Production system for automatically stacking different components of an electrochemical system

1 . A production system for producing at least one electrochemical system that comprises a stack consisting of a plurality of different components which are stacked one above the other along a stacking axis of the stack, with a height dimension of each component extending along the stacking axis, wherein the production system is designed: a) to determine height values for a large number of components and to store said height values in a machine-readable manner; b) to automatically read out height values of at least selected ones of the components; and c) to automatically produce a stack from a number of these components, taking into account the height values read out for these, such that a target height of the stack is achieved. 2 . The production system according to claim 1 , wherein the production system is designed to determine the respective height value of at least selected ones of the components individually. 3 . The production system according to claim 2 , wherein the individual determination comprises: individually measuring the height value; and/or individually calculating the height value as a function of how the component is individually assembled from pre-products. 4 . The production system according to claim 1 , wherein the production system is designed to determine, for at least one type of component, a representative height value that is stored for a plurality of components of this type. 5 . The production system according to claim 1 , wherein the production system is designed to execute at least one of the following measures in order to store the height values in a machine-readable manner: saving in an internal memory device of the production system; saving in an external memory device, the production system being designed to access the external memory device for the purpose of reading out the height values; encoding a height value in a machine-readable code that is applied to at least one of the components; encoding a link to a storage location of a height value in a machine-readable code that is applied to at least one of the components. 6 . The production system according to claim 1 , wherein at least measures a) and c) are executed in different devices and/or at different manufacturing stations of the production system. 7 . The production system according to claim 1 , wherein measure a) is executed for a large number of components, from which multiple stacks can be produced in order to produce a plurality of electrochemical systems. 8 . The production system according to claim 1 , wherein the production system is designed to determine a required number of height-compensating elements that are to be arranged in the stack in order to achieve the target height, it being possible for said number to be zero, one, or more than one. 9 . The production system according to claim 1 , wherein the production system is designed to determine a required height dimension of at least one height-compensating element that is to be arranged in the stack in order to achieve the target height of the stack. 10 . The production system according to claim 1 , wherein the production system is designed to determine a required number of electrochemically inactive dummy cells that are to be arranged in the stack in order to achieve a target height of the stack, it being possible for said number to be zero, one, or more than one. 11 . The production system according to claim 8 , wherein the production system is designed to tension the stack only after any height-compensating elements have been arranged in the stack and/or after any dummy cells have been arranged in the stack. 12 . The production system according to claim 1 , wherein the production system is designed to select a plurality of components, taking into account the height values thereof, in order to produce the stack. wherein the components are selected in order to produce a common portion of the stack to be produced, such that a target height of said common portion is achieved, and wherein the components are selected by taking into account the actual height value and/or the expected extrapolated height value. 13 . The production system according to claim 1 , wherein the production system is designed to determine an actual height value of the at least partially produced stack while the stack is being produced, and/or to determine an expected extrapolated height value of the finished stack. 14 . The production system according to claim 13 , wherein the actual height value and/or the expected extrapolated height value is or are determined on the basis of a summing of the height values of the components stacked one above the other thus far. 15 . The production system according to claim 1 , wherein the electrochemical system is a fuel cell system and the stack ( 16 , 18 ) comprises at least one of the following types of components: bipolar plates formed of two separator plates; unipolar plates, comprising one or two separator plates at a lowermost or uppermost position in a sub-stack comprising a plurality of alternately stacked bipolar plates and cells; endplate assemblies; membrane electrode assemblies (MEA); seals; gas diffusion layers; electrochemical cells, each comprising an MEA and at least one gas diffusion layer. 16 . The production system according to claim 1 , wherein the electrochemical system is an electrolyzer and the stack comprises at least one of the following types of components: separator plates between electrochemical cells of the system and/or between an electrochemical cell and an endplate assembly; endplate assemblies; proton-exchange membranes; frame elements; sealing elements; gas diffusion layers; transport layers; electrochemical cells, each comprising at least one proton-exchange membrane and one or more gas diffusion layers and/or one or more transport layers. 17 . The production system according to claim 1 , wherein the electrochemical system is an electrochemical compressor or a redox flow battery. 18 . The production system according to claim 1 , wherein the stack comprises bipolar plates or single-layer separator plates and/or MEAs and gas diffusion layers as components, the height values of these components referring to at least one of the following states: height (thickness) of the starting material used to produce the individual plates for producing the bipolar plates; height after the individual plates have been embossed and/or cut to size to produce the bipolar plates or after the separator plates have been embossed and/or cut to size; height after the individual plates have been joined to produce the bipolar plates; height after the bipolar plates or separator plates have been coated; height after a seal has been applied to the bipolar plates or separator plates height after the gas diffusion layers have been cut to size; height of the MEA used; height after one of the MEAs and one or two gas diffusion layers have been joined, prior to these being arranged in the joined state in the stack to be produced. 19 . Method for producing at least one electrochemical system that comprises a stack consisting of a plurality of different components which are stacked one above the other along a stacking axis of the stack, with a height dimension of each component extending along the stacking axis, wherein the method comprises: determining height values for a large number of components and storing said height values in a machine-readable manner; automatical