Alkylation | Chemical Technology - Chemical Engineering PDF Download

9.1 Introduction 

  • In this lecture we present a brief overview of the alkylation process.
  • In an alkylation process, olefins are reacted with isoparaffins to yield alkylate product.
  • The basic purpose of alkylation is to enhance the octane number of the feed stock.
  • For instance, octane number of butane alkylate is about 92 – 97. This is due to the formation of a hydrocarbon with side chain arrangement of carbon and hydrogen atoms.

9.2 Reaction Mechanism

  • There are three basic reaction steps to achieve alkylation
  • Step 1 involving Carbonium ion formation: In this reaction, alkene reacts with a proton (acid catalyst) to produce a proton substituted olefin. The proton substituted olefin reacts with isoparaffin to generate a reactive carbonium ion and alkane.

 

Alkylation | Chemical Technology - Chemical Engineering

 

Alkylation | Chemical Technology - Chemical Engineering

  • Step 2 involving carbonium ion intermediate formation: In this reaction, the carbonium ion formed in step 1 reacts with the olefin to produce an intermediate carbonium ion.

 

Alkylation | Chemical Technology - Chemical Engineering

  • Step 3 involving regeneration of carbonium ion: In this reaction, the intermediate carbonium ion reacts with the isoparaffin to produce alkylate product and carbonium ion. Thus carbonium ion is again regenerated to take part in step 2 reactions along with other additional unreacted olefin molecules.

Alkylation | Chemical Technology - Chemical Engineering

9.3 Reaction conditions

  • To avoid olefin polymerization, high isobutane to olefin ratios are used.
  • Typical isobutene to olefin ratios are 5:1 to 15:1
  • Acid catalysts are used. Primarily sulphuric acid (H2SO4) or HF are used.
  • Depending on the acid catalysts choosed the process complexity varies. We present both process technologies to indicate the pertinent process complexity.
  • Reaction operating temperature: 10 - 20 oC using H2SO4 and 25 – 40 oC using HF
  • Reaction temperature: 4.4 bar for H2SO4 and 7.8 bar for HF
  • When H2SO4 is used refrigeration is used.
  • When HF is used, refrigeration is not used.

9.4 Sulfuric acid based alkylation process technology (Figure 9.1) 

 

Alkylation | Chemical Technology - Chemical Engineering

Figure 9.1 Sulphuric Acid Alkylation Unit

  • Caustic wash: The feed mixture (olefin + C4 compounds) are first subjected to caustic wash. During caustic wash, sulphur compounds are removed and spent caustic is recycled back to the caustic wash. Fresh caustic solution is added to take care of the loss.
  • Refrigeration: The olefin feed enters a refrigeration unit to reduce the feedstock temperature.
  • Alkylation reactor: The reactor is arranged as a series of CSTRs with acid fed in the first CSTR and feed supplied to different CSTRs. This arrangement is for maximizing the conversion.
  • In the alkylation reactor it is important to note that the olefin is the limiting reactant and isoparaffin is the excess reactant.
  • The alkylator unit therefore will have two phases in due course of reaction namely the olefin + isoparaffin mixture which will be lighter and the alkylate stream which will be heavier and will be appearing as a bottom fraction if allowed to settle.
  • Since excess isoparaffin is used, the isoparaffin can be easily allowed as a bypass stream.
  • Eventually, the alkylate product from the last reactor will be taken out as a heavy stream.
  • Thus, the alkylation reactor produces two streams. These are (a) isoparaffin rich organic phase and (b) alkylate rich phase along with acid and isobutane phases.
  • These streams should be subjected to further purification.
  • Phase separator: It so happens that the acid enters the organic rich stream and will be subjected to phase separation by settling. Similarly, the olefin/isoparaffin mixture will be also separated by gravity settling. Thus the phase separator produces three streams namely (a) olefin + isoparaffin rich phase (b) acid rich stream (c) alkylate rich stream.
  • Olefin + Paraffin processing:The olefin + paraffin stream is first subjected to compression followed by cooling. When this stream is subjected to throttling and phase separation, then the olefin + paraffin rich stream will be generated. The propane rich stream from this stream is generated as another stream in the phase separator.
  • Propane defractionator: The propane rich stream after cooling is fed to a fractionator where propane is separated from the olefin+isoparaffin mixture. The olefin+isoparaffin mixture is sent back to mix with the olefin feed.
  • Caustic wash for alkylate rich stream: The caustic wash operation ensures to completely eliminate acid concentration from the alkylate.
  • Alkylate fractionation:The alkylate is fed to a distillation column that is supplied with isobutane feed and alkylate feeds to produce isobutane as a top product and alkylate + butane mixture as a bottom product.
  • Debutanizer: The debutanizer separates butane and alkylate using the concept of distillation 

9.5 HF process technology (Figure 9.2) 

 

Alkylation | Chemical Technology - Chemical Engineering

Figure 9.2 HF Alkylation Processes

  • The process is similar to the sulphuric acid plant. However, additional safety issues make the process complex.
  • The feed is first subjected to drying followed by pre-cooling.
  • After pre-cooling the reaction mixture, the reaction mixture is fed to a reactor.
  • Unlike CSTRs in series here impeller reactors are used. The reactor consists of cooling tubes to absorb the heat generated.
  • The reaction products enters a settler where oil and the HF are separated.
  • Since there can be traces of HF in the oil rich phase and vice-versa additional processing is followed.
  • The HF rerun column removes traces of oils from the bulk of the HF. Thus HF purified will be recycled back to the reactor. The bottom product thus generated in this unit is acid oils.
  • A HF stripper is used to remove the HF in lower quantities from the alkylate product. Eventually, the HF stripper produces HF that is sent back to the reactor and the alkylate product.
  • The alkylate product is sent to a deisobutanizer and depropanizer units. The final alkylate product is produced by using a deflourinator which is basically a caustic wash or adsorption unit. Finally n-butane + alkylate is produced as the bottom product

9.6 Technical questions

1. Why isobutane is fed to the deisobutanizer unit in the sulphuric acid flow sheet?

Ans: The isobutane feed consists of n-butane and it should be separated so that the alkylation reactor is fed with only isobutane. Now, the issue is to use a separate distillation column for separating isobutane feed into isobutane and butane. This will incur additional costs. Therefore, instead of two separate columns, both separations are carried out in the same distillation column. Ofcourse, costs will be saved by this concept in processing.

2. Explain how compression and cooling will enable the separation of propane and olefin+isoparaffins mixture? 

Ans: The separation of propane from isoparaffins and olefins is very difficult due to close boiling points of these streams. Now, compression is also required so as to avoid refrigeration system in the condenser of propane. This is also due to the fact that higher pressures increasing boiling point of the propane and enable the usage of cooling water in the condenser. On the other hand, removing heat from the system will enable adiabatic flash conditions which can be exploited to separate the propane and olefin+isoparaffin mixture.This entire operation has significant research in the field of thermodynamics and mass transfer subjects. Probably, good number of simulation studies have finally yielded the flowsheet to obtain such configurations.

3. What are the advantages of H2SO4 process when compared to the HF process? 

  • Additonal equipment is not need in this process. This is not the case in HF process where HF recovery or neutralization requires additional processes.
  • HF can form a toxic vapour cloud therefore, safety parameters need to be more effectively considered.
  • Higher capital costs in HF process - Good quality product is produced in sulphuric acid process but not the HF process.

4. Why is deisobutanizer placed before the depropanizer?

Ans: Isobutane is used in excess. If propane is removed first then both the columns have high flow rates. Since column costs are proportional to the flow rates, deisobutanizer is placed before depropoanizer so that the depropanizer can process less feed and hence have lower diameters and cost. 

5. What additional units are there in the HF process flow sheet when compared to the sulphuric acid flow sheet? 

a. Drier

b. Deflourinator

c. Safety instrumentation and accessories

The document Alkylation | Chemical Technology - Chemical Engineering is a part of the Chemical Engineering Course Chemical Technology.
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FAQs on Alkylation - Chemical Technology - Chemical Engineering

1. What is alkylation in chemical engineering?
Alkylation in chemical engineering refers to a process in which an alkyl group is added to a molecule. It involves the reaction of an alkylating agent, such as an olefin or an alkyl halide, with a reactive compound, often an aromatic hydrocarbon or an alcohol. This reaction is commonly used to produce gasoline additives, such as alkylate, which improve the octane rating and reduce the production of harmful emissions.
2. What are the main applications of alkylation in chemical engineering?
Alkylation has several important applications in chemical engineering. It is extensively used in the petroleum industry to produce high-octane gasoline additives, which enhance the performance of automotive engines. Alkylation is also employed in the production of detergents, pharmaceuticals, and other specialty chemicals. Additionally, it is used for the synthesis of alkylated aromatics, which are important in the production of plastics, solvents, and various industrial products.
3. What are the environmental considerations associated with alkylation processes?
Alkylation processes can have environmental implications. One significant concern is the potential formation of hazardous by-products, such as sulfuric acid, which is commonly used as a catalyst in alkylation reactions. Proper management and disposal of these by-products are essential to prevent pollution and minimize the environmental impact. Additionally, alkylation processes should be designed and operated to minimize the release of volatile organic compounds (VOCs) and other air pollutants, which can contribute to air pollution and climate change.
4. What are the challenges faced in alkylation processes?
Alkylation processes can present several challenges in chemical engineering. One challenge is the control of side reactions, which can lead to the formation of undesired by-products or the degradation of the desired product. This requires careful selection of catalysts, optimization of reaction conditions, and effective separation techniques. Another challenge is the management of heat transfer and mass transfer, as alkylation reactions are often exothermic and involve the handling of multiple reactants and products. Proper design and operation of equipment, such as reactors and heat exchangers, are crucial to ensure efficient and safe processes.
5. What are the advantages of alkylation in gasoline production compared to other methods?
Alkylation offers several advantages over other methods in gasoline production. One major advantage is the production of high-octane gasoline additives with excellent anti-knock properties. Alkylate, the product of alkylation, has a high octane rating and low vapor pressure, making it a valuable component for improving the quality of gasoline. Alkylation also enables the production of gasoline additives without the formation of significant amounts of undesirable by-products, such as aromatics and olefins, which can contribute to air pollution and engine deposits. Additionally, alkylation processes are generally more energy-efficient compared to other methods, leading to reduced energy consumption and lower greenhouse gas emissions.
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