel activation segments are electrically connected in series, such that the first electrode layer and the second electrode layer of each of said at least some of the fuel activation segments are operatively connected to different ones of the first and second electrode layers of different fuel activation segments. Alternatively, the fuel activation segments are electrically connected in a combination of a series connection and a parallel connection.
According to the fourth aspect of the present invention, there is provided a portable electronic device comprising:
an electronic unit for processing signals or data; and
a fuel cell for providing electricity to the electronic unit, the fuel cell comprising:
The portable electronic device can be a notebook computer, a laptop computer, a tablet computer, a personal digital assistant device, or the like.
The present invention will become apparent upon reading the description taken in conjunction with
a is a schematic representation illustrating an embodiment of the fuel cell stack in a fuel cell, according to the present invention.
b is an exploded view of the fuel cell stack of
a is a schematic representation illustrating the attachment of an MEA segment to the substrate, according to the present invention.
b is a schematic representation illustrating a different way to attach an MEA segment to the substrate.
c is a schematic representation illustrating yet another way to attach a MEA segment to the substrate.
a is a schematic representation illustrating a different method for collecting electrical current from the MEA segments.
b is a schematic representation illustrating yet another way to collect electrical current from the MEA segments.
a is a schematic representation illustrating a two-cell MEA segment.
b is a schematic representation illustrating a four-cell MEA segment.
c is a schematic representation illustrating a six-cell MEA segment.
The fuel cell, according to the present invention, comprises a plurality of MEA (membrane electrode assembly) segments, each of which has a separate PEM (proton-exchange membrane) and two electrode/diffusion layers for catalytic activation. As shown in
The MEA segment 110, as shown in
Preferably, each of the openings 142 on the substrate 140 has a step-like recess 144 around its edges so as to allow an MEA segment 110 to be attached therein, as shown in
Alternatively, two substrates 140 can be used to secure the MEA segments 110 with an appropriate bonding material 126, as shown in
In a fuel cell 200, the fuel cell stack 100 can be sandwiched between two current collectors 150, 160 as shown in
Alternatively, the MEA segments 110 can also be electrically connected in series, as shown in
In a different embodiment of the present invention, each of the activation layers 112 and 114 is extended beyond the PEM 120 so that it can be electrically connected to a feed-through 176, as shown in
It is understood that the electrical connection among the MEA segments 110 in a fuel cell stack 100 can also be a combination of series connection and parallel connection. The combination can be tailored to suit the voltage and power requirements of a portable electronic device.
a, 2b, 4a to 6b illustrate a fuel cell stack 100 in a fuel cell 200. The fuel cell stack 100 comprises a plurality of MEA segments 110, as shown in
Furthermore, when a fuel cell is fabricated to suit the size or the power consumption of a portable electronic device, it is possible to use a different number of MEA segments to fit the size of the fuel cell 200. For example, it is possible to fabricate one fuel cell with 4×6 MEA segments and to fabricate another fuel cell with 5×7 MEA segments of the same size. In contrast, with the prior art fuel cells, one must have PEMs of different sizes to suit the size of different portable electronic devices.
It should be noted that each MEA segment can be made of two or more pairs of activation layers attached to a PEM 120 on opposite sides thereof. As shown in
It should be noted that the individual “cell” in a single or multiple-cell MEA segment can be square, or rectangular with a certain aspect ratio to suit a variety of fuel cell sizes. For example, the aspect ratio for the individual cell can be 4:3 or 5:4.
In addition, the size of MEA segments for a fuel-cell stack need not be the same. As seen in
In sum, the membrane electrode assembly in a fuel cell can be made of a plurality of segments, each having a separate proton exchange membrane. As such, it is possible to replace a defective segment, instead of discarding the entire membrane electrode assembly, if the fuel cell becomes defective. With membrane electrode assembly segments, fuel cells of various sizes can be made without using proton exchange membranes of different sizes. In a fuel cell having a plurality of membrane electrode assembly segments, it is possible to electrically connect the segments in series, in parallel or in a combination thereof.
Although the invention has been described with respect to a preferred embodiment thereof, it will be understood by those skilled in the art that the foregoing and various other changes, omissions and deviations in the form and detail thereof may be made without departing from the scope of this invention.
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