You're confusing and accumulating waaaaay too many different these here - and, indeed, if as you claim "If you cannot ask it simply, you do not understand it well enough ... to be taught easily." 8<)
One. From an (assumed) maximum (or average ?) steam conditions of 390 C at 90 bar, you "might" theorectically be able to calculate the maximum size "perfect" steam turbine that, "might" be able some calculated energy under ideal conditions IF you also gave us the available cooling water flow, cooling water temperature, heat exchanger assumed efficiency (under average conditions, worst-case conditions, and best case conditions) and expected condenser vacuum conditions.
Or, for that assumed steam pressure and temperature, we could assume some atmospheric conditions or some "vented steam" conditions for those cases where you did not want to completely cool the steam to the condenser. The difference in heat energy, plus the assumed efficiencies of the turbine, turbine-to-generator, and generator efficiency could let us calculate what energy "might" be able to be created as a co-gen facility whose output ( steam, electricity, and low-grade heating steam) might be useful.
Or, if you gave us a required output of EITHER 50 Megawatt or 100 Megawatt electrical (?) and those steam conditions AND some assumed condenser properties, then we could calculate whether that much power could be generated at all. (Or, if that much electric could be generated from those conditions, how much steam flow would be required into what sized turbine given some assumed condenser properties.)
Or, let's say you (the customer) already had a 50 (or a 100) Megawatt turbine sitting in your parking lot. (It does happen you know.) Further, let's assume you (the customer) already has steam available at 390 deg C at 90 bar. Then, the question becomes: "How much (electrical) power can I generate using this established equipment from that much established steam properties (and at some assumed flow!) into some assumed condenser properties of cooling water temperature, cooling water flow, heat exchanger efficiency and vacuum."
But without steam flow, steam conditions, and condenser properties we are just guessing.
So, how do real engineers determine what size turbine is required? You (the customer) tells us what he or she wants. Then we (the real engineers) determine what is needed to generate that much under the real-world conditions of that particular power plant during each month (or day) of the year. Needing more information than what you provided.
