XPlateTM (Xenogenic Plate) is the innovative fuel saving proven technology of over 10 years of intense research applied for the UK patent and international patent in 2009.
XplateTM is a device which is flexible to install at various process applications such as boilers, thermal power stations, cement kilns, ceramic kilns, spray dryers, steel plants, gasification units, or any industry that uses any fuel for combustion with oxygen. This proven technology has been used by many government and private organizations around the world.
XPlateTM performance was first officially proven in 2010 by the Coal Energy Technology Institute (CETI) of the National Academic of Science (NAS), Government of Ukraine. Several technical trials were later conducted in many countries in the world. At present, XPlateTM trademark has been registered in several countries by Madrid international trademark system of the World Intellectual Property Organization (WIPO) in Switzerland.
Technology Principle
When gaseous fluids such as air flow in any pipe, the molecules naturally move and interact, or hit each other on the side wall of pipe. The interactions that occur between the atoms of a molecule with the other atoms of the other molecule cause the attractive and repulsive forces to occur. These forces are known as intermolecular forces that cause the molecules to adhere together and form molecular clusters.
Clusters of these passing air molecules, O2 and N2, can be separated into single O2 and single N2 molecules by XPlateTM technology. As a result, O2 molecules will have more active molecular surface areas available for the complete combustion.
Award
The Best Technology Achievement Award by The Federation of Economic Development Association (FEDA) on July 30th, 2023 in Dubai, United Arab Emirates.
XplateTM for Boilers / Power Plants application
Various fuel types including NG, LPG, gasoline, diesel, HFO / bunker oil, coal, biomass are perfectly applicable with XPlateTM technology in boilers. Industrial applications range from the power plants, food and beverage factories, rubber and tire, textile, paper industry, etc. of those using boilers. XPlateTM technology can save fuel consumption, reduce emissions such as CO, CO2, NOx and SOx. Several companies have proven and issued their test certificates.
We can do NOx reduction for boiler power plants.
XplateTM for Ceramic Kiln / Spray dryer application
XplateTM technology is suitable for ceramic factory to benefit fuel saving for tile kilns, tunnel kilns, porcelain kilns, hot gas generation (HAG) and spray dryers. Several renowned ceramic companies have installed and certified XplateTM. XplateTM also helps to reduce the electricity consumption and the greenhouse gases (GHG).
XplateTM for Cement Rotary Kiln application
XplateTM technology has been verified at several cement plants in several countries. XPlateTM breaks the larger-size oxygen clusters into the smaller-size oxygen single molecules that subsequently speed up the oxygen molecular diffusion into the coal structural porous media. This technology can be used with either wet or dry process, and either with satellite coolers or pre-calciner type.
We can do NOx reduction for cement plants.
XplateTM for Steel Reheating Furnace application
XPlateTM technology directly improves combustion in the preheating, heating and soaking zones of the RHF. Various fuel types such as NG, LPG, bunker, etc. can be used.
XplateTM for Coal Gasification Process application
Chemical reactions of carbon, oxygen and steam in gasification process have great benefits by XPlateTM technology. The more freely-moving molecules of both oxygen and steam can react more effectively with the coal porous granules, enhancing more CO, H2 and CH4 concentrations in syngas. Typically the syngas calorific value increases by 1% with less coal consumption.
XplateTM for Glass Furnace application
Positive gas saving in a gas-fired glass furnace combustion by XPlateTM technology has been commercially proven in Thailand. Improvement can be seen at the regeneration ports that chemical reactions occur more intensively due to speed and greater collision possibilities of single oxygen molecules towards the completeness of oxidation.