CEFIC 1998 MSSCH

To become acquainted with the production of fuels, we visited the Czech Refineries (Česká rafinérská a.s.) enterprise in Kralupy nad Vltavou. It is a fuel refinery specialising in the production of engine fuels and heating oils. We visited the control centre and the very well equipped laboratories. During a second visit we paid most attention to the measurement of gasoline octane numbers. The enterprise heavily invests into new technologies. Since April 1997, a new unit for C₅, C₆ fraction isomerisation has been operating here. In the near future the construction will start of a fluid catalytic cracking (FCC) unit which should be finished in 2001. These investments are vitally important for the enterprise. The refinery processes about 32 million tonnes of oil annually. It is located next to the Kaučuk enterprise, which uses the C₄ fraction for the production of butadiene. The by-product of this production is butenes, which are used in the production of methyltert. butylether (MTBE). This compound is added (up to 10 %) to the gasolines produced in the refinery. The gasolines are currently produced in a catalytic reforming unit.

Starting material - crude oil

Crude oil began to be processed in the 19th century, approximately from 1820. The main product at that time was kerosene for lamps, later lubrication oils. Following the invention of gasoline engines, engine fuels became the most important products, to be gradually supplemented by heating oils. Today, about 25 % of oil production is processed to engine fuels and about 50 % to heating oils. Other products obtained from oil are asphalt, lubricating oils, paraffin, and gas fuels and petrochemical raw materials.

Oils from different location can considerably differ in their density, colour, types of hydrocarbons and the content of non-hydrocarbon compounds. The basis is formed by C₅-C₃₅ hydrocarbons (plus small amounts of higher hydrocarbons). Dissolved gaseous C₁-C₄ alkanes are also present. Some oils contain substantial proportions of so-called oil resins and asphaltenes (M_r = 2000 - 3000) which impart to oil its dark colour and are converted to the macromolecular aphalts during processing.

The Kralupy refinery is supplied by oil via two oil pipelines, one from Russia and the other (since 1995) from Ingoldstadt.

Oil processing at the Kralupy refinery

Crude oil contains a small proportion of emulsified water with dissolved salts. This fraction is removed by sedimentation after the addition of de-emulsifiers. The resulting oil is then preheated in a tube furnace and is injected into a large atmospheric-pressure column. Three fractions are drawn off from the upper part of the column, the distillation residue being mazut.

Fraction 1 - primary gasoline
Fraction 2 - kerosene
Fraction 3 - gas oil

All these fractions are conveyed to hydrogenation refining. The hydrogenation takes place at a pressure of about 3 MPa, the catalyst contains molybdenum and cobalt. The hydrogenation involves the following transfer reactions:

O ® H₂O

S ® H₂S

N ® NH₃

H₂S is washed with diethanolamine and further processed to sulphur. This sulphur is supplied to the near chemical enterprise Spolana Neratovice to be used for the production of H₂SO₄. Fraction 1 is redistilled into three fractions with boiling points up to 65 ^oC, up to 85 ^oC and up to 175 ^oC. The lightest C₅, C₆ fraction is then taken to low-temperature isomerisation. The isomerisation takes place at 120 - 150 ^oC, the catalyst being platinum on acid alumina (pH 0 -1). Another type of catalyst for this process is zeolites. Pentane is converted to isopentane, hexane to 2,2-dimethylbutane. The objective of the process is to enhance the octane number (ON).

Heavy gasoline (b.p. 100 - 200 ^oC) is taken to catalytic reforming. This process yields a high-octane gasoline from a low-octane one, and also hydrogen which is then used for hydrogenation refining. What reactions take place here?

The major reaction is hydrogenation (the process is thus endothermic) and isomerisation of alkanes to isoalkanes. The reactions take place at about 500 ^oC and a pressure of 1.5 MPa in the presence of a catalyst - a Pt - Rh system on acid alumina. An example of such a reaction is:

It is clear that this process yields large amounts of aromatics, which strongly increase the octane value. However, the current trend is directed towards lowering the content of aromatics, especially benzene.

The refinery now obtains gasoline from 20 % of the processed oil. The demand for gasolines rises and it is thus necessary to use the heavier, higher-boiling-point oil fractions. These higher hydrocarbons have to be cleaved or cracked to lower ones. This is achieved in a process called cracking. The oldest technology is thermal cracking (as early as after 1910) which is nowadays used only to a small extent. It affords low gasoline yields with low ON and low stability (in view of the alkene content).

A modern technology which is to be soon set up in the refinery is fluid catalytic cracking (FCC). This cracking takes place in a fluid bed at 510 ^oC, a pressure of 0.2 - 0.3 MPa, with zeolites as catalysts. Apart from gasoline, its important products are light C₃ - C₅ alkenes which can be used for alkylation or in the production of MTBE and TAME (tert. amylmethylether).

A promising technology, which is to be considered for future use, is alkylation. Isobutane from FCC could be alkylated by C₃ - C₅ alkenes. The alkylation would proceed at low temperatures (below 40 ^oC) and moderate pressures, 0.1 - 1 MPa, with strong acid acting as catalyst. The alkylation product - alkylate - has a high ON and low volatility. The near future is certain to see the advent of so-called reformulated gasolines, i.e. gasolines which meet the strictest demands for emission production - low volatility, low content of aromatics, especially benzene, very low sulphur content and the presence of oxygen-containing components (the presence of oxygen in the fuel contributes to better combustion but the energy content of the fuel is somewhat lower). The oxygen-containing components are mostly ethers - MTBE, TAME.

All components available at the refinery form the so-called gasoline pool.
They include:

primary gasolines
reformate
isomerate
MTBE

An indispensable part is additives:
These include:

detergents and dispersants (prevention of the formation of deposits in the combustion space) - both low- and high-molecular derivatives of organic acids, phenolics, alcohols, amines and sulpho acids
anti-knock additives (tetraethyl lead Pb(C₂H₅)₄, tetramethyl lead) - replacements of lead compounds, e.g. ferrocene and others, are not yet equally effective
anticorrosives - low-molecular derivatives of organic acids, amines, phenols
antioxidants - derivatives of phenols, aromatic amines

Other products of the refinery are Diesel oil and aircraft gasoline.

Diesel oil is used as fuel for compression-ignition engines. It is basically a mixture of fraction 2 and fraction 3(b.p.170 - 370^oC) from primary oil distillation (C₁₂ - C₁₈) and a gas oil (C₁₅ - C₂₄). With this fuel, the demands for fuel processing are substantially lower, and involve mostly removal of sulphur. Fuel combustion occurs at higher temperatures and the composition of emissions is therefore different from that in spark-ignition engines. In terms of demands for fuel quality and of emissions, compression-ignition engines thus appear to be more advantageous that spark-ignition ones, but they are much more robust and expensive in view of the high working pressures.

The refinery supplies oils to the Prague Ruzyně airport. Aircraft gasoline is a fraction with boiling points in the range 150 - 280 ^oC. It has to be processed so that its viscosity at low temperatures would not be too high. It must not solidify up to -60 ^oC.

Alternative fuels Among fossil fuels, propane-butane mixture is the main alternative fuel, with natural gas showing promise. A typical composition of natural gas is 93 % CH₄, 3 % C₂H₆, 1 % higher HC, 3 % N₂, 0.3 % CO₂. Natural gas can be used either compressed (compressed natural gas – CNG) or liquefied – LNG. Current practice makes use preferentially of CNG of about 20 MPa pressure. The compression consumes up to 5 % of the energy content of the gas. For the time being, natural gas is used relatively little as fuel but its consumption will increase. A large-scale manufacture of cars using natural gas as fuel is planned after 2000. Gas is a very pure fuel; its mixture with air entering the engine combustion space is completely homogeneous and the combustion can therefore be better. Emissions of HC, CO and solid particles are very low. CO₂ emissions are also lower in view of the relatively high hydrogen content. Methane has a high octane number – 130, which permits the use of higher compression ratios and thereby the attainment of a higher efficiency.

Fuels produced from renewable resources, e.g. ethanol produced by fermentation, offer other possibilities. The so-called bio-gasoline contains methyl esters of higher fatty acids. They are produced from lower-quality plant oils.

A promising way is the use of hydrogen, which can be produced by different methods - electrolytically and chemically - from water and can be transported in a liquefied form or dissolved in metal alloys. Its advantages as a car fuel are:

a higher amount of energy released per weight unit of fuel - high heat of H₂ combustion
absence of harmful emissions except for a small quantity of NO_x

Energetic aspects of fuel use Combustion engines are heat machines in which chemical energy is converted to heat, and only then the hot combustion gases perform work. The efficiency of these machines is therefore in principle limited by the second law of thermodynamics, and is determined mainly by the difference of temperatures in the engine working space and in the environment.

T_2, T₁are thermodynamic temperatures, h _max is the efficiency in the case of reversibly occurring partial processes in the working cycle of the machine. However, the actual efficiency of combustion engines is much lower because the processes taking place within the engines are not reversible (in compression-ignition engines it is about 35%, in spark-ignition ones about 30 -32%). A considerable amount of energy is converted into waste heat, which is transferred into the environment. This heat represents a factor of environmental deterioration (thermal pollution) because it contributes to disrupting the heat equilibrium between the Earth and its environment.

For this reason, better alternative energy sources would be fuel cells in which a direct conversion of chemical energy to work takes place. Hence, their efficiency is not limited by the second law of thermodynamics and is about twice as high as in combustion engines (about 70 %). The best known is probably the hydrogen-oxygen cell, which may have, for instance, the following arrangement:

Ni (porous C) | KOH (aq) | NiO (porous C) anode cathode

Anode - oxidation: 2 H₂(g) + 4 OH^-(aq) ® 4 H₂O (l) + 4 e^-
Cathode - reduction: O₂ (g) + 2 H₂O (l) + 4 e^- ® 4 OH^- (aq)

The overall reaction is the sum of partial electrode reactions: 2H₂(g) + O₂ (g) ® 2 H₂O (l).

Hydrogen is continuously fed to the anode while oxygen is brought to the cathode. The KOH solution is kept hot, water vapour escapes from the electrode space. Ni and NiO function as electro-catalysts. Other fuel cells have been developed which are capable of "burning" hydrocarbons in the cold. For instance, the propane-oxygen cell:

Anode: C₃H₈ (g) + 6 H₂O (g) ® 3 CO₂(g) + 20 H⁺ (aq) + 20 e^-
Cathode: 5 O₂(g) + 20 H⁺ (aq) + 20 e^- ® 10 H₂O (l)

Overall reaction: C₃H₈(g) + 5 O₂ (g) ® 3 CO₂(g) + 4 H₂O(l)

In contrast to storage batteries, fuel cells cannot store energy. The reactants have to be continuously supplied and the products continuously removed. Fuel cells do not produce waste heat, vibrations, noise, and toxic substances. Despite these merits, they are not used to a large extent. The main problem is the selection of suitable electro-catalysts, which would exhibit long-term resistance to contamination and corrosion.

A very promising energy source is the system illustrated in the figure. It is basically a combination of a galvanic and a fuel cell.

Very high-purity aluminium (>99.99 %) is usedas anode. The cathode is made ofan inert porous material, which is usedto bring air into a NaOH or NaCl solution. The overall reaction, taking place in the cell, is:

₂

₃

As seen from the equation, aluminium and water are consumed and Al(OH)₃ is produced. Charging of the cell thus consists in a mere replenishment of water, replacement of the aluminium electrode and removal of product precipitate. The cell attains a voltage of up to 2.7 V. Its properties make it ideal for use in electromobiles.

Electromobiles are certain to experience widespread use in the future, albeit for shorter cruises at lower speeds. On a mass scale, however, the transports will still use gasoline and Diesel oil. The American companies Ford and Chrysler have developed a hybrid automobile equipped with storage batteries and electric engine and, in addition, a small combustion engine. This automobile should reach a speed of up to 160 km.h^-1 at a presumed fuel consumption of 2.6 l/100 km.