Название | Petroleum Refining Design and Applications Handbook |
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Автор произведения | A. Kayode Coker |
Жанр | Физика |
Серия | |
Издательство | Физика |
Год выпуска | 0 |
isbn | 9781119476450 |
Notes: 1. Temperatures in chart are maximum operating temperatures in degrees Fahrenheit for given thickness.
2. All hot insulated piping shall be coded, including piping insulated for personnel protection. Thickness is a function of insulation composition.
The process design engineer actually interprets the process into appropriate hardware (equipment) to accomplish the process requirements. Therefore, the engineer must be interested in and conversant with the layout of the plant; the relationship of equipment for maintenance; the safety relationships of equipment in the plant; the possibilities for fire and/or explosion; the possibilities for external fire on the equipment areas of the plant; the existence of hazardous conditions, including toxic materials and pollution, that could arise; and, in general the overall picture.
The engineer’s ability to recognize the interrelationships of the various engineering disciplines with the process requirements is essential to thorough design. For example, the recognition of metallurgy and certain metallurgical testing requirements as they relate to the corrosion in the process environment is absolutely necessary to obtain a reliable process design and equipment specification. An example of the importance of this is hydrogen brittlement (see latest charts [6]). Another important area is water service (see [7]). The engineer selecting the materials of construction should recognize the importance of plastics and plastic composites in the design of industrial equipment and appreciate that plastics often serve as better corrosive resistant materials than do metals.
14.4 Computer-Aided Flowsheeting
The term “flowsheeting” with computer application performs steady state heat and mass balancing, sizing, and costing calculations for a chemical process. There are many approaches to computer-aided flowsheeting, but the principal ones are sequential modular flowsheeting simulation and equation-based flowsheeting simulation. Figure 14.4 shows the partitioning of the design step into three basic steps: synthesis, analysis and optimization. The flowsheet structure is chosen from the synthesis where the particular equipment is being used and its interconnections are selected. The synthesis step allows one to set initial values for the variables. The second step is analysis, which is broken into three parts: involves solving the heat and material balances, sizing and costing the equipment and economic evaluation. The final steps are parameter and structural optimization. During analysis of a given flowsheet, some pertinent parameters such as temperature and pressure can adversely influence the resulting equipment sizes and invariably the flowsheet evaluation. Consequently, a decision is made to either alter the equipment and its interconnection because an improvement is required or to revise the present version of the flowsheet due to high cost. Structural optimization refers to changing the equipment type and its interconnection while parameter optimization deals with altering the temperature or pressure levels within a fixed flowsheet. The final flowsheet with its decision variable values and the resulting flowsheet illustrate the final design. Flowsheeting is the examination of a flowsheet of the process being examined together with the complete system characteristic. It does not include dimensions and structural design of the plants nor instrumentation and planning of the piping network system. Further steps in flowsheeting are described by Coker [9].
Figure 14.4 Partitioning the process design task into interrelated subtasks (source: Westerberg, et al. [8]).
14.5 Flowsheets—Types
The flowsheet is the “road-map” of a process, and serves to identify and focus the scope of the process for all interested and associated functions of the project. As a project progresses, the various engineering disciplines read their portions of responsibility from the flowsheet, although they may not understand the process or other details relative to some of the other phases of engineering. Here is where the process and/or project engineer serves to tie together these necessary segments of work. This often involves explanations sufficiently clear to enable these other groups to obtain a good picture of the objective and the problems associated with attaining it.
The flowsheet also describes the process to management as well as those concerned with preparing economic studies for process evaluation.
A good process flowsheet pictorially and graphically identifies the chemical process steps in proper sequence. It is done in such a manner and with sufficient detail to present to others a proper mechanical interpretation of the chemical requirements.
There are several types of flowsheets:
14.5.1 Block Diagram
This is usually used to set forth a preliminary or basic processing concept without details (Figure 14.5). The blocks do not describe how a given step will be achieved, but rather what is to be done. These are often used in survey studies to management, research summaries, process proposals for “packaged” steps, and to “talk-out” a processing idea.
14.5.2 Process Flowsheet or Flow Diagram
This is used to present the heat balance and material balances of a process (Figures 14.6a–14.6c). This may be in broad block form with specific key points delineated, or in more detailed form identifying essentially every flow, temperature and pressure for each basic piece of process equipment or processing step. This may