Solid oxide electrolyzer system including air bypass

The invention claimed is: 1. An electrolyzer system, comprising: a splitter configured to split a first air inlet stream into a bypass air stream and a second air inlet stream; a stack of electrolyzer cells configured receive steam and the second air inlet stream and output a product stream containing hydrogen and an oxygen exhaust stream, wherein the bypass air stream is configured to bypass the stack; and a product cooler heat exchanger configured to cool the product stream using the first air inle stream. 2. The electrolyzer system of claim 1 , further comprising an air heater configured to heat the second air inlet stream before the second air inlet stream is provided to the stack. 3. The electrolyzer system of claim 2 , wherein: the stack of electrolyzer cells comprises a stack of solid oxide electrolyzer cells; and the bypass air stream is configured to bypass the air heater and is configured not to be provided to the air heater or to the stack. 4. The electrolyzer system of claim 2 , further comprising: an air blower configured to provide the first air inlet stream to the product cooler heat exchanger; a first air conduit fluidly connecting the air blower to the product cooler heat exchanger; an exhaust conduit assembly fluidly connected to the stack and configured to receive the oxygen exhaust stream from the stack and to exhaust the oxygen exhaust stream from the electrolyzer system; and a bypass conduit fluidly connecting the splitter to the exhaust conduit assembly and configured to deliver the bypass air stream from the splitter to the exhaust conduit assembly while bypassing the stack. 5. The electrolyzer system of claim 4 , further comprising a bypass valve configured to control a flow rate of the bypass air stream through the bypass conduit. 6. The electrolyzer system of claim 5 , further comprising a controller configured to control the bypass valve based on an oxygen content of the oxygen exhaust, wherein the bypass valve is an electrically actuated valve. 7. The electrolyzer system of claim 4 , further comprising a hotbox housing the stack and the air heater, wherein the bypass conduit is disposed outside of the hotbox and is fluidly connected to a portion of the exhaust conduit assembly that is disposed outside of the hotbox. 8. The electrolyzer system of claim 7 , wherein the splitter is disposed outside of the hotbox, such that the bypass conduit bypasses the hotbox. 9. The electrolyzer system of claim 2 , further comprising an air recuperator heat exchanger configured to preheat the second air inlet stream using the oxygen exhaust stream before the second air inlet stream is provided to the air heater. 10. The electrolyzer system of claim 1 , wherein a flow rate of the bypass air stream is configured to be at least 10% of a flow rate of the first air inlet stream.