GE Energy (formerly Chevron Texaco) Gasifier
Formerly known as ChevronTexaco and/or Texaco gasifiers (GE Energy acquired the technology in 2004), GE gasifiers have operated commercially for over 45 years using a wide variety of feedstocks such as natural gas, heavy oil, coal and petcoke. The coal gasification process was developed by extending experience with gas and oil gasification. Most of the earlier development work was conducted at a 15-ton-per-day (tpd) pilot plant at Montebello, California. This facility has since been relocated to China. GE Energy has a 6 tpd pilot plant at Aoio, Japan, currently operated by Ishikawajima-Harima Heavy Industries Corporation, Ltd (IHI). In addition, GE Energy continues to conduct gasification research and development (R&D) work at their various technology centers throughout the world. There are over 60 commercial plants currently in operation, making GE gasifiers one of the most widely used gasification technologies.
source: GE Energy
GE gasification uses a single-stage, downward-feed, entrained-flow refractory-lined reactor to produce synthesis gas (syngas) from a coal/water slurry (~ 65% in wt) and oxygen (> 95%). The slurried feedstock is pumped to a custom-designed injector mounted at the top of the gasifier. The coal reacts exothermically with oxygen at high temperature (~ 2,200 to 2,700°F) and pressure (>300 psi) to form syngas and slag. No hydrocarbon liquids are produced in these high temperature conditions. The syngas produced contains mostly hydrogen (H2) and carbon monoxide (CO).
The raw syngas leaving the gasifier can be cooled by a radiant and/or convective heat exchanger and/or by a direct quench system, where water or cool recycled gas is injected into the hot raw syngas. The radiant cooling design uses a soot-tolerant radiant syngas cooler that generates high-pressure steam. Slag is quenched in a water pool located at the bottom of the reactor vessel, and removed through a lock hopper. This design maximizes heat recovery as well as CO production. The syngas is further cooled after leaving the gasifier by a water scrubber to recover the fine particulate matter and char for recycle to the gasifier, before the gas is sent on to downstream processing.
A direct quench system uses an exit gas water quench. Hot gas exiting the gasifier is contacted directly with water via a quench ring; it is then immersed in water in the lower portion of the gasifier vessel. The cooled, saturated syngas is then sent to a scrubber for soot and particulate removal. The quench design is less efficient, but also less costly, and it is commonly used when a higher hydrogen to CO ratio syngas is required.
Radiant Cooling Operation Mode - the following block and simplified process flow diagrams demonstrate the operation of a GE Gasifier in radiant cooling mode.
Figure 1: Block Diagram of GE Radiant Cooling Mode
Figure 2: Diagram of GE Radiant Cooling Process
Quench Operation Mode - the following block and simplified process flow diagram demonstrate the operation of a GE Gasifier in quench mode.
Figure 3: Block Diagram of GE Quench Mode
Figure 4: Diagram of GE Quench Process
Demonstration and Early Commercialization
GE Energy has over 65 gasification facilities, with an additional 20 in engineering or construction phase. Examples include:
- Cool Water IGCC demonstration plant (1984-1992), California, U.S.
- Tampa Electric Polk River IGCC (250 MW) Plant, Florida, U.S.
- Eastman Chemicals coal-to-chemicals plant, Tennessee, U.S.
- Sarlux IGCC plant, Sardinia, Italy
- Api Energia IGCC plant, Falconara, Italy
- Several plants in China making ammonia and methanol
- CVR Energy