Lean-manufacturing, as an organization model is applied in different industries, and it originates from Japan, particularly the automotive industry, particularly the Toyota corporation. The Toyota production system was developed after the Second World War, which resulted in a production system that eliminated many wastes, thereby enabling a very efficient technological development. Inside of lean-manufacturing, it appeared that better results come with detailed analysis of processes, which includes all phases of production. Design for production lends itself well into the lean manufacturing principles. In this work, the stated method of analysis is used on an example of a ships block, a typical cargo hold and tunnel of bulk carrier ship. The entire electical equipment is listed and classified in a table according to quantity, label, type, weight, and by work hours needed for installation of each equipment. As a result of this analysis, it is given less work hours for installation of cable tracks, in a way that instead of conducting an installation on the ship, it is done by integrating cable tracks in a pre-assembly of a section. Besides the equipment of the cargo hold and tunnel, the main equipment is the conveyor, based on which the simulation of a variable frequency drive is generated, where it is possible to control the speed of an asynchronous machine that drives the conveyor. Based on results of a simulation, it is shown how a variable frequency drive influences asynchronous machine, also it is analysed a working principle of an inverter in general. Also, an optimisation in building a ship is performed using FORAN software, whereby a simple version of a 3D ship model, by which calculation of ship propulsion is made so that it gives an insight of what power inverter to use, as a proposal of switching from diesel-mechanic propulsion to an electrical propulsion system.