Electric energy store

The invention claimed is: 1. An electric energy store, comprising: a thermally insulated space which has a process gas inlet and a process gas outlet, at least two stacks, each stack with at least one electrochemical storage cell, being arranged in the thermally insulated space, and each stack in turn having a process gas inlet and a process gas outlet, wherein the at least two stacks are connected in series with respect to the routing of the process gas, a heat exchanger arranged between a first stack and a second stack of the at least two stacks, and a heat store disposed in the thermally insulated space and in thermal contact with the heat exchanger, and an inlet heat exchanger disposed in the thermally insulated space between a process gas feed and the first stack with respect to the routing of the process gas, configured to heat process gas entering the first stack, and in thermal contact with the heat store. 2. The electric energy store as claimed in claim 1 , wherein the heat store is a latent heat store. 3. The electric energy store as claimed in claim 2 , wherein a phase transformation temperature of a storage material of the latent heat store lies above a process gas inlet temperature and below a process gas outlet temperature. 4. The electric energy store as claimed in claim 1 , wherein a heating element is arranged in the heat store. 5. The electric energy store as claimed in claim 1 , further comprising: at least two additional stacks, each additional stack with at least one electrochemical storage cell, each additional stack being arranged in the thermally insulated space, and each additional stack in turn having a process gas inlet and a process gas outlet, an additional heat exchanger disposed in the thermally insulated space; and an additional inlet heat exchanger disposed in the thermally insulated space; wherein with respect to an additional routing of the process gas the at least two additional stacks are connected to each other in series, the additional heat exchanger is disposed between the at least two additional stacks, and the additional inlet heat exchanger is disposed upstream of the at least two additional stacks. 6. The electric energy store as claimed in claim 5 , wherein the additional heat exchanger is in thermal contact with the heat store. 7. The electric energy store as claimed in claim 1 , further comprising: a third stack comprising at least one electrochemical storage cell, disposed in the thermally insulated space, and connected in series with and downstream of the second stack with respect to the routing of the process gas, and a further heat exchanger disposed in the thermally insulated space and between the second stack and the third stack with respect to the routing of the process gas, wherein the inlet heat exchanger is arranged such that the inlet heat exchanger is surrounded by the heat exchanger and the further heat exchanger. 8. The electric energy store as claimed in claim 1 , wherein the heat store is arranged in the thermally insulated space and is in turn insulated thermally from the thermally insulated space. 9. The electric energy store as claimed in claim 1 , wherein the heat exchanger receives heat from process gas exiting one of the stacks of the at least two stacks, wherein the heat store transfers the heat to the inlet heat exchanger, and wherein the inlet heat exchanger transfers the heat to process gas entering at least one of the stacks of the at least two stacks. 10. The electric energy store as claimed in claim 1 , wherein the electric energy store is embodied as a metal air battery.