Battery module disconnect arrangement

The invention claimed is: 1. A method of disconnecting at least one battery module of a plurality of battery modules in an automotive battery, the method comprising: detecting the at least one detected battery module is to be disconnected; bypassing the at least one detected battery module to be disconnected; and disconnecting the at least one detected battery module from remaining battery modules comprised in the automotive battery no earlier than simultaneous to bypassing of the at least one detected battery module. 2. The method according to claim 1 , further comprising: discharging the at least one detected battery module no earlier than simultaneously as the disconnection of the at least one detected battery module. 3. The method according to claim 1 , further comprising: indicating to a user of the battery that the at least one detected battery module is disconnected. 4. The method according to claim 1 , further comprising igniting a pyrotechnical charge to activate a piston-like movable bridging element to close a first conductive path for the at least one detected battery module and to activate a piston-like movable breaking element to open a second conductive path for the at least one detected batter module. 5. An arrangement for disconnecting at least one battery module of a plurality of battery modules in an automotive battery, the arrangement comprising: a device arranged to detect that at least one detected battery module is to be disconnected; a bypass switch arranged at each battery module, the bypass switch arranged at the at least one detected battery module being controllable to bypass the at least one detected battery module via a bypass path; and a disconnect switch arranged at each battery module, the disconnect switch arranged at the at least one detected battery module being controllable to disconnect the at least one detected battery module from remaining battery modules no earlier than simultaneously to bypassing of the at least one detected battery module such that the at least one detected battery module is at least one bypassed battery module. 6. The arrangement according to claim 5 , further comprising: a discharge switch and an energy draining device arranged at each battery module, the discharge switch arranged at the at least one detected battery module being controllable to couple the at least one detected battery module to the energy draining device for discharging of the at least one detected battery module no earlier than simultaneously as the disconnection of the at least one detected battery module. 7. The arrangement according to claim 6 , further comprising: current sensing means arranged at each battery module for sensing a current in the bypass path of the at least one bypassed battery module, the current sensing means for sensing a current being arranged to control the disconnect switch to disconnect the at least one bypassed battery module when the current in the bypass path has reached a predetermined threshold level, the current sensing means is arranged to control the discharge switch to discharge the at least one battery module to be disconnected when the current at a terminal of the at least one battery module has reached the predetermined threshold level. 8. The arrangement according to claim 6 , wherein the discharge switches are pyrotechnical switches arranged to couple the disconnected battery modules to the energy draining devices upon ignition of a pyrotechnical charge by causing a second movable bridging element arranged at the pyrotechnical charge to move to a position where the second bridging element closes a circuit between the battery module and the energy draining device. 9. The arrangement according to claim 8 , wherein at least two of the bypass switch, the disconnect switch and the discharge switch at the respective battery module are combined in the same housing and uses the same pyrotechnical charge for ignition. 10. The arrangement according to claim 5 , further comprising: current sensing means arranged at each battery module for sensing a current in the bypass path of the at least one bypassed battery module, the current sensing means for sensing a current being arranged to control the disconnect switch to disconnect the at least one bypassed battery module when the current in the bypass path has reached a predetermined threshold level. 11. The arrangement according to claim 10 , wherein the current sensing means arranged at each battery module for sensing a current is a coil. 12. The arrangement according to claim 5 , further comprising: current sensing means arranged at each battery module for sensing a current at a terminal of the at least one battery module to be disconnected, the current sensing means arranged to control the bypass switch to bypass the at least one battery module to be disconnected when the current at the terminal has reached a predetermined threshold level. 13. The arrangement according to claim 12 , wherein: the current sensing means arranged at each battery module is arranged to control the disconnect switch to disconnect the at least one battery module to be disconnected when the current at the terminal has reached the predetermined threshold level. 14. The arrangement according to claim 5 , wherein the disconnect switch is arranged to receive a control signal from an electronic control unit of a motor vehicle in which the automotive battery is arranged, for disconnecting the at least one detected battery module. 15. The arrangement according to claim 14 , wherein the disconnecting switches are pyrotechnical switches arranged to disconnect the battery modules upon ignition by the control signal of a pyrotechnical charge by causing a movable breaking element arranged at the pyrotechnical charge to move to a position where the breaking element breaks a connection between the respective battery module and a main power delivery line of the automotive battery. 16. The arrangement according to claim 14 , wherein the bypass switches are pyrotechnical switches arranged to close a bypass path upon ignition by the control signal of a pyrotechnical charge by causing a first movable bridging element arranged at the pyrotechnical charge to move to a position where the first bridging element closes the bypass path to the main power delivery line of the automotive battery. 17. The arrangement according to claim 5 , further comprising: a delay circuit arranged at each battery module to delay a control signal to one or more of the respective bypass switches, disconnect switches and discharge switches. 18. The arrangement according to claim 5 , further comprising: a pyrotechnical charge; a piston-like movable bridging element movable in response to ignition of the pyrotechnical charge to close a first conductive path for the at least one detected battery module; and a piston-like movable breaking element movable in response to ignition of the pyrotechnical charge to open a second conductive path for the at least one detected batter module. 19. An arrangement for disconnecting all battery modules of a plurality of battery modules in an automotive battery, the arrangement comprising: a device arranged to detect detected battery modules to be disconnected; a bypass switch arranged at the automotive battery controllable to bypass the battery modules via a bypass path; and a disconnect switch arranged at a location selected from a group consisting of each battery module and a main power delivery line, the disconnect switch arranged at the resp