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Catalytic Reforming

Catalytic reforming is a major conversion process in petroleum refinery and petrochemical industries. The reforming process is a catalytic process which converts low octane naphthas into higher octane reformate products for gasoline blending and aromatic rich reformate for aromatic production. Basically, the process re-arranges or re-structures the hydrocarbon molecules in the naphtha feedstocks as well as breaking some of the molecules into smaller molecules. Naphtha feeds to catalytic reforming include heavy straight run naphtha. It transforms low octane naphtha into high-octane motor gasoline blending stock and aromatics rich in benzene, toluene, and xylene with hydrogen and liquefied petroleum gas as a byproduct. With the fast growing demand in aromatics and demand of high - octane numbers, catalytic reforming is likely to remain one of the most important unit processes in the petroleum and petrochemical industry. Various commercial catalytic reforming processes is given in Table M-VI 6.1. 

Table M-VI 6.1: Various Catalytic Reforming Processes

 

Process

Licensor

Rheniforming

Chevron oil

Power forming

ESSO Oil/EXXON

Magna forming

Altalntic Richfield oil

Ultra forming

British petroleum

Houdriforming

Houdry process

CCR Plateforming

UOP

Octanising

Axen

 

Octane Number of Hydrocarbons 

Octane number is a measurement of antiknock characteristics of fuels

  • Among the same carbon number compounds, the order of RONC is (Research Octane Number ) Paraffins < Naphthenes < Aromatics
  • Branched paraffins also have high octane. It increases with degree of branching. Therefore, octane number of naphtha can be improved by reforming the hydrocarbon molecule (Molecular rearrangement). Octane number of various hyrdrocarbons is mention in Table M-VI 6.2. Such rearrangement takes place in reforming reactors in presence of catalyst by way of numerous complex reactions. 

 Table M-VI 6.2: Octane Number of Various Hydrocarbons 

Hydrocarbon

Octane number

n-Butane

94.0

i-Butane

102.0

n-Pentane

61.8

i-Pentane

93.0

n-Heptane

 

octane

100.0

toluene

119.7

 
 
Feed consists of Heavy straight run gasoline (HSR), Naphtha, Heavy hydro cracker naphtha and Naphtha containing (C6-C11) chain paraffins, olefins, naphthenes & aromatics.
 
Process Steps In Catalytic Reforming 
 
Basic steps in catalytic reforming involve  
  • Feed preparation: Naphtha Hydrotreatment
  • Preheating: Temperature Control,
  • Catalytic Reforming and Catalyst Circulation and Regeneration in case of continuous reforming process  
  • Product separation: Removal of gases and Reformate by fractional Distillation
  • Separation of aromatics in case of Aromatic production

Naphtha Hydro Treatment 

Naphtha hydrotreatment is important steps in the catalytic reforming process for removal of the various catalyst poisons. It eliminates the impurities such as sulfur, nitrogen, halogens, oxygen, water, olefins, di olefins, arsenic and other metals presents in the naphtha feed stock to have longer life catalyst. Figure M-VI 6.1 illustrate hydrotreatment of naphtha.

  • Sulphur: Mercaptans, disulphide, thiophenes and poison the platinum catalyst. The sulphur content may be 500 ppm.
  • Maximum allowable sulphur content 0.5 ppm or less and water content <4 ppm.  
  • Fixed bed reactor containing a nickel molybdenum where both hydro de sulphurisation reactions and hydro de nitrification reactions take place.  
  • The catalyst is continuously regenerated. Liquid product from the reactor is then stripped to remove water and light hydrocarbons.  

Various sections in the naphtha hydro treatment unit are:

Charge Heater: Preheating reactor feedstock to reaction temperature of 340 oC. Charge heater has four passes four gas burners. Heater tubes are made up of SS-321  

Reaction Section: The reactor consists of two catalyst beds.

Stripping Section: Stripping section uses air for stripping the light ends mainly hydrogen sulfide from reactor product, stripper temperature 14 kg/ cmand temp. 172 0C

 Stripper Reboiler: Stripper reboiler supply heat required for striper  

Operating Variables Naphtha Hydrotreatmernt

  • Reactor temperature
  • Space velocity
  • Hydrogen partial pressure
  • H2/HC ratio, feed quality
  • Stripper bottom temperature 

Catalytic Reforming (Part - 1) | Chemical Technology - Chemical Engineering

Figure M-VI 6.1: Hydrotreatment of Naphtha

Classification of Processes 

  • Semi Regenerative catalytic reforming
  • Cyclic catalytic reforming
  • Continuous catalytic reforming(CCR) 

Various Types of Catalytic Reformers

Semi-Regenerative Fixed Bed reactors: In this type of reformers the catalyst generally has a life of one or more years between regeneration. The time between two regeneration is called a cycle. The catalyst retains its usefulness over multiple regeneration.

Cyclic Fixed Bed Reformers: Cyclic reformers run under more severe operating conditions for improved octane number and yields. Individual reactors are taken offline by a special valving and manifold system and regenerated while the other reformer unit continues to operate.

Continuous Reformers: In these reformers the catalyst is in moving bed and regenerated frequently. This allows operation at much lower pressure with a resulting higher product octane, C5+, and hydrogen yield. These types of reformers are radial flow and are either separated as in regenerative unit or stacked one above the other.

 Semi- regenerative Catalytic Reforming Process

A semi-regenerative process uses low platinum and regeneration is required only once a year. The process consists of typically three reactor beds & furnace preheaters. The dehydrogenation is highly endothermic and large temperature drop as the reaction proceeds. Multiple reactors with intermediate reheat is required. Dehydrogenation of naphthene takes place in first reactor and requires less catalyst. Preheat of feed is required. Last reactor for isomerization of paraffins. Typical catalyst distribution in three reactors are 20, 30 and 50percent. Figure M-VI 6.2 shows typical catalytic reforming process.

Catalyst Regeneration 

Performance of the catalyst decreases with respect to time due to deactivation. Reasons for deactivation  

  • Coke formation
  • Contamination on active sites
  • Agglomeration
  • Catalyst poisoning Activity could be restored if deactivation occurred because of coke formation or temporary poisons.

Objective of Regeneration

  • Surface area should be high
  • Metal Pt should be highly dispersed
  • Acidity must be at a proper level
  • Regeneration changes by the severity of the operating conditions
  • Coke formation can be offset for a time by increasing reaction temperatures. 

Catalytic Reforming (Part - 1) | Chemical Technology - Chemical Engineering

Figure M-VI 6.2: Catalytic Reforming Process

 Reactions in Catalytic Reforming 

Following are the most prevalent main reactions in catalytic reforming

Desirable

  • Dehydrogenation of naphthenes to aromatics
  • Isomerisation of paraffins and naphthenes
  • Dehydrocyclisation of paraffins to aromatics

Non-Desirable 

  • Hydrocracking of paraffins to lower molecular weight compounds

Dehydrogenation & Dehydrocyclization: Highly endothermic, cause decrease in temperatures, highest reaction rates, aromatics formed have high B.P so end point of gasoline rises Dehydrogenation reactions are very fast, about one order of magnitude faster than the other reactions. The reaction is promoted by the metallic function of catalyst  

Methyl cyclohexane → Toluene + H2

MCP→Benzene + H2

Dehydrocyclisation: It involves a dehydrogenation with a release of one hydrogen mole followed by a molecular rearrangement to form a naphthene and the subsequent dehydrogenation of the naphthene.

 i-paraffins to aromaticsof paraffins  

n-heptane à toluene + H2

Favourable Conditions: High temperature, Low pressure, Low space velocity, Low H2/HC ratio 

Isomerisation: Branched isomers increase octane rating, Small heat effect, Fairly rapid reactions. 

Favourable Conditions: High temperature, Low pressure, Low space velocity, H2/HC ratio no significant effect  

n-Hexane → Neo hexane

Naphthenes dehydro-Isomerisation: A ring re-arrangement reaction, Formed alkyl-cyclohexane dehydrogenate to aromatics." Octane increase is significant, Reaction is slightly exothermic 

Coking: Coking is very complex group of chemical reactions. Linked to heavy unsaturated products such as poly-nuclear aromatics. Traces of heavy olefines and di-olefines promote coking. High feed FBP favors coking. Poor feed distribution in the reactor promotes coking favored by high temperature

Hydrocracking: Exothermic reactions, slow reactions, consume hydrogen, produce light gases, Lead to coking, Causes are high paraffin conc feed

Favourable conditions: High temperature, High pressure

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FAQs on Catalytic Reforming (Part - 1) - Chemical Technology - Chemical Engineering

1. What is catalytic reforming and how does it work?
Ans. Catalytic reforming is a chemical process used in petroleum refineries to convert low-quality naphtha into high-octane gasoline and aromatic compounds. It involves the use of a catalyst, typically a platinum or rhenium catalyst, to rearrange the hydrocarbon molecules in the naphtha, producing a mixture of higher-octane hydrocarbons.
2. What are the main products obtained from catalytic reforming?
Ans. The main products obtained from catalytic reforming are high-octane gasoline and aromatic compounds. The high-octane gasoline produced is essential for meeting the increasing demand for cleaner-burning fuels with better performance. The aromatic compounds are used in various industries such as chemicals, plastics, and pharmaceuticals.
3. What are the advantages of catalytic reforming compared to other processes for gasoline production?
Ans. Catalytic reforming offers several advantages over other processes for gasoline production. Firstly, it can produce high-octane gasoline with excellent anti-knock properties, which is crucial for efficient and high-performance engines. Secondly, it allows the production of aromatic compounds, which have various industrial applications. Additionally, catalytic reforming is a flexible process that can utilize different feedstocks and adjust the product yield based on market demand.
4. What are the key factors influencing the performance of catalytic reforming?
Ans. The performance of catalytic reforming is influenced by several factors. The choice of catalyst plays a critical role, as it determines the selectivity and activity of the process. The operating conditions, such as temperature and pressure, also significantly impact the performance. The feedstock composition, particularly the content of sulfur and nitrogen compounds, can affect the catalyst's stability and activity. Lastly, the presence of impurities, such as metals or coke precursors, can deactivate the catalyst and reduce the process efficiency.
5. How does catalytic reforming contribute to the production of cleaner fuels and environmental sustainability?
Ans. Catalytic reforming contributes to the production of cleaner fuels and environmental sustainability in multiple ways. Firstly, it enables the production of high-octane gasoline, which reduces engine knock and allows for more efficient combustion, leading to lower emissions. Secondly, the process can convert low-quality naphtha into valuable products, reducing the need for crude oil extraction and minimizing environmental impact. Additionally, catalytic reforming can reduce the sulfur content in gasoline, helping to meet stringent fuel quality regulations and improving air quality.
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