Thermal energy storage system with heat discharge system to prevent thermal runaway

What is claimed is: 1. A thermal energy storage system, comprising: a first assemblage of first thermal storage blocks and a second assemblage of second thermal storage blocks, the first and second thermal storage blocks configured to store heat generated from received electrical energy as thermal energy; and a control system configured to: direct fluid flows to the first and second assemblages to produce an output fluid flow comprising hot air or one or more gases; during a first discharge period, perform a first discharge operation by discharging the first assemblage sufficiently to prevent thermal runaway while discharging the second assemblage to at or above a delivery temperature of the output fluid flow; and during a second, successive discharge period, perform a second discharge operation by discharging the second assemblage sufficiently to prevent thermal runaway while discharging the first assemblage to at or above the delivery temperature. 2. The thermal energy storage system of claim 1 , wherein the control system is configured to: perform the first discharge operation by initiating discharge of the first assemblage at a beginning of the first discharge period and initiating discharge of the second assemblage after a first discharge temperature of a first fluid flow produced by the first assemblage drops below the delivery temperature; and perform the second discharge operation by initiating discharge of the second assemblage at a beginning of the second discharge period and initiating discharge of the first assemblage after a second discharge temperature of a second fluid flow produced by the second assemblage drops below the delivery temperature. 3. The thermal energy storage system of claim 2 , wherein the control system is configured to cause the first and second discharge operations to be performed alternately in successive discharge periods. 4. The thermal energy storage system of claim 2 , wherein the control system is configured to perform the first and second discharge operations by initiating a fluid flow to a given assemblage in a trickle mode after discharging the given assemblage to prevent thermal runaway. 5. A method, comprising: receiving, by a thermal energy storage system that includes a first assemblage of first thermal storage blocks and a second assemblage of second thermal storage blocks, input electricity from one or both of a renewable energy source and an electrical grid; using, by the thermal energy storage system, the input electricity to create thermal energy that is stored in the first and second thermal storage blocks; controlling fluid flows to the first and second assemblages to produce an output fluid flow comprising hot air or one or more gases at temperatures within a selected temperature range, wherein the controlling causes: during a first discharge period, discharging the first assemblage in a manner sufficient to reduce thermal runaway in the first thermal storage blocks while discharging the second assemblage to a temperature at or above the selected temperature range; and during a second, successive discharge period, discharging the second assemblage in a manner sufficient to reduce thermal runaway in the second thermal storage blocks while discharging the first assemblage to a temperature at or above the selected temperature range. 6. The method of claim 5 , wherein discharging the first assemblage during the first discharge period includes initiating fluid flow to the first assemblage in a trickle mode after deeply discharging the first assemblage, and wherein discharging the second assemblage during the second discharge period includes initiating fluid flow to the second assemblage in the trickle mode after deeply discharging the second assemblage. 7. The method of claim 5 , wherein discharging the first and second assemblages to reduce thermal runaway is performed based on measured thermal data for the first and second assemblages. 8. The method of claim 5 , wherein discharging the first and second assemblages to reduce thermal runaway is performed based on a modeling of thermal data for the first and second assemblages. 9. A thermal energy storage system, comprising: two or more assemblages of thermal storage blocks, wherein each of the two or more assemblages is configured to store heat generated from received electrical energy as thermal energy; and a control system configured to: direct fluid flows to the two or more assemblages to produce an output fluid flow comprising hot air or one or more gases; and cause each of the two or more assemblages to be periodically deeply discharged to reduce temperature nonuniformities within the two or more assemblages. 10. The thermal energy storage system of claim 9 , wherein the two or more assemblages include a particular assemblage, and wherein the control system is configured to cause the particular assemblage to periodically be deeply discharged on an as-needed basis. 11. The thermal energy storage system of claim 9 , wherein the two or more assemblages include a particular assemblage, and wherein the control system is configured to cause the particular assemblage to periodically be deeply discharged at regularly occurring intervals. 12. The thermal energy storage system of claim 9 , wherein the two or more assemblages are a plurality of N assemblages, and wherein the control system is configured to cause each of the N assemblages to be deeply discharged once every N discharge periods. 13. The thermal energy storage system of claim 9 , wherein the output fluid flow has a specified temperature profile, wherein the two or more assemblages are a plurality of N assemblages, and wherein the control system is configured to cause each of the N assemblages to be deeply discharged at least once every N discharge periods and partially discharged to a current value of the specified temperature profile at least once every N discharge periods. 14. The thermal energy storage system of claim 13 , wherein the two or more assemblages includes a first assemblage and a second assemblage, and wherein the control system is configured to alternate, in successive discharge periods, between: deeply discharging the first assemblage and partially discharging the second assemblage to a current value of the specified temperature profile; and deeply discharging the second assemblage and partially discharging the first assemblage to the current value of the specified temperature profile. 15. The thermal energy storage system of claim 9 , wherein the control system is configured to open an inlet valve to admit a bypass fluid flow that is mixed with other fluid flows to produce the output fluid flow, the output fluid flow having a delivery temperature and the bypass fluid flow having a bypass temperature, and wherein the two or more assemblages are deeply discharged to be closer to the bypass temperature than to the delivery temperature. 16. The thermal energy storage system of claim 9 , wherein the control system is configured to provide supply a trickle fluid flow to a given assemblage after the given assemblage has been deeply discharged. 17. A method, comprising: receiving, at a thermal storage structure, input electricity from one or both of a renewable energy source and an electrical grid; using, by thermal storage structure, the received input electricity to heat heating elements within two or more assemblages of thermal storage blocks; directing fluid flows to the two or more assemblages to produce an output fluid flow comprising hot air or one or more gases and having a delivery temp