Practical Power Plant Engineering. Zark Bedalov
what he was expecting. So he skipped over the border to Wiena, Austria, and arranged for immigration to Canada. Finding a job in Canada was not easy, in particular if you are an engineer. Being an engineer comes with responsibility and that requires “Canadian Experience.” It took him about six months to start as a draftsman on mining projects. Had a lot of support from many senior engineers and three years later was certified a “Professional Engineer.”
From thereon, Zark was in his domain and in demand. Early on, he changed companies every three to four years to learn more. He worked for almost 50 years on large projects, power plants, and heavy industries, all around the world, employed by major international engineering companies, such as Bechtel, Fluor, Atomic Energy of Canada, SNC Lavalin, and often independent, teaching along the way and enjoying the work and life. Now retired, he writes on electricity and teaches young engineers on how the electricity makes the factories and power plants function.
1 Plant from Design to Commissioning
CHAPTER MENU
1.1 Planning 1.1.1 Plant Design Procedure 1.1.2 Codes and Standards
1.2 Project Development 1.2.1 Type of Project 1.2.2 Conceptual Design for Feasibility Study 1.2.3 Detailed Design 1.2.4 Engineering Documents 1.2.5 Equipment Specifications and Data Sheets 1.2.6 Equipment Numbering 1.2.7 Load List 1.2.8 Generated Cable List 1.2.9 Schematic/Wiring Diagrams
1.3 Precommissioning and Commissioning 1.3.1 Precommissioning 1.3.2 Commissioning 1.3.3 Reliability Run 1.3.4 Power Plant Grid Tests 1.3.5 Commissioning Reports
1.4 Project Economics 1.4.1 Budget Estimate 1.4.2 Levelized Cost of Energy (LCOE) 1.4.3 Marginal Cost of Energy 1.4.4 Profitability of an Industrial Plant
1.1 Planning
The electrical power distribution systems have to be designed to fit the plant electrical requirements. The power systems must be well planned, considering the technological process, cost, reliability, maintenance, control, operating flexibility, and future growth. Furthermore, the undertaking must take into account the safety of people and equipment, continuity of power supply, installation, and operating costs.
Electrical engineers' responsibility is to prepare design criteria and single‐line diagrams, power system studies, calculate fault currents, locate load centers within the plant, estimate load diversity, select the grounding system, define the routes of overhead lines, prepare plant layouts, and develop the electrical protection system, all of it to suit the plant location and the prevailing standards. Furthermore, he/she must procure the equipment and participate in the plant construction and commissioning.
The basic concept for a single‐line diagram representing the power plant power distribution is generally established by the utilities. The main engineering effort is on implementing the power system around the generating units. Depending on the generator unit MW size, a decision will be made on having generator breakers next to the generators or employing high voltage (HV) breakers instead, in the switchyard to serve as the unit breakers for the generator/transformer groups. That is one of the most significant factors that define the overall concept of the diagram. The power plant station service generally uses less than 5% of power of the generator MW rating, thus, the one‐line diagram for a power plant is relatively simple in comparison to the industrial plants (see Chapter 18 for more details).
One‐line diagrams for industrial plants vary significantly from industry to industry. The load is fully distributed around the various operating activities, such as crushing, grinding, mixing, drying, pumping, batching, each of which requires a considerable engineering effort and decision making process to arrive at an optimal economic diagram that can be scaled and readily expanded in the future.
This book is written in 26 chapters to cover all the technical aspects of electrical engineering and to transfer practical experience onto young electrical engineers. In order to present it in a meaningful way, the book explains the technical details around a fictitious, though realistic power plant and industrial projects. An industrial project offers a greater variety of requirements and lends itself better for practical analysis.
This analysis can be applied to other plants that use similar electrical equipment, such as transformers, motors, generators, variable frequency drives (VFDs), cables, switchgear, overhead lines, fire protection, control systems, grounding, lighting, etc.
The project is commenced by an investor (company) who have decided to build a power or an industrial plant (cement factory, steel manufacturing, oil refinery, wood mill, plastic cups, fruit canning, etc.) on a particular location for a particular operating capacity (produced MW, tons of cement, tons of steel, tons of paper, tons fruit, etc.).
The investor company had already prepared a rough estimate proposal for a project with a simple budget estimate of ±40% accuracy and had received positive indications of financing from a bank to develop a feasibility study and a more detailed cost estimate. Figure 1.1 shows the steps of the project development.
Figure 1.1 Project development.
From the electrical power system perspective, the first step is to review the project flow diagrams produced by mechanical engineers and on that basis prepare electrical design criteria and develop a key one‐line diagram (see Chapter 2). The key one‐line diagram will envelop all the process facilities within the plant starting from the power source down to the individual equipment