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15.1 Introduction 

In industrial processes, hydrocarbons are contacted with H2O, depending upon the desired effect. When hydrocarbon vapors at very high pressures are contacted with water, water which has a very high latent heat of vaporization quenches the hydrocarbon vapors and transforms into steam. In such an operation, chemical transformations would not be dominant and energy lost from the hydrocarbons would be gained by water to generate steam. The quenching process refers to direct contact heat transfer operations and therefore has maximum energy transfer effeiciency. This is due to the fact that no heat transfer medium is used that would accompany heat losses. The steam cracking of hydrocarbons is an anti-quenching operation, and will involve the participation of water molecule in reactions in addition to teh cracking of the bnydriocarbond on their own. Since steam and the hydrocarbons react in the vapour phase the reaction products can be formed very fast. Therefore cracking of the hydrocarbons on their own as well as by steam in principle is very effective.  

When steam cracking is carried out, in addition to the energy supplied by the direct contact of steam with the hydrocarbons, steam also takes part in the reaction to produce wider choices of hydrocarbon distribution along with the generation of Hand CO.

  • Hydrocarbons such as Naphtha and LPG have lighter compounds.
  • When they are subjected to steam pyrolysis, then good number of petrochemicals can be produced.
  • These include primarily ethyelene and acetylene along with other compounds such as propylene, butadiene, aromatics (benzene, toluene and xylene) and heavy oil residues.
  • The reaction is of paramount importance to India as India petrochemical market is dominated by this single process.

15.2 Reaction

CxHy + H2O + O2→ C2H4 + C2H6 + C2H2 + H2 + CO + CO2 + CH4 + C3H6 + C3H8 + C4H10 + C4H8 + C6H6 + C+ Heavy oils 

  • The reaction is pretty complex as we produce about 10 to 12 compounds in one go
  • The flowsheet will be reaction-separation-recycle system only in its topology. But the separation system will be pretty complex.
  • Almost all basic principles of separation appears to be accommodated from a preliminary look.
  • Important separation tasks: Elimination of CO and CO2, Purification of all products such as ethylene, acetylene etc.-
  • The process can be easily understood if we follow the basic fundamental principles of process technology
  • Typical feed stocks are Naphtha & LPG
  • Reaction temperature is about 700 – 800 oC (Vapor phase reaction).

 15.3 Process technology (Figure 15.1)

Hydrocarbon Steam Cracking for Petrochemicals | Chemical Technology - Chemical Engineering

Figure 15.1 Flow sheet of Hydrocarbon Steam Cracking for Petrochemicals

  • Naphtha/LPG saturates is mixed with superheated steam and fed to a furnace fuel gas + fuel oil as fuels to generate heat.  The superheated steam is generated from the furnace itself using heat recovery boiler concept.
  • The C2-C4 saturates are fed to a separate furnace fed with fuel gas + fuel oil as fuels to generate heat.
  • In the furnace, apart from the steam cracking, steam is also generated. This is by using waste heat recovery concept where the combustion gases in the furnace.
  • After pyrolysis reaction, the products from the furnace are sent to another heat recovery steam boiler to cool the product streams (from about 700 – 800 oC) and generate steam from water.
  • After this operation, the product vapours enter a scrubber that is fed with gas oil as absorbent. The gas oil removes solids and heavy hydrocarbons.
  • Separate set of waste heat recovery boiler and scrubbers are used for the LPG furnace and Naphtha steam cracking furnaces
  • After scrubbing, both product gases from the scrubbers are mixed and fed to a compressor.  The compressor increases the system pressure to 35 atms.
  • The compressed vapour is fed to a phase separation that separates the feed into two stream namely the vapour phase stream and liquid phase stream. The vapour phase stream consists of H2, CO, CO2 C1-C3+ components in excess.  The liquid phase stream consists of C3 and C4 compounds in excess.
  • Subsequently, the vapour phase and liquid phase streams are subjected to separate processing.

Gas stream processing:

  • CO2 in the vapour phase stream is removed using NaOH scrubber.  Subsequently gas is dried to consist of only H2, CO, C1-C3 components only.  This stream is then sent to a demethanizer which separates tail gas (CO + H2 + CH4) from a mixture of C1-C3 components.  The C2-C3+ components enter a dethanizerwhich separates C2 from C3 components.
  • Here C2 components refer to all kinds of C2s namely ethylene, acetylene etc. Similarly, C3 the excess of propylene, and propane.
  • The C2 components then enter a C2 splitter which separates ethane from ethylene and acetylene.
  • The ethylene and acetylene gas mixture is fed to absorption unit which is fed with an extracting solvent (such as N-methylpyrrolidinone) to extract Acetylene from a mixture of acetylene and ethylene.
  • The extractant then goes to a stripper that generates acetylene by stripping. The regenerated solvent is fed back to the absorber.
  • The ethylene stream is fed to a topping and tailing still to obtain high purity ethylene and a mixture of ethylene and acetylene as the top and bottom products. The mixture of ethylene and acetylene is sent back to the C2 splitter unit as its composition matches to that of the C2 splitter feed.

Liquid stream processing

  • The liqiuid stream consists of C3,C4, aromatics and other heavy oil components is fed to a NaOH scrubber to remove CO2
  • Eventually it is fed to a pre-fractionator. The pre-fractionator separates lighter components from the heavy components.  The lighter components are mixed with the vapour phase stream and sent to the NaOH vapour phase scrubber unit.
  • The pre-fractionator bottom product is mixed with the deethanizer bottom product.
  • Eventually the liquid mixture enters a debutanizer that separates C3, C4 components from aromatics and fuel oil mixture.  The bottom product eventually enters a distillation tower that separates aromatics and fuel oil as top and bottom products respectively.
  • The top product then enters a depropanizer that separates C3s from C4 components.  
  • The C4 components then enter an extractive distillation unit that separates butane + butylenes from butadiene.  The extractive distillation unit consists of a distillation column coupled to a solvent stripper.  The solvent stripper produces butadiene and pure solvent which is sent to the distillation column.
  • The C3 components enter a C3 splitter that separates propylene from propane + butane mixture. Thesaturates mixture is recycled to the saturates cracking furnace as a feed stream.

15.4 Technical questions 

1. Why two separate furnaces are used for C2-C4 saturates and Naphtha feed stocks?

Ans: The purpose of steam cracking is to maximize ethylene and acetylene production. For this purpose if we mix C2-C4 saturates and naphtha and feed them to the same furnace, then we cannot maximize ethylene and acetylene production. The napntha steam cracker has its own operating conditions for maximizing ethylene and acetylene and so is the case for C2-C4 saturates.

2. Why the product gases from naphtha and C2-C4 saturates steam cracker processed separately before mixing them and sending them to the compressor?

Ans: Both crackers produce products with diverse compositions.  Both cannot be fed to a single scrubber and remove the heavy hydrocarbons and oil components.  While the scrubber associated to naphtha steam cracking needs to be remove significantly the oil and heavy hydrocarbons, this is not the case for steam cracker product vapour processing.

An alternate way of designing a single scrubber is to design a complex scrubber that has multiple feed entry points correspond to both product gases entering from various units.  This refers to process intensification and would be encouraging.

3. Why specifically the gases are compressed to 35 atm?

Ans: The distribution of light and heavy components in vapour and liquid streams is critically dependent on the pressure.  Therefore, the pressure of the system plays a critical role in the distribution of these key components.

4. Why is it  not possible to sharply split C3 components in the phase separator?

Ans: This is the basic problem of the phase equilibrium factors associated to the intermediate components.  Usually, phase equilibrium factors are highest for lighter components and lowest for the heavier components. But intermediate components such as C3s have phase equilibrium factors in between. Therefore, C3s get distributed between both vapour and liquid equally.  This will be the case even with higher pressure and going for higher pressure is not economical as the pressurizing costs will be significantly.

5. Why a tailing and topping still is required for ethylene production?

Ans: The distillation column for separating ethylene from ethylene from C2 components needs to carry out a difficult separation. This is also due to the fact that the boiling points of C2 components is very close. Therefore, there needs to be two columns (indicating good number of trays).

6. Explain how extractive distillation enables the separation of butadiene?

Ans: Dimethyl formamide (solvent) is fed to the distillation column fed with butadiene, butane and butylenes.  The solvent interacts differently with the components and therefore adjusts the relative volatility of the mixture which was close to 1 previously.  Thereby, the solvent forms a high boiling mixture at the bottom with butadiene and thereby enables the difficult separation of butadiene from the C4 compounds.  Thereby, the solvent + butadiene is fed to a stripper which removes butadiene from the DMF.  One important issue here is that the solvent does not form an azeotrope with the butadiene and is therefore, easy to separate.

7. When acetylene is not required, what process modifications will exist to the technology?

Ans: When acetylene is not required, then the top product from C2 splitter (which is a mixture of acetylene and ethylene) is fed to a packed bed column and H2 to convert the acetylene to ethylene. Eventually, one does not require the absorber-stripper technology for acetylene purification.

The document Hydrocarbon Steam Cracking for Petrochemicals | Chemical Technology - Chemical Engineering is a part of the Chemical Engineering Course Chemical Technology.
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FAQs on Hydrocarbon Steam Cracking for Petrochemicals - Chemical Technology - Chemical Engineering

1. What is hydrocarbon steam cracking in the petrochemical industry?
Ans. Hydrocarbon steam cracking is a process used in the petrochemical industry to break down long-chain hydrocarbons into smaller, more valuable molecules. It involves the use of high temperatures and steam to break the carbon-carbon bonds in hydrocarbon feedstocks, such as ethane or naphtha, resulting in the production of olefins like ethylene and propylene.
2. How does hydrocarbon steam cracking contribute to the production of petrochemicals?
Ans. Hydrocarbon steam cracking is a crucial step in the production of petrochemicals as it provides the primary source of olefins, which are the building blocks for various petrochemical products. Olefins like ethylene and propylene are essential for the manufacturing of plastics, rubber, solvents, detergents, and other industrial chemicals.
3. What are the main factors that influence the efficiency of hydrocarbon steam cracking?
Ans. Several factors affect the efficiency of hydrocarbon steam cracking. The main ones include the temperature of the cracking furnace, the residence time of the hydrocarbons in the furnace, the composition of the hydrocarbon feedstock, and the steam-to-hydrocarbon ratio. Optimizing these factors helps to maximize the yield of desired olefins and minimize unwanted byproducts.
4. What are the challenges associated with hydrocarbon steam cracking?
Ans. Hydrocarbon steam cracking faces challenges such as coke formation, which can lead to fouling and reduced heat transfer efficiency in the cracking furnace. Managing the high temperatures and pressures required for the process also requires robust materials and equipment. Additionally, the production of olefins through steam cracking contributes to greenhouse gas emissions, making environmental sustainability a significant challenge.
5. Are there any alternatives to hydrocarbon steam cracking for petrochemical production?
Ans. Yes, there are alternative methods for petrochemical production, such as catalytic cracking and advanced thermal cracking techniques. These methods aim to improve efficiency, reduce energy consumption, and minimize environmental impact. However, hydrocarbon steam cracking remains the most widely used and economically viable process for large-scale production of olefins in the petrochemical industry.
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