All-solid-state batteries possess multiple advantages compared to already established battery technologies. Therefore, they are emerging as promising candidates for the sustainable storage of energy and acceleration of electrification in multiple fields. Despite the rapidly growing interest and vast material and cell design research activities, all-solid-state batteries are still in their infancy stage. Both market entry and full exploitation of the storage potential now mainly depend on the development of production technology empowering the large-scale breakthrough. Thereby, the selection of suitable manufacturing routes and development of production processes resulting from the novel components and materials plays a key role. To provide a better understanding and a systematic approach for the analysis of all-solid-state battery production, a holistic Matlab-based SimEvents factory simulation model is presented in this work. It enables the modeling and simulation of all-solid-state battery production scenarios consisting of a certain material choice, process steps, sequence, process parameters, storage capacity, and boundary conditions such as throughput, downtime, and scrap rate. An algorithm automatically performs the evaluation and comparison of the scenarios regarding production-related KPIs such as ramp-up time, capacity utilization, circulating stock, and storage load. In addition, the highly complex and nonlinear dependencies specific for all-solid-state battery production, as well as bottlenecks between the processes, are quantified. As a result, the factory model enables the optimization of manufacturing routes and production processes depending on the product design at a very early stage and the low-level maturity of this new energy storage technology.