Device and method for producing flow field plates

The invention claimed is: 1. A method for producing bipolar plates for fuel cells, the method comprising: providing a substrate strip in a coil, the substrate strip being pre-coated with a reactive coating and/or catalyst coating; cutting a first substrate plate from the pre-coated substrate strip; cutting a second substrate plate from the pre-coated substrate strip; forming or stamping structures into the first substrate plate to form an anode plate; forming or stamping structures into the second substrate plate to form a cathode plate; and joining the anode plate to the cathode plate to form a bipolar plate. 2. The method for producing bipolar plates according to claim 1 , wherein the forming and/or stamping of the substrate plates is carried out in a pressing device or a rolling device. 3. The method for producing bipolar plates according to claim 1 , wherein after the forming or stamping, the anode plate and the cathode plate are transported, automatically driven by a conveying device, to a joining device and there are joined to form the bipolar plate. 4. The method for producing bipolar plates according to claim 3 , wherein for the joining of the bipolar plate, the cathode plate is placed on the anode plate or the anode plate is placed on the cathode plate by means of the conveying device in the area of the joining device wherein, first the cathode plate or the anode plate is inserted into a holder of the joining device by the conveying device and then the conveying device moves the anode plate or the cathode plate to at least partially overlap the inserted cathode plate or anode plate and then deposits it on the inserted cathode plate or anode plate. 5. The method for producing bipolar plates according to claim 1 , wherein, after the step of forming or stamping, the anode plate and/or the cathode plate is not coated with a reactive coating or a catalyst coating. 6. The method for producing bipolar plates according to claim 1 , wherein after the step of joining the anode plate to the cathode plate to form the bipolar plate, the bipolar plate is not coated with a reactive coating or a catalyst coating. 7. A method for producing bipolar plate stacks using a bipolar plate produced according to a method of claim 1 , wherein, after the joining, the bipolar plate is transported, automatically driven, to a stacking device and there is brought together with a membrane and stacked to form a fuel cell stack. 8. A method for producing bipolar plates for fuel cells, wherein a bipolar plate is formed by joining an anode plate to a cathode plate, and, before the joining, an anode plate and a cathode plate are formed from a substrate plate by forming or stamping structures, wherein a plate provided with a reactive coating and/or catalyst coating is used as substrate plate, and wherein the method is carried out using a device comprising a conveying device, a forming device and a joining device, wherein the conveying device transports substrate plates, automatically driven, in a transport direction first to the forming device and then to the joining device, wherein the forming device stamps structures into the substrate plates by means of at least one stamping die or at least one forming die and thereby forms a substrate plate into an anode plate or a cathode plate, and wherein the joining device joins an anode plate and a cathode plate to form a bipolar plate, and wherein the conveying device has a transport beam with at least one workpiece gripper for gripping substrate plates and/or anode plates and/or cathode plates, wherein the transport beam extends from the forming device to the joining device, and a conveying drive device is connected to the transport beam in order to move the workpiece gripper and/or the transport beam, automatically driven, in or against the transport direction, and to move the workpiece gripper and/or the transport beam, automatically driven, in a lifting direction and/or in a clamping direction.