Fuel cell gas inlet manifold drain

We claim: 1. A fuel cell, comprising: a cell stack assembly including a plurality of cells that are configured to facilitate an electrochemical reaction; a gas inlet manifold positioned on one side of the cell stack assembly and outside the plurality of cells, the gas inlet manifold being configured to introduce a gas to each of the plurality of cells of the cell stack assembly, the gas inlet manifold having an upper end and a lower end, the gas inlet manifold arranged vertically so that the gas inlet manifold has a longest dimension and an overall length that extend from the upper end to the lower end; a gas outlet manifold positioned on another side of the cell stack assembly and outside the plurality of cells, the gas outlet manifold being configured to direct gas away from each of the plurality of cells of the cell stack assembly, the gas outlet manifold arranged vertically and parallel to the gas inlet manifold; a drain channel coupled to the lower end of the gas inlet manifold, the drain channel connecting the gas inlet manifold to the gas outlet manifold, the drain channel being configured to carry liquid from the gas inlet manifold to the gas outlet manifold; and a wet seal associated with the drain channel to restrict gas flow from the gas inlet manifold into the drain channel, wherein the wet seal is positioned at an interface between the gas inlet manifold and the drain channel. 2. The fuel cell of claim 1 , wherein the drain channel comprises a tube. 3. The fuel cell of claim 1 , wherein the wet seal comprises a porous member that allows liquid to pass through the porous member and limits gas flow through the porous member. 4. The fuel cell of claim 1 , wherein the liquid can flow at least partially through the drain channel under the force of gravity. 5. The fuel cell of claim 1 wherein the liquid can flow an entire way through the drain channel and into the gas outlet manifold under the force of gravity. 6. The fuel cell of claim 1 wherein a pressure differential exists between the gas inlet manifold and the gas outlet manifold such that the pressure differential can at least partially urge the liquid through the drain channel and into the gas outlet manifold. 7. A fuel cell system, comprising: a cell stack assembly including a plurality of cells that are configured to facilitate an electrochemical reaction; a gas inlet manifold on a first side of the cell stack assembly and outside the plurality of cells, the gas inlet manifold being configured to introduce a gas to each of the plurality of cells of the cell stack assembly, the gas inlet manifold having an upper end and a lower end, the gas inlet manifold arranged vertically so that the gas inlet manifold has a longest dimension and an overall length that extend from the upper end to the lower end; a gas outlet manifold on a second side of the cell stack assembly opposite to the first side and outside the plurality of cells, the gas outlet manifold being configured to direct gas away from each of the plurality of cells of the cell stack assembly, the gas outlet manifold arranged vertically and parallel to the gas inlet manifold; a drain channel coupled at a first end to the lower end of the gas inlet manifold and at a second end to the gas outlet manifold, the drain channel positioned externally with respect to the cell stack assembly and oriented perpendicularly with respect to each of the plurality of cells; and a diaphragm associated with the drain channel to restrict gas flow from the gas inlet manifold into the drain channel, wherein the diaphragm has an outside dimension corresponding to an inside dimension of the drain channel and includes a hole through the diaphragm, the hole being smaller in size than the inside dimension of the drain channel. 8. The fuel cell system of claim 7 wherein the drain channel is configured to remove liquid from the gas inlet manifold to prevent the liquid from entering the plurality of cells of the cell stack assembly.