Method for heating energy storage cells of an energy storage system, and heatable energy storage system

The invention claimed is: 1. A method for heating energy storage cells of an energy storage device configured to generate an n-phase supply voltage, wherein n≧1, the energy storage device including n parallel-connected energy supply branches each coupled between an output connection and a reference potential rail, wherein each of the energy supply branches includes a multiplicity of series-connected energy storage modules, each energy storage module including (i) an energy storage cell module having at least one energy storage cell, and (ii) a coupling device having coupling elements configured to selectively switch the energy storage cell module into a respective energy supply branch or to bypass the respective energy supply branch, the method comprising: connecting the output connections of the energy storage device to input connections of an n-phase electric machine and coupling the output connections via a neutral point of the electric machine; and actuating the coupling devices of at least one energy storage module of a first energy supply branch to switch respective energy storage cell modules into the first energy supply branch, and simultaneously, actuating the coupling devices of at least one energy storage module of a second energy supply branch to switch respective energy storage cell modules into the second energy supply branch for a first predetermined time period. 2. The method as claimed in claim 1 , further comprising: actuating the coupling devices of the at least one energy storage module of the second energy supply branch to bypass the respective energy storage cell modules in the second energy supply branch for a second predetermined time period, after the first predetermined time period has elapsed. 3. The method as claimed in claim 1 , wherein the first predetermined time period is shorter than a quotient of an inductance and a nonreactive resistance of the inductive components of the electric machine. 4. The method as claimed in claim 1 , further comprising: selecting the at least one energy storage module of the first energy supply branch and the at least one energy storage module of the second energy supply branch to provide the n-phase supply voltage for the electric machine. 5. The method as claimed in claim 2 , wherein the method is performed if a temperature of the energy storage cells falls below a first predetermined limit value. 6. The method as claimed in claim 5 , wherein the actuating the coupling devices of the at least one energy storage module of the second energy supply branch to switch the respective energy storage cell modules into the second energy supply branch and the actuating the coupling devices of the at least one energy storage module of the second energy supply branch to bypass the respective energy storage cell modules in the second energy supply branch are alternated until a temperature of energy storage cells of at least one energy storage module in question exceeds a second predetermined limit value. 7. A system, comprising: an n-phase electric machine, wherein n≧1; an energy storage device configured to generate an n-phase supply voltage, the energy storage device including n parallel-connected energy supply branches each coupled between an output connection and a reference potential rail, each of the energy supply branches including a multiplicity of series-connected energy storage modules, each energy storage module including (i) an energy storage cell module having at least one energy storage cell, and (ii) a coupling device having coupling elements configured to selectively switch the energy storage cell module into a respective energy supply branch or to bypass the respective energy supply branch; n phase lines each configured to couple one of the output connections of the energy storage device to one of n phase connections of the n-phase electric machine; and a control device is configured to perform a method for heating the energy storage cells of the energy storage device including connecting the output connections of the energy storage device to input connections of the n-phase electric machine and coupling the output connections via a neutral point of the electric machine, and actuating the coupling devices of at least one energy storage module of a first energy supply branch to switch respective energy storage cell modules into the first energy supply branch, and simultaneously actuating the coupling devices of at least one energy storage module of a second energy supply branch to switch respective energy storage cell modules into the second energy supply branch for a first predetermined time period. 8. The system as claimed in claim 7 , wherein the coupling devices comprise coupling elements in a full-bridge circuit. 9. The system as claimed in claim 7 , wherein the coupling devices comprise coupling elements in a half-bridge circuit. 10. The system as claimed in claim 7 , wherein the energy storage cells comprise lithium-ion rechargeable batteries.