Direct reduction processes can be divided roughly into two categories: gas-based and coal-based. In both cases, the objective of the process is to remove the
oxygen contained in various forms of iron ore (sized ore, concentrates, pellets, mill scale, furnace dust, etc.) in order to convert the ore to metallic iron, without melting it (below ). The direct reduction process is comparatively energy efficient.
Steel made using DRI requires significantly less fuel, in that a traditional blast furnace is not needed. DRI is most commonly made into steel using
electric arc furnaces to take advantage of the heat produced by the DRI product.
Benefits Direct reduction processes were developed to overcome the difficulties of conventional
blast furnaces. DRI plants need not be part of an integrated steel plant, as is characteristic of blast furnaces. The initial capital investment and operating costs of direct reduction plants are lower than integrated steel plants and are more suitable for developing countries where supplies of high-grade
coking coal are limited, but where steel scrap is generally available for recycling. Many other countries use variants of the process. Factors that help make DRI economical: • Direct-reduced iron has about the same iron content as
pig iron, typically 90–94% total iron (depending on the quality of the raw ore), so it is an excellent feedstock for the electric furnaces used by
mini mills, allowing them to use lower grades of scrap for the rest of the charge or to produce higher grades of steel. • Hot-briquetted iron (HBI) is a compacted form of DRI designed for ease of shipping, handling, and storage. • Hot direct reduced iron (HDRI) is DRI that is transported hot, directly from the reduction furnace, into an electric arc furnace, thereby saving energy. • The direct reduction process uses pelletized iron ore or natural "lump" ore. One exception is the
fluidized-bed process, which requires sized iron ore particles. • The direct reduction process can use natural gas contaminated with inert gases, avoiding the need to remove these gases for other use. However, any inert gas contamination of the reducing gas lowers the effect (quality) of that gas stream and the
thermal efficiency of the process. The use of natural gas also produces greenhouse gases. • Supplies of powdered ore and raw natural gas are both available in areas such as
Northern Australia, avoiding transport costs for the gas. In most cases, the DRI plant is located near a natural gas source as it is more cost effective to ship the ore rather than the gas. • To
eliminate fossil fuel use in iron and steel making,
renewable hydrogen gas can be used in place of
syngas to produce DRI and eliminate production of greenhouse gases.
Complications Direct reduced iron is susceptible to
oxidation and
rusting if left unprotected, and is normally processed further to steel. The bulk iron can also catch fire (it is
pyrophoric). Unlike
blast furnace pig iron, which is almost pure metal, scrap-based DRI contains some
siliceous gangue, which needs to be removed in the steel-making process. == History ==