Posts Tagged ‘H2S disposal’

SWAPSOL in Houston’s Sulphur 2011 Nov. 10 on H2S processing breakthrough

Wednesday, November 9th, 2011

Media Alert

SWAPSOL Corporation tomorrow will present its breakthrough sulfur recovery technology that can reduce hydrogen sulfide to below detectable levels and yield valuable products in a low temperature catalytic reaction.

Sulphur 2011 / Intercontinental Houston / Houston, TX
11:50am, Thursday, November 10th, 2011

Session: Stream A: Sulphur and Sulphides
Presenter: Wolf Koch, CEO / SWAPSOL Corp.

The SWAP: A breakthrough in hydrogen sulfide processing
SWAPSOL is developing commercial processes around a recently discovered chemical reaction, which reduces hydrogen sulfide (H2S) below detectable levels while reacting with carbon dioxide (CO2) to form water, sulfur and carsuls, a carbon-sulfur polymer. The SWAP stands to fundamentally simplify sulfur removal technology as it consumes carbon dioxide in an exothermic reaction under relatively mild process conditions. Alternatively, hydrogen sulfide may be reacted to form hydrogen and sulfur. The SWAP will have applications in landfill gas, sour gas, industrial flue gas cleanup, Claus tail gas cleanup and may serve as an alternative to Claus technology. A related process allows for the destruction of waste hydrocarbons by reacting them with sulfur to form hydrogen sulfide and carsuls.

The primary reactions and variants have been independently verified and the chemical kinetics determined by a third party laboratory. Swapsol has filed US and international patent applications covering all aspects of the technology. Laboratory scale development of the various Swapsol processes is nearing completion and the company is exploring opportunities for pilot plant development programs with potential partners.

For more information:

Evan Howell / evan.howell@swapsol.com

Tags: , , , , , , , , , ,
Posted in Uncategorized | No Comments »

SWAPSOL in Hydrocarbon Engineering Magazine on sour gas, landfill gas cleanup

Wednesday, October 12th, 2011

This month, editors at Hydrocarbon Engineering Magazine, Europe’s premiere refining trade publication, took a look at the SWAP’s application in cleaning sour gas which has potential for dramatic savings for refiners.  A new outside report shows the SWAP can beat costs of traditional methods (Claus) by as much as 70 percent.

In early 2011, an independent comprehensive process design and cost analysis was commissioned for the SWAP sour gas application, covering a design for a typical well and one for cleaning landfill gases. The outside contractor was chosen because of his renown expertise in sulfur recovery technology and process design.


“What is clear from the data is that the SWAP can provide cost advantages over competing processes, especially in view of the fact that thecompeting cost data needs to be inflated for a four year time period. Compared to the industry standard (the Claus process), the SWAP provides a cost advantage in excess of 40 % (after adjustments for inflation); the advanced SWAP process increases the potential advantage to 70%.”

To read the full article, please visit the PDF.

Tags: , , , , , , , , ,
Posted in Uncategorized | No Comments »

SWAPSOL SHARES LOW-COST LANDFILL GAS CLEANUP PROCESS DISCOVERY AT JANUARY EPA/LMOP CONFERENCE

Monday, January 17th, 2011

Operators given novel choice: Eliminate H2S and reduce CO2, or turn H2S into fuel

EATONTOWN, N.J. (Jan. 17, 2011) – SWAPSOL Corp. executives will be in Baltimore, Md., to explain how the Stenger-Wasas Process (SWAP) can give landfill operators a cost-effective solution to turn their sites into sources of clean, affordable power.  They will also discuss their latest research on directly converting hydrogen sulfide (H2S) into hydrogen (H2) for fuel. SWAPSOL will exhibit at the 14th Annual LMOP Conference and Project Expo at the Baltimore Hilton Jan. 18-20.

“Landfill gas cleanup may likely be the easiest application of the SWAP to implement quickly. This type of cleanup is expected to experience significant growth in the future as a renewable energy option,” said Wolf Koch, Ph.D., SWAPSOL director of planning and development. “Each landfill is normally a standalone application close to an urban location and requires little integration activities with existing processes.”

The SWAPSOL Sulfur Cycle

The SWAPSOL Sulfur Cycle

The SWAP
The SWAP is a suite of hydrocarbon (HC) processing applications independently verified to convert H2S with three possible reaction paths and may be applied to cleaning landfill, sour, flue, and other industrial gases. The process may be used to eliminate NOx, SOx, O3, CO, COS, and stoichiometrically reduce CO2 by using H2S. Alternatively, air may be used to react with H2S. Laboratory work has shown that the SWAP has the ability to also convert H2S into H2 for fuel. The SWAP reacts CO2 in the presence of H2S, forming water, sulfur, and carbon-sulfur polymers (carsuls). The alternate reactions produce sulfur and either water or hydrogen. The SWAP has been shown in the laboratory to eliminate H2S to below detectable limits.

No pre-separation required: Landfills early adopters
A variant of the SWAP has the ability to destroy most common HC wastes via a reaction with sulfur, producing additional H2S and carsuls. As landfills accept large quantities of construction and demolition (C&D) debris along with regular municipal solid waste (MSW), they generate increasing amounts of H2S. The SWAP eliminates the need for pre-separating the H2S, lowering operating costs for gas cleanup.

“We’re very excited about applying this technology in the waste management sector,” Koch said. “Not only can the SWAP clean landfill gas in ongoing operations, but operators may also use the technology to generate power from capped sites.”

Engineering & cost studies toward pilot construction
An independent engineering and comparative cost analysis is being completed to form the blueprint for pilot development. Work is underway to identify potential partners in establishing the first commercial landfill application in mid-2011. Koch said he hopes the successful demonstration will lead to the SWAP’s further implementation into the natural gas and coal-fired power generation industries.

“The SWAP is not a CO2 capture process, but a CO2 elimination process,” Koch said. “The SWAP vision is to enable carbon-emitters to profit by not polluting, to substantially lower their carbon penalties, and to earn carbon credits.”

(follow us on Twitter / Join our Linkedin group

Tags: , , , , , , , , , , ,
Posted in Uncategorized | No Comments »

Can sulfur recovery breakthroughs reduce our environmental footprint?

Saturday, August 22nd, 2009

There has been a recent discovery of a previously unknown exothermic reaction between CO2 and H2S.  It’s a reaction that may fundamentally alter the hydrocarbon industry.  Work continues.  It’s called the Stenger-Wasas Process (SWAP) developed by Ray Stenger and Jim Wasas.  And it may make obsolete traditional petroleum methods, such as the Claus Process and its variants.

The SWAP: Unrefined sour natural gas is fed into the catalytic reactor, where the SWAP reaction occurs between CO2 and H2S. Refined gas flows past the separator. CO2 and H2S are converted into water, sulfur and carbon in the collector. In a reaction that can start in less than one second at very moderate temperatures, the result of the SWAP is refined natural gas.

Brief Overview

Sulfur contaminants such as hydrogen sulfide (H2S), carbonyl sulfide (COS), and mercaptans in gas streams can create unacceptable levels of sulfur emissions in power applications or poison catalysts used in chemical synthesis. Sulfur contaminants are usually reduced to less than 300 ppm for power generation and considerably lower (<1 ppm) for the synthesis of methanol, ammonia, and Fischer-Tropsch (FT) liquids.

Sulfur recovery unit (courtesty: C&I)

Sulfur recovery unit (courtesy: C&I)

Sulfur Recovery Processes

Removing sulfur from a natural gas or syngas process stream is only part of the story. The residual sulfur present in an acid gas stream must then be recovered to prevent environmental and safety harms, as well as meet operator permit requirements. Two main technologies have traditionally been used commercially to recover sulfur: the Claus process (partial combustion) for high levels of sulfur, and catalytic Redox processes, for relatively low levels of sulfur. In recent years, bio-chemical based technology, the Thiopaq Process, has been developed and commercially implemented. Other recent developments include the development of hybrid processes that combine Claus and Redox technology and are used for tailgas cleanup in Claus plants.

The SWAP has been verified by gas chromatography in the laboratory to reduce H2S to below the limit of detection (about 4ppb) in a single pass through the SWAP column.

The SWAP in the laboratory

The SWAP in the laboratory

Classified as hazardous waste by the EPA, H2S disposal requires expensive processing, i.e. the Claus Process. The SWAP may reduce related capital costs for the H2S disposal resulting from crude oil desulfurization, while simultaneously eliminating substantial amounts of CO2.

CLAUS PROCESS

Technology Description

In the Claus process, a high H2S concentration stream is the feedstock for recovery to elemental sulfur. Roughly 1/3 of the H2S is burnt (partial combustion) to form sulfur dioxide (SO2). The remaining H2S reacts with the synthesized SO2 over an alumina or bauxite catalyst to produce elemental sulfur. Depending on their concentrations, the unreacted components (tail gas), such as residual SO2, CO2, and H2S, are either emitted, thermally oxidized, or further treated in an additional recovery process.

(US Environmental Protection Agency, AP42, 5th Edition, “Compilation of AirPollutant Emissions Factors Volume 1: Stationary Point and Area Sources, 1995) The Claus process is thermodynamically limited to ~97 percent sulfur recovery, although additional treatment steps, such as tail gas sulfur recovery, can increase the recovery rate.

Commercial Manufacturers and Applications

The Claus process is the oldest commercial sulfur treatment process, with development dating back to the late 19th century. Today, Claus processes are the main step used for elemental sulfur production worldwide-in fact, 90 percent to 95 percent of the sulfur recovered in the United States was from the Claus process. Almost 40 companies operate over 1000 Claus processes in the United States, recovering nearly 9 million tons per year of sulfur. The petroleum and natural gas industries are the main users of the technology, with IGCC applications making up a small but growing segment of the user population.

With catalytic refining, environmental footprint and operational costs can be lowered. This and other breakthroughs may change the landscape of hydrocarbon refining.  www.swapsol.com

Tags: , , , , , , , , ,
Posted in Uncategorized | No Comments »