Calculations were performed of the thermal system of a power plant with installed water pressure tanks. The maximum rise in the block electric power resulting from the shut-off of low-pressure regenerative heaters is determined. At that time, the boiler is fed with hot water from water pressure tanks acting as heat accumulators. Accumulation of hot water in water tanks is also proposed in the periods of the power unit small load. In order to lower the plant electric power in the off-peak night hours, water heated in low-pressure regenerative heaters and feed water tank to the nominal temperature is directed to water pressure tanks. The water accumulated during the night is used to feed the boiler during the period of peak demand for electricity. Drops in the power block electric power were determined for different capacities of the tanks and periods when they are charged. A financial and economic profitability analysis (of costs and benefits) is made of the use of tanks for a 200 MW power unit. Operating in the automatic system of frequency and power control, the tanks may also be used to ensure a sudden increase in the electric power of the unit. The results of the performed calculations and analyses indicate that installation of water pressure tanks is well justified. The investment is profitable. Water pressure tanks may not only be used to reduce the power unit power during the off-peak night hours and raise it in the periods of peak demand, but also to increase the power capacity fast at any time. They may also be used to fill the boiler evaporator with hot water during the power unit start-up from the cold state.

The paper covers problems of the owners of a fleet of long-operated conventional power plants that are going to be decommissioned soon in result of failing to achieve new admissible emissions levels or exceeding pressure elements design lifetime. Energoprojekt-Katowice SA, Siemens AG and Rafako SA presents their joint concept of the solution which is a 2on1 concept – replacing two unit by two ultra-supercritical boilers feeding one turbine. Polish market has been taken as an example.

Today’s manufacturing environment is highly uncertain, and it is continuously changing. It

is characterized by shorter life cycles of products and technologies, shorter delivery times, an

increased level of customization at the price of a standard product, increased product variety,

quality as well as demand variability and intense global competition. Academicians, as well as

practitioners, agree that uncertainty will continue to grow in the twenty-first century. To deal

with the uncertainties in demand variation and production capacity a manufacturing system

is required which can be easily reconfigured when there is a need at low cost. A reconfigurable

manufacturing system is such a type of system.

In the present work, the concept of the reconfigurable manufacturing system has been discussed

and reviewed. It has been compared with dedicated systems and flexible manufacturing

systems. Part family formation and barriers of reconfiguration also have been discussed.

This work is an attempt to contribute to the conceptual systematization of the reconfigurable

manufacturing system and reconfigurability by synthesizing the vast literature available after

a systematic review.