Lecture Notes Week 1 ChE 1008 Spring Term (03-2).

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Presentation transcript:

Lecture Notes Week 1 ChE 1008 Spring Term (03-2)

Lecture 1

Staged Separations

Equilibrium Staged Separations What do we mean by separations? What do we mean by equilibrium? What do we mean by staged? That is – what is this course about?

Overview of the Overview This course covers the basic “work horse” separation methods most commonly used in the chemical and petroleum industry Distillation Absorption Extraction It does not cover newer “advanced” separations methods: Adsorption (e.g., PSA) Note the difference: AB vs. AD Membrane separation Electrophoresis

Overview of the Overview You will also learn basic problem solving skills: 0. I want to and I can 1. Define the problem 2. Explore or think about it 3. Plan 4. Do it 5. Check 6. Generalize

Separations – Distillation

Staged Separations – Distillation

Staged Separations – McCabe-Thiele Method Chapter 2 Equilibrium Chapters 3 & 5 Flash & Feed Chapters 4 & 5 Mass Balances Chapters 5 & 6 Stage Solution

Separations – Distillation Design Chapters 7 & 9 Multicomponent Distillation Chapter 12 Design

Separations – Why Needed? Separations are employed in chemical plants where the separation of a mixture is required to obtain a relatively pure chemical species. Separations are usually closely integrated with other unit operations in the process flow, obtaining feeds from other unit operations and separating the desired product or providing the required product streams for feed to other units. The number of other unit operations is often small compared to the number of unit operations involving separations – it is often relatively easy to make something, but the subsequent separation of the desired component is often the most involved process!

Separations – Why Design? The first goal in separation design is to obtain the required products from the given feeds. The second goal is to minimize the cost of the equipment – that is design it such that it works, but also such that it is not oversized or undersized – thus, minimizing construction costs and problems. The third goal is to minimize operating costs since separations, such as distillation – the most common separation method – consume enormous amounts of energy, often up to 50% of a plant’s operating costs.

Mechanisms of Separation One takes advantage of differences in the chemical and physical properties of chemical species to enable their separation – these differences can involve their molecular, thermodynamic, and transport properties. If these differences are not significantly large at given conditions, one may increase the magnitude of these differences by altering the system conditions or by the addition of other species.

Separation via Thermodynamic Properties One of the most powerful differences that we can take advantage of for separation is the differences in the thermodynamic properties of different chemical species. The thermodynamic properties of the chemical species can be altered by changes in the system temperature and pressure, which often can be readily and relatively easily varied in a process.

What thermodynamic properties? The relative volatility of chemical species at a particular temperature and pressure is one of the most useful thermodynamic properties for separation. Volatility is the tendency of a chemical species to vaporize to a gas; thus, it is related to its boiling point. Most chemical species have a different volatility or boiling point than others.

Separations – Distillation

Vapor-Liquid Phase Separations If a mixture of components is allowed to separate into vapor and liquid phases, the more volatile component – the one with the lower boiling point – will tend to be more highly concentrated in the vapor phase. If we then separate the vapor from the liquid, we have increased the concentration of the component in the vapor phase with respect to the liquid phase. The separation of the vapor from the liquid is readily accomplished by their differences in density – a vapor phase comes of the top and the liquid phase off the bottom of the separator. It is that simple! Except that…

Equilibrium – The Determining Separation Factor The ultimate concentrations of the chemical species with respect to the phases are determined by thermodynamic equilibrium for a given set of conditions. Given the temperature, pressure, and concentrations of a mixture, we can use equilibrium relationships to determine the liquid and vapor phase concentrations of the chemical species as they separate. By assuming equilibrium in our separation designs, we can thus solve design problems.

Staged Separations Equilibrium is the determining factor as to what concentrations can be obtained in the liquid and vapor phases at a given set of conditions. Equilibrium behavior, and thus the concentrations in the liquid and vapor phases, can be changed by altering the conditions of the system – for example, the temperature and/or pressure. Multiple separations may be employed in series, each at different conditions, to take advantage of even slight differences in the equilibrium concentrations to ultimately obtain high levels of separation. Each separator can be thought of as an equilibrium “stage” in the overall separation. We can even combine these stages into an overall single separator, as we will see, for example, in distillation.

Separations – Distillation

So what is this course about? We will use equilibrium relationships to determine the vapor and liquid behavior of mixtures of chemical species as they separate. We will use this behavior in conjunction with mass and energy balances to solve separation problems. We will incorporate staged separations to achieve the desired level of separation. We will design separators using all of the above.

Separations – Design

End of Lecture 1