Method of controlling a transformation process of charge material to a product
IPC분류정보
국가/구분
United States(US) Patent
등록
국제특허분류(IPC7판)
C10G-001/06
C10G-001/00
C10G-001/04
C09K-008/52
출원번호
US-0996421
(2009-05-07)
등록번호
US-8665437
(2014-03-04)
우선권정보
AT-A 921/2008 (2008-06-06)
국제출원번호
PCT/EP2009/055545
(2009-05-07)
§371/§102 date
20110207
(20110207)
국제공개번호
WO2009/146994
(2009-12-10)
발명자
/ 주소
Fischer, Harald
Mali, Heinrich Rochus
Schenk, Johannes Leopold
Schuster, Stefan
Spuida, Bernhard Hailu
Wieder, Kurt
Winter, Franz
출원인 / 주소
Siemens Vai Metals Technologies GmbH
대리인 / 주소
Ostrolenk Faber LLP
인용정보
피인용 횟수 :
0인용 특허 :
6
초록▼
A method for controlling a transformation process in which the conversion of charge materials to a product takes place along a transformation interface from the crystal and/or grain and/or phase and/or pore surface into the charge material, wherein one or more chemical elements in the charge materia
A method for controlling a transformation process in which the conversion of charge materials to a product takes place along a transformation interface from the crystal and/or grain and/or phase and/or pore surface into the charge material, wherein one or more chemical elements in the charge materials is released and/or incorporated and/or rearranged and wherein the conversion of the charge materials takes place along advancing transformation interfaces. The charge materials are identified on the basis of at least one optical, in particular microscopic, analysis with respect to their phases and/or phase components and/or their phase morphology, structure, texture and/or their chemical composition. On the basis of these variables, reference functions for the charge materials, which describe the conversion of the charge materials in the process, are assigned and used for establishing the process parameters of the transformation process.
대표청구항▼
1. A method for microscopic analysis of charge materials that are for a transformation process, wherein the transformation process is for producing metals and/or primary metallurgical products and/or intermediate metallurgical products from thecharge materials using process gases, the method compris
1. A method for microscopic analysis of charge materials that are for a transformation process, wherein the transformation process is for producing metals and/or primary metallurgical products and/or intermediate metallurgical products from thecharge materials using process gases, the method comprising; microscopically analyzing the charge materials with respect to their phases and/or phasecomponents and/or their phase morphology, structure, texture and/or their chemical composition; performing the microscopic analysis in one or more stages using unpolarized and/orpolarized electromagnetic waves and/or electron microscopy and performing the microscopicanalysis using polarized light which has a different direction or directions of polarization indifferent ones of the one or more stages; conducting the microscopic analysis for a single crystal, or a crystal cluster or a phase ofa charge material by determining distance dimensions relative to a surface of the single crystal,or the crystal cluster or a phase; and transforming the distance dimensions into a color-graded or a gray-scale image andcompiling intervals based on the distance dimensions into a model of concentric shells, whereinthe number of shells represents a measure of the duration of the transformation and the thicknessof the shells represents a measure of the rate of conversion of the charge material and the phasesthereof in the transformation process. 2. The method as claimed in claim 1, further comprising determining a crystal morphology and/or the phase morphology of the phases which phases are selected from the group consisting of surface area, circumference, circumferential shape, specific circumference, porosity, pore shape and number of pores; and storing the determined morphology in a databank in the form of phase parameters as a basis for industrial conversion in the transformation process. 3. The method as claimed in claim 1, wherein the transforming further comprises setting the thickness of each shell which is a measure of the transformation rate wherein the thickness setting is either constant, for simplified calculation, or becomes thinner with increasing distance from the surface and is dependent on the charge material and the transformation process, and the method further comprises determining the thickness of each shell in empirical tests. 4. The method as claimed in claim 1, further comprising assessing the suitability of a charge material or a mixture of charge materials for a transformation process on the basis of the microscopic analysis, and determining maximum permissible proportions for individual charge materials. 5. The method as claimed in claim 1, further comprising performing the microscopic analysis on the basis of single crystals and/or crystal aggregates of a mineral and/or at least one phase of the charge materials. 6. The method as claimed in claim 1, wherein the charge materials are selected from the group consisting of carbonaceous and silicaceous rocks, burnt lime, coals and/or cokes and/or ores, iron ores, and/or ore agglomerates, ore sinters or sintered ores, and/or intermediate metallurgical products, sponge iron, or mixtures of the materials. 7. A transformation process, comprising the method for microscopic analysis as claimed in claim 1, further comprising: controlling the transformation process by using the microscopic analysis for producing metals and/or primary metallurgical products and/or intermediate metallurgical products using process gases, andconverting the charge materials to a product takes place along at least one transformation interface from the crystal and/or grain and/or phase and/or pore surface into the charge material, wherein one or more chemical elements in the charge materials is released and/or incorporated and/or rearranged and the conversion of the charge materials takes place along advancing transformation interfaces. 8. The method is claimed in claim 1, comprising a further calculating step, with respect to the thickness for a number of thin shells that are to be put together to form a thicker shell. 9. The method is claimed in claim 1, wherein the electromagnetic waves are light waves.
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