Part 1: Do the Analysis of the Ocean Thermal Gradient Power Plant shown below. Your Analysis will be easier to do in EES but it is up to you. Your EES program must be well documented and documentation in your code should reference system sketches. (The cycle and individual components) These sketches are done on attached engineering or typing paper, unless you are able to draw them in EES. You must validate your results with hand calculations on engineering paper that invoke the 1st and 2nd Law from the perspective of the entire cycle, not the individual components. Of course, a system sketch is required. 1. An ocean thermal gradient power plant using a simple non-ideal Rankine Cycle operates with a peak boiler temperature of 70 °F and a condenser temperature of 40 °F. The warm surface water of the ocean is supplying the thermal energy to the boiler. Assume a high source temperature of 80 °F. The cooler water deeper in the ocean is the sink for heat rejection at the condenser. Assume a low sink temperature of 35 °F (Such a power plant is a type of solar plant. After all, it's the sun that heats the ocean surface water.) Assume that the turbine has an isentropic efficiency of 0.8 and that the pump has an isentropic efficiency of 0.75. Assume that the working fluid for the power plant is water. The quality of the steam leaving the boiler is 1.0 for a simple cycle. Find the following and present them on a single typed Summary page that is the front page of Part 1: a) The Net work per unit of mass flow rate of the plant's working fluid b) The plant's thermal efficiency

Transcribed Image Text:

Part 1: Do the Analysis of the Ocean Thermal Gradient Power Plant shown below. Your Analysis will be easier to do in EES but it is up to you. Your EES program must be well documented and documentation in your code should reference system sketches. (The cycle and individual components) These sketches are done on attached engineering or typing paper, unless you are able to draw them in EES. You must validate your results with hand calculations on engineering paper that invoke the 1 and 2 Law from the perspective of the entire cycle, not the individual components. Of course, a system sketch is required. nd 1. An ocean thermal gradient power plant using a simple non-ideal Rankine Cycle operates with a peak boiler temperature of 70 °F and a condenser temperature of 40 °F. The warm surface water of the ocean is supplying the thermal energy to the boiler. Assume a high source temperature of 80 °F. The cooler water deeper in the ocean is the sink for heat rejection at the condenser. Assume a low sink temperature of 35 °F (Such a power plant is a type of solar plant. After all, it's the sun that heats the ocean surface water.) Assume that the turbine has an isentropic efficiency of 0.8 and that the pump has an isentropic efficiency of 0.75. Assume that the working fluid for the power plant is water. The quality of the steam leaving the boiler is 1.0 for a simple cycle. Find the following and present them on a single typed Summary page that is the front page of Part 1: a) The Net work per unit of mass flow rate of the plant's working fluid b) The plant's thermal efficiency c) The Lost Work of the plant per unit mass flow rate of the working fluid. d) The back work ratio e) The required working fluid flow rate for a 1000 MW net power output f) The diameter of the pipe leaving the boiler if the velocity in the pipe is to be 100 ft/sec Note: Include in your analysis a State Table (can be done on engineering or typing paper if you prefer) and a T-S diagram