化工厂初步设计（英文）

化工厂初步设计（英文）


Preliminary Chemical Engineering Plant Design

WilliamD. Baasel
Professor of Chemical Engineering
Ohio University

Preface
The idea for this book was conceived while I was on a Ford Foundation residency
at the Dow Chemical Company in Midland, Michigan. I was assigned to the process
engineering department, where I was exposed to all areas of process engineering,
project engineering, and plant construction. My previous industrial experiences
had been in pilot plants and research laboratories. Much to my surprise, I found that
what was emphasized in the standard plant design texts was only a part of preliminary
process design. Such areas as writing a scope, site selection, equipment lists,
layout, instrumentation, and cost engineering were quickly glossed over. After I
returned to Ohio University and began to teach plant design, I decided a book that
emphasized preliminary process engineering was needed. This is the result. It takes
the reader step by step through the process engineering of a chemical plant, from the
choosing of a site through the preliminary economic evaluation.
So that the reader may fully understand the design process, chapters dealing with
planning techniques, optimization, and sophisticated computer programs are in-
. cluded. These are meant merely to give the reader an introduction to the topics. TO
discuss them thoroughly would require more space than is warranted in an introductory
design text. They (and other sophisticated techniques, like linear programming)
are not emphasized more because before these techniques can be applied a
large amount of information about the process must be known. When it is not
available, as is often the case, the engineer must go through the preliminary process
design manually before these newer techniques can be used. It is to this initial phase
of design that this book is directed.
Three types of design problems fit this situation. One is the design of a plant for a
totally new product. The second is the design of a new process for a product that
currently is being produced. The last is the preliminary design of a competitor’s
plant, to determine what his costs are. In each of these, little is known about the
process, so that a large amount of educated guessing must occur.
As time goes on, more and more people are being involved in these types of plant
design. Most chemical companies estimate that 50% of their profits 10 years hence
will come from products not currently known to their research laboratories. Since
these will compete with other products now on the market, there will be a great need
for improving present processes and estimating a rival’s financial status.
This book deals mainly with chemical plant design, as distinct from the design of
petroleum refineries. For the latter, large amounts of data have been accumulated,
and the procedures are very sophisticated. It is assumed that the reader has some
familiarity with material and energy balances. A background in unit operations and
thermodynamics would also be helpful, although it is not necessary. No attempt is
made to repeat the material presented in these courses.
This book applies a systems philosophy to the preliminary process design and
cost estimation of a plant. In doing so, it tries to keep in perspective all aspects of the
design. There is always a tendency on the part of designers to get involved in
specific details, and forget that their job is to produce a product of the desired
quality and quantity, at the lowest price, in a safe facility. What is not needed is a
technological masterpiece that is difficult to operate or costly to build.
For those using this book as a text, I suggest that a specific process be chosen.
Then, each week, one chapter should be read, and the principles applied to the
specific process selected. The energy balance and economic chapters may each
require two weeks. The pollution abatement chapter may be included after Chapter
8, or it can be studied as a separate topic unrelated to the over-all plant design.
Each student or group of students may work on a different process, or the whole
class may work on the same process. The advantage of the latter method is that the
whole class can meet weekly to discuss their results. This has worked very successfully
at Ohio University. In the discussion sections, the various groups present their
conclusions, and everyone, especially the instructor, benefits from the multitude of
varied and imaginative ideas.
Initially, this procedure poses a problem, since in most college courses there is a
right and a wrong answer, and the professor recognizes and rewards a correct
response. In designing a plant, many different answers may each be right. Which is
best often can be determined only by physically building more than one plant, and
evaluating each of them. Of course, no company would ever do this. It would build
the plant that appears to contain fewer risks, the one that seems to be best
economically, or some combination of these.
Since the student will build neither, and since the professor probably cannot
answer certain questions because of secrecy agreements or lack of knowledge, the
student must learn to live with uncertainty. He will also learn how to defend his own
views, and how to present material so as to obtain a favorable response from others.
These learning experiences, coupled with exposure to the process of design as
distinct from that of analysis and synthesis, are the major purposes of an introductory
design course.
Besides students, this book should be useful to those in industry who are not
intimately familiar with process engineering. Researchers should be interested in
process design because their projects are often killed on the basis of a process
engineering study. Administrators need to have an understanding of this because
they must decide whether to build a multi-million-dollar plant designed by a process
engineering team. Operating personnel should know this because they must run
plants designed by process engineers. Similarly, project engineers and contractors
need to understand process engineering because they must take the resultant plans
and implement them. Finally, pilot plant and semi-plant managers and operators
need to know the problems that can arise during process design because they often
must determine whether the various schemes devised by process designers are
feasible.
The importance of preliminary design cannot be underestimated. For every plant
built, 10 partially engineered plants are rejected. For some of these, over $100,000
worth of engineering will have been completed before the plant is rejected. Often
this loss could have been avoided if there had been a greater understanding of
preliminary chemical engineering process design by all concerned.
I wish to express my deep thanks to the Dow Chemical Company, particularly to
my preceptors Dr. Harold Graves and James Scovic, and everyone in the Process
Engineering Department. They were completely open with me, and showed me
how chemical engineering plant design is done. Also, I would like to thank all those
others at Dow who spent a lot of time educating me.
I would also like to acknowledge the support of the Chemical Engineering
Department at Ohio University, and especially its chairman, Dr. Calvin Baloun.
However, the group that had the greatest influence on the final form of this book
was the Ohio University Chemical Engineering seniors of 1970, 1971, 1972, 1973,
and 1974. They evaluated the material and suggested many improvements tha