Fuel cell systems and methods

1 . A fuel cell system comprising: at least one fuel cell stack comprising at least one fuel cell, and having an anode inlet, an anode off-gas outlet for flow of anode off-gas; a first heat exchanger coupled to receive the anode off-gas which has been output form the anode off-gas outlet, the first heat exchanger configured to exchange heat between the anode off-gas and a heat transfer fluid to cool the anode off-gas and heat the heat transfer fluid; a second heat exchanger that is configured to provide heat to the heat transfer fluid; a heat removal region that is configured to remove heat from the heat transfer fluid; and a pump configured to pump the heat transfer fluid around a fluid circuit in a flow direction of: heat removal region where thermal energy is removed, second heat exchanger where thermal energy is added, first heat exchanger where thermal energy is added. 2 . The fuel cell system of claim 1 , further comprising a separator to receive the anode off-gas from the first heat exchanger and configured to separate condensed water from the anode off-gas from anode off-gas containing remaining water vapour. 3 . The fuel cell system of claim 1 , further comprising a burner through which the anode off-gas is routed, subsequent to the separator, and remaining fuel in the anode off-gas combusted, and wherein the combustion products are routed to the second heat exchanger to provide said heat to the heat transfer fluid. 4 . The fuel cell system of claim 3 , further comprising a top up line configured to supply fuel to burner, wherein use of fuel by the burner is controllable to increase a heat content of the combustion products and thereby increase the temperature of the heat transfer fluid. 5 . The fuel cell system of claim 1 , wherein the heat removal region comprises a third heat exchanger configured to remove heat from the heat transfer fluid to another medium. 6 . (canceled) 7 . The fuel cell system of claim 5 , wherein the other medium is a gas, and wherein the gas is driven through the third heat exchanger by a controllable fan configured to control heat transfer from the heat transfer fluid. 8 . (canceled) 9 . The fuel cell system of claim 1 , wherein the heat removal region comprises a fourth heat exchanger in the fluid circuit configured to remove heat from the heat transfer fluid to a heat reservoir if the temperature of the heat transfer fluid is greater than the temperature of the heat reservoir and provide heat to the heat transfer fluid from the heat reservoir if the temperature of the heat transfer fluid is less than the temperature of the heat reservoir. 10 . The fuel cell system of claim 9 , wherein the heat reservoir comprises a hot water circuit in which water circulates. 11 . The fuel cell system of claim 1 , further comprising a fifth heat exchanger positioned in the fluid circuit between the heat removal region and the first heat exchanger, and the fifth heat exchanger configured to provide heat to the heat transfer fluid. 12 . (canceled) 13 . The fuel cell system of claim 1 , wherein one or more of the pump and the rate of heat removal in the heat removal region are controllable by an algorithm to maintain a target temperature of the heat transfer fluid subsequent to the first heat exchanger. 14 . (canceled) 15 . A method for controlling temperature of a heat transfer fluid in a fuel cell system in which the heat transfer fluid is pumped around a fluid circuit by a pump of controllable speed and a heat removal region configured to remove heat from the heat transfer fluid to another medium, wherein a mass flow rate of the other medium is controllable to control the rate of heat removal, the method comprising: prioritising increasing pump speed over increasing the mass flow rate of the other medium as temperature of the heat transfer fluid rises, and prioritising reducing mass flow rate of the other medium over reducing pump speed as temperature of the heat transfer fluid falls. 16 - 18 . (canceled) 19 . The method of claim 15 , wherein if the temperature is less than the maximum temperature of the operating range, further comprising reducing the mass flow rate of the other medium to zero. 20 . (canceled) 21 . The method of claim 15 , wherein the temperature is a first temperature and the first temperature of heat transfer fluid is monitored subsequent to a first heat exchanger in the fluid circuit and further comprising determining that the first temperature is such that the heat transfer fluid may freeze and increasing the temperature of the heat transfer fluid and/or determining that the temperature of water condensed at the first heat exchanger and entering a storage tank subsequent to the first heat exchanger may freeze and increasing the temperature of the heat transfer fluid. 22 . The method of claim 15 , further comprising monitoring a water level in a tank in which water is recovered from anode off-gas for reuse in a fuel cell stack, and a) determining that an increased rate of water recovery is required to at least maintain the water level, and increasing pump speed and/or increasing mass flow rate of the other medium in order to reduce the temperature of the heat transfer fluid, or b) determining that a decreased rate of water recovery may be tolerated, and reducing pump speed and/or reducing mass flow rate of the other medium in order to increase the temperature of the heat transfer fluid. 23 . The method of claim 15 , further comprising monitoring a second temperature of heat transfer fluid prior to the first heat exchanger. 24 . The method of claim 23 , further comprising determining that the second temperature is such that the heat transfer fluid may freeze and supplying fuel to a burner configured to combust said fuel and routing the combustion products to a second heat exchanger in the fluid circuit to heat the heat transfer fluid. 25 . (canceled) 26 . The method of claim 15 , wherein the other medium is a gas, and wherein the gas is driven by a fan of controllable speed to vary the mass flow rate of the gas and control the rate of heat removal in the heat removal region. 27 . A fuel cell system comprising: at least one fuel cell stack comprising at least one solid oxide fuel cell, and having an anode inlet, an anode off-gas outlet for flow of anode off-gas; a first heat exchanger coupled to receive the anode off-gas which has been output form the anode off-gas outlet, the first heat exchanger configured to exchange heat between the anode off-gas and a heat transfer fluid to cool the anode off-gas and heat the heat transfer fluid; a second heat exchanger that is configured to provide heat to the heat transfer fluid; a heat removal region that is configured to remove heat from the heat transfer fluid; a bypass path for the heat transfer fluid to bypass the heat removal region; and a pump configured to pump the heat transfer fluid around a fluid circuit in a flow direction of: first heat exchanger where thermal energy is added second heat exchanger where thermal energy is added, heat removal region where thermal energy is removed. 28 . The fuel cell of claim 27 , wherein the bypass path comprises a controllable flow splitter to control a relative flow rate of the heat transfer fluid through the bypass path and through the heat removal region. 29 . The fuel cell of claim 27 , wherein the heat removal r