Ahmels, L.L.AhmelsBott, A.-K.A.-K.BottBruder, E.E.BruderGibbels, M.M.GibbelsGramlich, S.S.GramlichHansmann, M.M.HansmannKarin, IvanIvanKarinKohler, M.M.KohlerLipp, K.K.LippMelz, T.T.MelzMüller, C.C.MüllerNeufeld, D.D.NeufeldNiehuesbernd, J.J.NiehuesberndRoos, M.M.RoosTomasella, A.A.TomasellaUlbrich, S.S.UlbrichWagener, R.R.WagenerWalter, A.A.Walter2022-03-052022-03-052017https://publica.fraunhofer.de/handle/publica/25407410.1007/978-3-319-52377-4_42-s2.0-85034768745Based on its procedural principle, every manufacturing technology affects a variety of properties of the workpiece or product in a characteristic way (Sect. 2.3). The sum of all those properties which comprise geometrical as well as material-related ones is considered as manufacturing-induced properties. While the geometric manufacturing-induced properties are often the reason why a specific technology is chosen by the designer for the manufacturing of a certain product, the material-related manufacturing-induced properties are often seen as by-products of the process. With regard to metal forming, all manufacturing processes inherently influence the mechanical properties of the manufactured material. In many cases, these mechanical manufacturing-induced properties are merely regarded in terms of restrictions in product development. However, with respect to a manufacturing-integrated product development approach, the mechanical properties are of special interest, since we aim at utilizing their full potential to maximize the product performance.en620book article