Device and method for controlling the temperature of an electric energy store of a vehicle

The invention claimed is: 1. A device for controlling a temperature of an electric energy store of a vehicle, comprising: a first flow path opening into a housing of the electric energy store; a ventilation system for temperature-controlled ventilation of a passenger compartment of the vehicle, the ventilation system having a heating and/or cooling device and a second flow path leading from the at least one heating and/or cooling device into the passenger compartment; a supply air inlet configured to receive an inflow of air from a surroundings of the vehicle, divide the inflow into a first partial flow and a second partial flow, feed the first partial flow to the first flow path, and feed the second partial flow to an inlet of the ventilation system; and a heat exchanger connected in the first and the second flow paths, wherein the two flow paths are connected in the device such that an airflow in, in each case, one of the two flow paths is fluidically independent of an airflow in the respective other of the two flow paths, and wherein the heat exchanger is configured for pure heat exchange between the airflows in the two flow paths. 2. The device as claimed in claim 1 , wherein the heating and/or cooling device has a cooling compressor and/or a stationary-mode heater. 3. The device as claimed in claim 1 , further comprising: a first temperature regulating device having a temperature sensor configured to determine a temperature of the electrical energy store and an actuator element configured to change a throughflow of the airflow in the first flow path. 4. The device as claimed in claim 3 , wherein the ventilation system has a second temperature regulating device having a temperature sensor configured to determine a temperature in the passenger compartment and an actuator element configured to change a throughflow of the airflow in the second flow path. 5. The device as claimed in claim 1 , further comprising: an air discharge duct configured to discharge air from the housing of the electrical energy store, wherein the ventilation system has a second air discharge duct configured to discharge air from the passenger compartment, through which air discharge ducts respective waste air is discharged to the surroundings of the vehicle. 6. The device as claimed in claim 5 , wherein the ventilation system has a return flow duct, connecting the second air discharge duct to the inlet of the ventilation system, for an air circulation mode of the ventilation system. 7. A vehicle having a passenger compartment, an electric energy store, and a device for controlling a temperature of the electric energy store, the device comprising: a first flow path leading to the electric energy store; a ventilation system for temperature-controlled ventilation of the passenger compartment, the ventilation system having a heating and/or cooling device and a second flow path leading to the passenger compartment; a supply air inlet configured to receive an inflow of air from a surroundings of the vehicle, divide the inflow into a first partial flow and a second partial flow, feed the first partial flow to the first flow path, and feed the second partial flow to an inlet of the ventilation system; and a heat exchanger connected in both flow paths, wherein the first flow path opens into a housing of the electric energy store, wherein the two flow paths are connected in the device such that an airflow in, in each case, one of the two flow paths is fluidically independent of an airflow in the respective other of the two flow paths, and wherein the heat exchanger is configured for pure heat exchange between the airflows in the two flow paths. 8. A method for controlling a temperature of an electric energy store of a vehicle with a ventilation system for temperature-controlled ventilation of a passenger compartment of the vehicle, comprising: dividing a supply airflow of air from a surroundings of the vehicle in a supply air inlet into a first partial flow and a second partial flow; feeding the first partial flow to a first flow path; feeding the second partial flow to an inlet of the ventilation system; feeding a temperature-controlled airflow to the electric energy store by the first flow path, the first flow path leading through a heat exchanger; feeding an airflow to the passenger compartment via a second flow path with the ventilation system, the second flow path leading through the heat exchanger; and temperature controlling the airflow which is fed to the energy store in the heat exchanger by a transfer of heat between the airflows. 9. The method as claimed in claim 8 , wherein the divided first partial flow is fluidically independent from the divided second partial flow. 10. The method as claimed in claim 8 , wherein the airflow which is fed to the energy store is temperature controlled in the heat exchanger by pure heat exchange between the airflows.