TH280A - The process of reducing iron-containing substances directly in a rotary kiln - Google Patents

Abstract

Before iron oxide-containing substances are reduced in rotary kilns. By reacting with solid carbon reducing agents at lower temperatures The melting point of the inserted substance Iron oxide and carbon redundant substances are pre-heated in a multiplex-heart furnace. Where the reducing agent is at least incomplete coke or at least incomplete carbonization at low temperatures to prevent reducing and incomplete cleaning. Iron-containing substances Oxides are pre-heated in the upper part of the multiplex-heart furnace. And the solid carbon redoxin is pre-heated in the lower part of the mulitple-heart kiln, at least the part of the gas obtained by carbonization. At low temperature In the lower part of the multi-hart furnace, it flows upwards. In a contrary way with substances containing iron oxide to provide such upper heating as required

Claims (4)

1. Reduction process with iron oxide directly By reacting with a solid carbon reducing agent at a temperature below the melting point of the substance that is placed in the rotary kiln It consists of pre-heating of iron oxide and carbon redundant in a multiplex-heart furnace before being placed into a rotary kiln. And make the reducing agent in the multi-heart kiln at least to be Incomplete coke or at least incomplete carbonization at low temperatures. Which is characterized by that substances containing iron oxide Will be heated first in the upper part of the multiplex-heart furnace. In almost no reducing conditions, the solid carbon redundant is preheated in the lower part of the multi-heart furnace. And at least some of the low-temperature carbonization gases in the lower part were flowed upwards in a contrary to iron oxide-containing substances. 2. The process according to claim 1, where low-temperature carbonization gas flows into the upper part of the multiplex-heart furnace. And will be at least partly combustion during the process before or as it enters the top of the multiplex-heart furnace. 3. Clause 2, where at least most of the volatile and combustible components of the gas obtained by carbonization at low temperatures Will burn before or as it enters the top of the multiplexed-heart furnace. 4.Procedure according to claim 1, where the gas outlet temperature from the top of the multiplexed-heart furnace It was maintained above the gas combustion point temperature and the residual gas could be metabolized by air.