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The Claus process is a process, recovering elemental from gaseous mixtures containing , (H2S). First patented in 1883 by the chemist Carl Friedrich Claus, the Claus process remains the most important desulfurization process in the industry. It is standard at , natural gas processing plants, and or . In 2005, byproduct sulfur from hydrocarbon-processing facilities constituted the vast majority of the 64 teragrams of sulfur produced worldwide. Sulfur production report by the United States Geological Survey Discussion of recovered byproduct sulfur Der Claus-Prozess. Reich an Jahren und bedeutender denn je, Bernhard Schreiner, Chemie in Unserer Zeit 2008, Vol. 42, Issue 6, Pages 378–392.

The overall Claus process reaction is described by the following equation:

2 H2S + O2 → 2 S + 2 H2O
However, the process occurs in two steps:
2 H2S + 3 O2 → 2 SO2 + 2 H2O
4 H2S + 2 SO2 → 3 S2 + 4 H2O
Moreover, the input is usually a mixture of gases, containing , , or . The mixture may begin as raw , or output from physical and chemical gas treatment units (, , and amine scrubbers) when e.g. refining .
(1984). 9780824771508, Marcel Dekker, Inc..

Gases containing over 25% H2S are suitable for the recovery of sulfur in straight-through Claus plants. Gases with less than 25% H2S can be processed through alternate configurations such as a split flow, or feed and air preheating.Gas Processors Association Data Book, 10th Edition, Volume II, Section 22

History
The process was invented by Carl Friedrich Claus, a German chemist working in England. A British patent was issued to him in 1883. The process was later significantly modified by . Bibliographic Citation Sulfur Recovery Technology, B.G. Goar, American Institute of Chemical Engineers Spring National Meeting, , , April 6, 1986

Process description
A schematic process flow diagram of a basic 2+1-reactor (converter) SuperClaus unit is shown below: The Claus technology can be divided into two process steps, thermal and .

Thermal step
In the thermal step, hydrogen sulfide-laden gas burns in a substoichiometric at temperatures above 850 °C.Or between 950 and 1200 °C and even hotter near the flame, as stated in Der Claus-Prozess. Reich an Jahren und bedeutender denn je, Bernhard Schreiner, Chemie in Unserer Zeit 2008, Vol. 42, Issue 6, Pages 378–392. The process requires careful control of the fuel-air ratio. To ensure a stoichiometric Claus reaction in the catalytic step, only of the hydrogen sulfide (H2S) content should convert to SO2.

A Claus facility usually maintains several separate fires in lances surrounding a central to handle different gas sources. The concentration of H2S and other combustible components ( or ) then determine how the feed gas is burned.

Claus gases with no further combustible contents besides H2S (acid gas) burn in the lances by the following chemical reaction:

2 H2S + 3 O2 → 2 SO2 + 2 H2O       (Δ H = −518 kJ mol−1)
This is a strongly , free-flame of hydrogen sulfide, generating .

The central muffle itself burns gas mixtures containing ammonia (from a refinery's sour water stripper) or hydrocarbons. Sufficient air is injected into the muffle for the complete combustion of all hydrocarbons and ammonia, and the temperature is often maintained above 1050°C.Klint, B. "Hydrocarbon Destruction in the Claus SRU Reaction Furnace." Proceedings of the Laurance Reid Gas Conditioning Conference. 2000.Rahman, Ramees K., et al. "Reduction in natural gas consumption in sulfur recovery units through kinetic simulation using a detailed reaction mechanism." Industrial & Engineering Chemistry Research (2018). The high temperature destroys (Benzene, Toluene, Ethylbenzene and Xylene) mixtures, which otherwise would poison the downstream Claus catalyst.Rahman, Ramees K., Salisu Ibrahim, and Abhijeet Raj. "Oxidative destruction of monocyclic and polycyclic aromatic hydrocarbon (PAH) contaminants in sulfur recovery units." Chemical Engineering Science 155 (2016): 348–365.

To reduce the process gas volume or obtain higher combustion temperatures, the air requirement can also be covered by injecting oxygen. Several technologies utilizing oxygen enrichment are available in industry, but require a special burner in the reaction furnace.

The Claus reaction continues downstream, as more hydrogen sulfide () reacts with the , to produce gaseous, elemental sulfur:

2 H2S + SO2 → 3 S + 2 H2O      (Δ H = −1165.6 kJ mol−1)
The sulfur forms in the thermal phase as highly reactive S2 diradicals which combine exclusively to the S8 allotrope:
4 S2 → S8
Usually, 60 to 70% of the total amount of produced in the process is already present at the conclusion of the thermal process step.

Side reactions
Other chemical processes taking place in the thermal step of the Claus reaction are:
:2 H2S → S2 + 2 H2        (Δ H > 0)
: CH4 + 2 H2O → CO2 + 4 H2
: H2S + CO2 → S=C=O + H2O
: CH4 + 2 S2 → S=C=S + 2 H2S

Catalytic step
The waste stream from the thermal step is initially cooled to precipitate the sulfur, similar to the post-catalytic cooling discussed below. Further treatment with an activated or oxide then boosts the sulfur yield. One suggested mechanism is that S6 and S8 desorb from the catalyst's active sites with simultaneous formation of stable cyclic elemental sulfur.

Catalytic treatment is normally repeated a maximum of three times. Where an incineration or tail-gas treatment unit (TGTU) is added downstream of the Claus plant, only two catalytic stages are usually installed.

The catalytic recovery of sulfur consists of three substeps: heating, catalytic reaction and cooling plus condensation. Reheating the gas prevents sulfur condensation in the catalyst bed, which fouls the catalyst. Several industrial methods achieve the required bed operating temperature:

  • Hot-gas bypass: mixing in bypass gas direct from the waste-heat boiler.
  • Indirect steam reheaters: a consuming high-pressure steam.
  • Gas/gas exchangers: a heat exchanger cooling the hot gas from an upstream catalytic reactor.
  • Direct-fired heaters: fired reheaters burning acid gas or fuel gas substoichiometrically to prevent oxygen breakthrough

The typically recommended operating temperature of the first catalyst stage is 315 °C to 330 °C (bottom bed temperature). The high temperature hydrolyzes and , combustion byproducts that are otherwise inert during the modified Claus process. For subsequent stages, the catalytic conversion is maximized at lower temperatures, but care must be taken to remain above sulfur's . The operating temperatures of the subsequent catalytic stages are typically 240 °C for the second stage and 200 °C for the third stage (bottom bed temperatures).

After each catalytic pass, the process gas cools in the sulfur condenser to between 150 and 130 °C, whereupon the sulfur formed condenses. The waste heat and the condensation heat are captured as medium or low-pressure . The condensed sulfur is removed through a liquid outlet.

Before storage, liquid sulfur streams pass a degassing unit, which removes gases (primarily H2S) dissolved in the sulfur.

The tail gas from the Claus process still contains combustible components and sulfur compounds (H2S, H2 and CO). It either burns in an incineration unit or is further desulfurized in a downstream tail gas treatment unit.

Sub dew point Claus process
The conventional Claus process described above is limited in its conversion due to the reaction equilibrium being reached. Like all exothermic reactions, greater conversion can be achieved at lower temperatures, however as mentioned the Claus reactor must be operated above the sulfur dew point (120–150 °C) to avoid liquid sulfur physically deactivating the catalyst. To overcome this problem, the sub dew point Clauss reactors are oriented in parallel, with one operating and one spare. When one reactor has become saturated with adsorbed sulfur, the process flow is diverted to the standby reactor. The reactor is then regenerated by sending process gas that has been heated to 300–350 °C to vaporize the sulfur. This stream is sent to a condenser to recover the sulfur.

Process performance
Over 2.6 tons of steam will be generated for each ton of sulfur yield.

The physical properties of elemental sulfur obtained in the Claus process can differ from that obtained by other processes. In the Claus process, sulfur is usually transported as a liquid ( 115 °C). In elemental sulfur, increases rapidly at temperatures in excess of 160 °C due to the formation of polymeric sulfur chains.

Another anomaly is the of residual H2S in liquid sulfur as a function of temperature. Ordinarily, the solubility of a gas decreases with increasing temperature but H2S behaves inversely Solubility of Hydrogen Sulfide in Sulfur Rocco Fanelli. Industrial & Engineering Chemistry 1949 41 (9), 2031-2033 DOI: 10.1021/ie50477a047. This means that toxic and explosive H2S gas can build up in the headspace of any cooling liquid sulfur reservoir. The explanation for this anomaly is the endothermic reaction of sulfur with H2S to H2Sx.

Sulfur stockpile
Millions of tons of elemental sulfur are produced worldwide by the Claus process each year.

Owing to the high sulfur content of the Athabasca Oil Sands, stockpiles of elemental sulfur from this process now exist throughout , Canada.

(1982). 9780841207134

Another way of storing sulfur, while reusing it as a valuable material, is as a binder for concrete, the resulting product having many desirable properties (see ).

(2025). 9781604270051, J. Ross Publishing. .

See also

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