Your next challenge will be to analyze the associated energy evacuation system that every power generation plant must have, together with the associated protections. And you will achieve it with this Postgraduate diploma!"  

This Postgraduate diploma contains the most complete program on Economics and Operation of Power Plants: Combined Cycle and Cogeneration Plants. It details how the integration of the different technologies within the power generation park is operated and regulated, and addresses production technologies according to their characteristics, installed capacity and energy demand. It also includes the integration of renewable energies into the electricity generation market. 

The student will learn how to perform investment appraisals for the viability and profitability of a power generation plant, as well as how to finance a power generation plant with equity and debt. All this will allow you to perform an in-depth analysis of preliminary projects and studies, since the technical-economic variables and the feasibility of the investment required for the implementation and construction of power generation projects are studied. 

Finally, before embarking on the construction of an electricity generating plant, we must know what type of recruitment we will use for its execution. Therefore, we will study the different types of recruitment that exist, with their different characteristics. Moreover, as it is a 100% online program, it provides the student with the ease of being able to study it comfortably, wherever and whenever they want. They will only need a device with internet access to take their career one step further. A modality in line with the current times with all the guarantees to position the professional in a highly demanded area that is continuously changing, in line with the SDGs promoted by the UN. 

You will learn more about how renewable energies are integrated into the Electricity Market and the international agreements related to the emission of pollutants into the atmosphere" 

This Postgraduate diploma in Economics and Operation of Power Plants: Combined Cycle and Cogeneration Plants contains the most complete and up-to-date scientific program on the market. The most important features of the program include:

• The development of case studies presented by experts in electrical engineering
• The deepening in Energy Resources Management
• The graphic, schematic, and eminently practical contents with which they are created, provide scientific and practical information on the disciplines that are essential for professional practice
• Practical exercises where self-assessment can be used to improve learning
• Its special emphasis on innovative methodologies
• Theoretical lessons, questions to the expert, debate forums on controversial topics, and individual reflection assignments 
• Content that is accessible from any fixed or portable device with an Internet connection 

With this Postgraduate diploma you will deepen your knowledge in the operation and performance of the steam turbine, as it is a fundamental part of power plants"

The program’s teaching staff includes professionals from the sector who contribute their work experience to this training program, as well as renowned specialists from leading societies and prestigious universities.

The multimedia content, developed with the latest educational technology, will provide the professional with situated and contextual learning, i.e., a simulated environment that will provide an immersive training program designed to train in real situations.

This program is designed around Problem-Based Learning, whereby the professional must try to solve the different professional practice situations that arise during the academic year. For this purpose, the professional will be assisted by an innovative interactive video system created by renowned and experienced experts.  

You will discover a new approach to the evolution and new trends in cogeneration plants as never before"

Due to its economic importance, you will learn how the life cycle of electricity generating plants evolves"

The structure of the contents of this program has been designed by industrial engineering professionals who work as electrical energy consultants, focused on the economic management and operation of Combined Cycle and cogeneration power plants. Thus, the program comprises the most advanced knowledge in economics and the latest updates on this area of the energy sector, distributed in four modules. A comprehensive and complete syllabus that is presented as unique in the market today, with which the professional will acquire full competence for their day-to-day work, specializing in areas of the future.    

Become an expert in the different power generation technologies and perform successful economic-financial feasibility analyses" 

Module 1. Economics of Electricity Generation

1.1. Electric Generation Technologies

1.1.1. Generation Activity
1.1.2. Hydraulic Power Plants
1.1.3. Conventional Thermal Plants
1.1.4. Combined Cycle
1.1.5. Cogeneration
1.1.6. Wind
1.1.7. Solar
1.1.8. Biomass
1.1.9. Tidal
1.1.10. Geothermal

1.2. Production Technologies

1.2.1. Features
1.2.2. Installed Power
1.2.3. Power Demand

1.3. Renewable Energies

1.3.1. Characterization and Technologies
1.3.2. Economy of Renewable Energies
1.3.3. Integration of Renewable Energies

1.4. FFinancing of a Generation Project

1.4.1. Financial Alternatives
1.4.2. Financial Instruments
1.4.3. Financial Strategies

1.5. Valuation of Investments in Power Generation

1.5.1. Current Net Value
1.5.2. Internal Rate of Return
1.5.3. Capital Asset Pricing Model (CAPM)
1.5.4. Recuperation of Investment
1.5.5. Limitations to Traditional Techniques

1.6. Real Options

1.6.1. Typology
1.6.2. Principles of Option Pricing
1.6.3. Types of Real Options

1.7. Assessment of Real Options

1.7.1. Probability
1.7.2. Processes
1.7.3. Volatility
1.7.4. Estimation of the Value of the Underlying Asset

1.8. Economic-Financial Feasibility Analysis

1.8.1. Initial Investment
1.8.2. Direct Expenses
1.8.3. Income

1.9. Financing with Own Resources

1.9.1. Corporate Income Tax
1.9.2. Cash Flows
1.9.3. Payback
1.9.4. Net Present Value
1.9.5. Internal Rate of Return

1.10. Partial Debt Financing

1.10.1. Loan
1.10.2. Corporate Income Tax
1.10.3. Cash Flows
1.10.4. Debt Service Coverage Ratio
1.10.5. Shareholder Cash Flow
1.10.6. Shareholder Payback
1.10.7. Net Present Value of Shareholders
1.10.8. Internal Rate of Return to Shareholders

Module 2. Combined Cycle 

2.1. Combined Cycle

2.1.1. Current Combined Cycle Technology
2.1.2. Thermodynamics of Combined Gas-Steam Cycles
2.1.3. Future Trends in Combined Cycle Development

2.2. International Agreements for Sustainable Development

2.2.1. Kyoto Protocol
2.2.2. Montreal Protocol
2.2.3. Paris Climate

2.3. Brayton Cycle

2.3.1. Ideal
2.3.2. Real
2.3.3. Cycle Improvements

2.4. Rankine Cycle Improvements

2.4.1. Intermediate Reheating
2.4.2. Regeneration
2.4.3. Use of Supercritical Pressures

2.5. Gas Turbine

2.5.1. Operation
2.5.2. Performance
2.5.3. Systems and Subsystems
2.5.4. Classification

2.6. Recovery Boiler

2.6.1. Recovery Boiler Components
2.6.2. Pressure Levels
2.6.3. Performance
2.6.4. Characteristic Parameters

2.7. Steam Turbines

2.7.1. Components
2.7.2. Operation
2.7.3. Performance

2.8. Auxiliary Systems

2.8.1. Cooling System
2.8.2. Combined Cycle Performance
2.8.3. Advantages of Combined Cycles

2.9. Pressure Levels in Combined Cycles

2.9.1. A Level
2.9.2. Two Levels
2.9.3. Three Levels
2.9.4. Typical Configurations

2.10. Combined Cycle Hybridization

2.10.1. Fundamentals
2.10.2. Economic Analysis
2.10.3. Emission Savings

Module 3. Cogeneration 

3.1. Structural Analysis

3.1.1. Functionality
3.1.2. Heat Needs
3.1.3. Alternatives in the Processes
3.1.4. Justification

3.2. Types of Heat

3.2.1. With Reciprocating Gas or Fuel Oil Engine
3.2.2. With a Gas Turbine
3.2.3. With a Steam Turbine
3.2.4. In Combined Cycle with Gas Turbine
3.2.5. In Combined cycle with Reciprocating Engine

3.3. Alternative Motors

3.3.1. Thermodynamic Effects
3.3.2. Gas Engine and Auxiliary Elements
3.3.3. Energy Recovery

3.4. Pyrotubular Boilers

3.4.1. Types of Boilers
3.4.2. Combustion
3.4.3. Water Treatment

3.5. Absorption Machines

3.5.1. Operation
3.5.2. Absorption Vs Compression
3.5.3. Water/Lithium Bromide
3.5.4. Ammonia/Water

3.6. Trigeneration, Tetrageneration and Microcogeneration

3.6.1. Trigeneration
3.6.2. Tetrageneration
3.6.3. Microcogeneration

3.7. Exchangers

3.7.1. Classification
3.7.2. Air-Cooled Exchangers
3.7.3. Plate Heat Exchangers

3.8. Tail Cycles

3.8.1. ORC Cycles
3.8.2. Organic Fluids
3.8.3. Kalina Cycle 

3.9. Selection of Cogeneration Plant Type and Size

3.9.1. Design
3.9.2. Types of Technologies
3.9.3. Selection of Fuel
3.9.4. Dimensioning

3.10. New Trends in Cogeneration Plants

3.10.1. Services
3.10.2. Gas Turbines
3.10.3. Alternative Motors

Module 4. Construction and Operation of Electric Power Production Plants 

4.1. Construction

4.1.1. EPC
4.1.2. EPCM
4.1.3. Open Book

4.2. Exploitation of Renewable Energy in the Electricity Market

4.2.1. Increase in Renewable Energies
4.2.2. Market Failures
4.2.3. New Tendencies in Markets

4.3. Steam Generator Maintenance

4.3.1. Water Pipes
4.3.2. Steam Pipes
4.3.3. Recommendations

4.4. Turbine and Motor Maintenance

4.4.1. Gas Turbines
4.4.2. Steam Turbines
4.4.3. Alternative Motors

4.5. Wind Park Maintenance

4.5.1. Types of Faults
4.5.2. Component Analysis
4.5.3. Strategies

4.6. Nuclear Power Plant Maintenance

4.6.1. Structures, Systems and Components
4.6.2. Behavioral Criteria
4.6.3. Behavioral Assessment

4.7. Maintenance of Photovoltaic Power Plants

4.7.1. Panels
4.7.2. Inverters
4.7.3. Energy Evacuation

4.8. Hydraulic Plant Maintenance

4.8.1. Catchment
4.8.2. Turbine
4.8.3. Generator
4.8.4. Valves
4.8.5. Cooling
4.8.6. Oleohydraulics
4.8.7. Regulation
4.8.8. Rotor Braking and Lifting
4.8.9. Excitement
4.8.10. Synchronization

4.9. Life Cycle of Power Plants

4.9.1. Analysis of Life Cycle
4.9.2. LCA Methodologies
4.9.3. imitations

4.10. Auxiliary Elements in Production Plants

4.10.1. Evacuation Lines
4.10.2. Electrical Substation
4.10.3. Protections 

This Postgraduate diploma in Economics and Operation of Power Plants: Combined Cycle and Cogeneration Plants is the program you need to become part of the elite of the sector"