ISO/TR 25088

ISO/TR DTR 25088:####(X)
ISO /TC 17/SC 21
Secretariat: JISC
Date: 2025-07-01
ApplicationGuidance for the application of low-carbon
technologies in steel plants
DTR stage
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Lignes directrices pour l'application des technologies à faible teneur en carbone dans les usines sidérurgiques
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ISO/DTR 25088:(en)
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iii
ISO/DTR 25088:(en)
Contents
Foreword . v
Introduction . vii
1 Scope . 1
2 Normative references . 1
3 Terms and definitions . 1
4 Technology classification . 2
5 Technical properties . 4
Bibliography . 29

iv
ISO/DTR 25088:(en)
Foreword
Foreword . 3
Introduction . 4
1 Scope . 5
2 Normative references . 5
3 Terms and definitions . 5
4 Technology classification . 5
4.1 Overview . 5
4.2 Breakthrough in smelting process . 6
4.3 Process optimization and innovation . 6
4.4 Resources recycling . 7
4.5 CO capture and utilization (CCU) . 7
5 Technical properties . 7
5.1 Overview of the technical properties . 7
5.2 Smelting process breakthroughs . 9
5.3 Process optimization and innovation . 13
5.4 Resource recycling . 16
5.5 CO capture and utilization. 19
Bibliography . 24

v
ISO/DTR 25088:(en)
FOREWORD
ISO (the International Organization for Standardization) is a worldwide federation of national standards
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of the ISO/IEC Directives, Part 2 (see www.iso.org/directives).
Attention is drawnISO draws attention to the possibility that some of the elementsimplementation of this
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This document was prepared by Technical Committee ISO/TC 17, Steel, Subcommittee SC 21, Environment
related to climate change in the iron and steel industry.
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vi
ISO/DTR 25088:(en)
Introduction
With the intensification of global actions to address climate change, the iron and steel industry is facing
unprecedented pressure and challenges. It needs to achieve low-carbon transformation through technological
innovation and industrial upgrading.
Currently, several leading steel enterprises around the world have formulated low-carbon development
roadmaps, but the majority of steel companies are still in the exploratory phase. The application of low-carbon
technologies is a key pathway for the green transformation of the steel industry. In recent years, a large
number of low-carbon technologies have emerged within the industry. However, how to identify which low-
carbon technologies have significant carbon reduction effects and whether they are suitable for enterprise
application remains an urgent issue to be resolved.
Low-carbon technologies include, but are not limited to, energy efficiency improvements, the use of
alternative energy sources, carbon capture and utilization technologies, and the promotion of circular
economy models. Nevertheless, due to the lack of unified guidelines, there are differences in the selection and
application of low-carbon technologies among countries and enterprises, which not only affects the efficiency
of technology promotion but also increases the transformation costs for enterprises.
This document is formulated for the purpose of promoting the low-carbon development of the global iron and
steel industry, establishing and improving the low-carbon technology system, and driving technological
progress of the iron and steel industry.
This document stands in the global perspective, based on the current technology development and application
status, to sort out the low-carbon technology of the iron and steel industry. It encompasses processes such as
sintering, pelletizing, coking, ironmaking, steelmaking, continuous casting, rolling and other auxiliary
processes. Moreover, this document puts forward the specific technology application guidance from the
aspects of smelting process breakthroughs, resource recycling, process optimization and innovation, and CO
capture and utilization, etc. which can be used as the reference technical information for the low-carbon
development of the iron and steel industry.
Smelting process breakthroughs mainly focus on the transformative innovation in key technologies which
deviates from the constraints of traditional processes and equipment, including low-carbon blast furnace
ironmaking technology, hydrogen-based direct reduction technology, etc. Resource recycling technologies
provide the way to utilize secondary resources such as solid, liquid, and gas phase wastes generated from the
iron and steel production process by efficient recycling. Process optimization and innovation introduces the
way and technologies for innovating steel manufacturing processes and improving process efficiency by
adjusting and optimizing the process and the proportion of raw material structure and energy consumption
based on traditional processes and equipment. CO capture and utilization gives the method and application
of separating CO from the emission sources of steel manufacturing and reducing CO emissions into the
2 2
atmosphere through effective solidification, or resource utilization.
This document will help steel enterprises choose low-carbon technologies that are suitable for their own
conditions and future development trends. It will promote the global application of advanced green and low-
carbon technologies and hold significant importance for the green and low-carbon development of the global
steel industry. Due to the continuous innovation in technology, this document will also undergo regular
revisions to provide the most up-to-date guidance.
Note 1 to entry: EconomicIt is expected that economic aspects shall beare taken into account for the respective
technology.
Identification of patent holders, if any.

vii
ISO/DTR 25088:(en)
Application
viii
TECHNICAL REPORT ISO/TR 25088:202X(E)

Guidance for the application of low-carbon technologies in steel plants
1 Scope
This document provides an overview of low-carbon technologies for the entire production process of the iron
and steel industry, sets application in sintering, pelletizing, coking, ironmaking, steelmaking, continuous
casting, rolling and other production processes.
Note1: NOTE Low-carbon technologies in the iron and steel industry are constantly evolving. This document describes
processes in different stages of maturity. There is heterogeneity in the decarbonization pathways among the steel
enterprises. Therefore, not all low-carbon technologies covered in this technical reportdocument are equally applicable
to all steel plants. Low-carbon technologies in the iron and steel industry are not limited to those listed in this technical
report, and this technical report needs todocument. This document will be revised as appropriate as technologies evolve.
2 Normative references
There are no normative references in this document.
3 Terms and definitions
For the purposes of this document, the following terms and definitions apply.
ISO and IEC maintain terminology databases for use in standardization at the following addresses:
— — ISO Online browsing platform: available at https://www.iso.org/obphttps://www.iso.org/obp
— — IEC Electropedia: available at https://www.electropedia.org/https://www.electropedia.org/
3.1 3.1
low-carbon technology
technologies that reduce net greenhouse gas emissions excluding virtual emission reductions using carbon
credits when applied.
Note 1 to entry: Low-carbon technologies include BAT (Best Available Technologies), described in national / regional
BAT documents, as well as innovative technologies.
3.2 3.2
low-carbon electricity
electricity generated from low-carbon energy sources (including but not limited to solar energy, wind power,
biomass energy, geothermal energy, hydropower, nuclear power) with significantly lower emissions of
greenhouse gases than fossil fuel-based generation.
ISO/TR XXXX:202X(E)
DTR 25088:(en)
Note 1 to entry: The term "fossil free electricity" is often used for the same type of electricity.
4 Technology classification
4.1 Overview
The classification of technologies includes four main categories: smelting process breakthroughs, resource
recycling, process optimization and innovation, and CO capture and utilization.
Smelting process breakthroughs mainly focus on the transformative innovation in key technologies which
deviates from the constraints of traditional processes and equipment, including low-carbon blast furnace
ironmaking technology, hydrogen-based direct reduction technology, etc.
Resource recycling technologies provide the way to utilize secondary resources such as solid, liquid, and gas
phase wastes generated from the iron and steel production process by efficient recycling.
Process optimization and innovation introduce the way and technologies for innovating steel manufacturing
processes and improving process efficiency by adjusting and optimizing the process, the raw materials and
their proportions, and the energy mix based on traditional processes and equipment.
CO capture and utilization gives the method and application of separating CO from the emission sources of
2 2
steel manufacturing and reducing CO emissions into the atmosphere through effective solidification, or
resource utilization.
When giving properties of the low-carbon technologies, including technical sophistication, feasibility,
technology maturity, and application conditions, this proposal is based on existing research and application
situations. It is expected that such characteristics will evolve over time, and this document will require updates
accordingly.
4.2 Breakthrough in smelting process
The breakthrough in smelting process is to deviatedeviates from the constraints of traditional process
equipment, with the goal of significantly reducing fossil carbon, and seek transformative innovation in key
technologies, achieving a breakthrough in the original smelting process towards low-carbon smelting.
Breakthroughs in smelting process focus on:
— — developdeveloping melting reduction technologies, such as plasma smelting to achieve low-carbon
smelting, focusing on the research and promotion of blast furnace hydrogen-rich and gas de-carbonization
cycles, hydrogen-rich direct reduction, and biomass smelting;
2 © ISO 2022 – All rights reserved

ISO/TRDTR 25088:202X(E:(en)
— — exploreexploring new technologies for direct reduction of hydrogen-rich gas or pure hydrogen in iron-
making and establish a new DRI-EAF/SAF process route; Paypaying attention to the reduction of carbon
emissions from steelmaking itself, continuecontinuing to develop the high-efficiency multi-energy supply
technology based on low-carbon electricity, the low-carbon clean melting technology of all scrap, DRI less
slag steelmaking and biomass carbon slag foaming technology, etc., and formforming a new process of
Near-zero CO emission electric arc furnace steelmaking to achieve near-zero carbon melting process;.
Any new electrical melting processes require minimized electrical net perturbations.;
— — actively tracktracking new smelting processes such as alkaline solution electrolysis and molten oxide
electrolysis that replace carbon with low-carbon electricity, completely breaking through the process
route of iron-making and steel-making, and achieving low-carbon smelting.
4.3 Process optimization and innovation
Process optimization and innovation is based on existing processes and equipment, by optimizing the
proportion of raw materials and energy, the process of steel production, innovating the steel manufacturing
process, improving the efficiency of the process, and significantly reducing CO emissions. Process
optimization and innovation focus on:
— — optimizeoptimizing traditional process flow and reduce process energy consumption, such as low-
carbon smelting technology for optimizing the proportion of raw materials and fuels, intelligent control
technology for electric furnace steel-making, etc., to achieve carbon reduction;
— — actively layout and increaseincreasing the substitution of fossil energy by renewable and clean energy
sources such as solar energy, wind energy, achieving a combination of self-generation, and self-supply
with enterprises, and continuously increasing the proportion of non-fossil energy use in production
processes, such as heating, smelting, and transportation;
— — breakbreaking traditional process flow, adopting technologies such as near net shape fully continuous
rolling (such as ESP), endless rolling, TMCP temperature controlled rolling, etc., further breaking through
core rolling technologies such as homogenization solidification and efficient rolling forming, achieving
simplicity and compactness of iron and steel casting and rolling, reducing repeated heating and forming.
4.4 Resources recycling
Resource recycling refers to the efficient reuse of solid waste, wastewater, flue gas and other resources
generated in the steel production process, through the recycling in steel or other related industries, to achieve
maximum resource value and promote pollution and carbon reduction in the iron and steel industry and the
entire society. Resource recycling focus on:
— —centercentring on steel production, involveinvolving the orderly coordination and integration of
multiple industrial chains, including steel, petrochemicals, building materials, and chemical industries;
— — strengthenstrengthening the research, promotion, and application of technologies for the recycling and
utilizing recyclable resources like scrap, slag, and other solid wastes. Through technological innovations
in scrap identification, sorting, and processing, and in steel slag separation, modification, stabilization,
processing and reuse, improve and stabilize the quality and performance of products derived from
metallurgical solid waste utilization;
— — establishestablishing a comprehensive treatment and recycling technology framework for the entire
process of wastewater resources, cascade the utilization of water resources, and strengthen the efficient
recycling of wastewater;
ISO/TR XXXX:202X(E)
DTR 25088:(en)
— — combinecombining with ultra-low emission transformation, strengthenstrengthening the efficient
recycling and utilization of by-products from flue gas treatment, and vigorously promote the
comprehensive recycling and utilization of waste gas resources generated by various furnaces and
processes in iron and steel production.
4.5 CO2 capture and utilization (CCU)
CO capture and utilization is the separation of CO from the emission sources of steel manufacturing,
2 2
solidification, or resource utilization, becoming a crucial element in achieving carbon neutrality in the iron
and steel industry. CCU focus on:
— —the technologies and processes for enriching, separating, and extracting CO from various emission
sources in steel manufacturing under the premise of low cost and high efficiency;
— — technologies for CO utilization in the steel production process, bio-fermentation for ethanol production
in the chemical industry, chemical catalysis for methanol production, mineralization fixation for building
materials in the building materials industry.
5 Technical properties
5.1 Overview of the technical properties
Currently applied low-carbon technologies are classified into four main categories and are shown in Table
1,Table 1, which also lists the main properties such as technology maturity, technical feasibility, etc.
Table 1 — Main properties of low-carbon technologies
Procedure of iron and steel Challenges and
Term Classification
industry constraints
Hydrocarbon coupling Insufficient
Smelting process
enhanced blast furnace Ironmaking hydrogen-rich gas
breakthroughs
b
technology resources
Insufficient
Hydrogen-based direct Smelting process
Ironmaking hydrogen-rich gas
b
reduction technology breakthroughs
resources
Low-carbon and hydrogen- Insufficient
Smelting process
rich sintering technology Sintering hydrogen-rich gas
breakthroughs
a
in stratified heating mode resources
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ISO/TRDTR 25088:202X(E:(en)
Procedure of iron and steel Challenges and
Term Classification
industry constraints
Near-zero CO emission
Smelting process Insufficient scrap
electric arc furnace Steel making
breakthroughs resources
a
steelmaking
Near net shape rolling Process optimization and Product structure
Rolling
a
technology innovation and market demand
High-pellet-proportion
Process optimization and Stable supply of
ironmaking technology of Ironmaking
innovation high-grade iron ore
a
blast furnace
Thermal bending Process optimization and Product structure
Rolling
a
technology innovation and market demand
Process optimization and
a
Coke dry quenching (CDQ) Cokemaking -—
innovation
High scrap ratio smelting Insufficient scrap
Steel making Resource recycling
c
for BOF resources
Top pressure recovery
Ironmaking Resource recycling -—
a
turbine (TRT)
Recovery of heat from
Cokemaking Resource recycling -—
a
crude coke oven gas
Procedures and facilities
b
CO capture technology which generates CO CO capture and utilization Excessive costs
2 2 2
such as blast furnace, lime kiln
a
CO injection in BOF Steel making CO capture and utilization -—
2 2
Steel and chemical co-
Auxiliary CO capture and utilization Market demand
b
production
CO mineralization
technology based on steel Steel making CO2 capture and utilization Production cost
b
slag utilization
a Established, broad application
b Emerging, few isolated applications
c R&D, under development, has not left the lab scale

Note 1 to entry :NOTE For CO2 emissions calculating method, see ISO 14404.

ISO/TR XXXX:202X(E)
DTR 25088:(en)
5.2 Smelting process breakthroughs
5.2.1 Hydrocarbon coupling enhanced blast furnace technology
5.2.1.1 Technical process
Figure 1 1 — Flow chart of low-carbon blast furnace
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ISO/TRDTR 25088:202X(E:(en)
5.2.1.2 Technical principle
Hydrocarbon coupling enhanced blast furnace technology uses hydrogen-rich gas and carbon monoxide-rich
gas as gas sources. After dedusting, purification, pressurization, decarbonization and heating, it is piped in
from the blast furnace tuyere area blowing device to achieve low solid carbon consumption. The blowing gas
is blown into the blast furnace from the tuyere after pressure regulation by a compressor, and the high
concentration of H and CO in the blowing medium undergoes a reduction reaction with the iron ore in the
blast furnace with a high reduction rate, which in turn promotes indirect reduction. The heat absorption of
the hydrogen reduction process is much smaller than the reduction of heat consumption due to the reduction
of direct reduction, and the heat demand of the blast furnace is reduced on the whole, which promotes the
decrease of solid fuel consumption and realizes the carbon reduction of the blast furnace.
5.2.1.3 Technological advancement and feasibility
This technology contains three key technologies: 1)
1) blast furnace production control technology under the condition of hydrogen-rich blast blowing; 2)
Equipment
2) equipment development of hydrocarbon coupled blowing technology system for blast furnace; 3)
3) key technologies of hydrocarbon coupled blowing intelligent regulation and control technology.
All of them have achieved breakthroughs and innovations in engineering application, obtained reliable data
support, and realized the engineering application of complete production flow and production process,
therefore, the technology is feasible.
5.2.1.4 Conditions of technical applicability
It is applicable to new, reconstructed and expanded blast furnace high-efficiency reduction of hydrocarbon
projects, including blast furnace hydrogen-rich blowing (such as coke oven gas, natural gas, coalbed methane,
shale gas, petrochemical hydrogen-rich waste gas), blast furnace CO-rich gas blowing, blast furnace
hydrocarbon coupling gas blowing, and furnace top gas recycling process.
ISO/TR XXXX:202X(E)
DTR 25088:(en)
5.2.2 Hydrogen-based direct reduction technology
5.2.2.1 Technical process
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ISO/TRDTR 25088:202X(E:(en)
Figure 2 2 — Process flow of hydrogen-based shaft furnace
Hydrogen-based direct reduction technology belongs to the non-blast furnace ironmaking process, which is
different from the blast furnace ironmaking. It adopts CO-rich or H -rich or pure H or polyhydrocarbon gas
2 2
(to be reformed into CO or H ) or other gases as the reductant, and uses pellet or/and lump ore as the raw
material, and produces the product as Direct Reduced Irondirect reduced iron (DRI), which is in the form of
solid granules, mainly as the raw material used in the electric furnaces for steelmaking.
5.2.2.2 Technical principle
The basic principle is the gas-solid phase reaction between H , CO and iron oxides, which is characterized by
mature technology, fast reaction speed, high productivity and good product quality. Its representative
technology is mainly based on hydrogen-based shaft furnace process.
5.2.2.3 Technological advancement and feasibility
Based on the current status quo of the global steel process (especially in developing countries), the process of
steel production will gradually change from the traditional carbon-based long process to the innovative
hydrogen-based and low-carbon electricity short process to achieve the goal of carbon neutrality. Coal-based
methods such as tunnel kiln and rotary kiln are mainly used, with backward production process, high energy
consumption and unstable product quality. From the point of view of single furnace capacity, energy
consumption and CO emission of the production unit, hydrogen-based shaft furnace has greater advantages
compared with coal-based method direct reduction process, which is more suitable for the production of
direct reduced iron for large-scale steelmaking.
ISO/TR XXXX:202X(E)
DTR 25088:(en)
5.2.2.4 Conditions of technical applicability
It is mainly applicable to iron and steel smelting scenarios with methane-rich gas (natural gas, coke oven gas,
shale gas, coal bed methane, etc.) and hydrogen as the main reductant.
5.2.3 Low-carbon and hydrogen-rich sintering technology in stratified heating mode
5.2.3.1 Technical process
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ISO/TRDTR 25088:202X(E:(en)
Figure 3 — Process flow of low-carbon and hydrogen-rich sintering technology in stratified heating
mode
5.2.3.2 Technical principle
The low-carbon and hydrogen-rich sintering technology in stratified heating mode aims at solving the
difficulties including unreasonable material layer heating, poor temperature control during the sintering
condensation mineralization, incomplete fuel combustion, etc. in the existing sintering process. Instead of
singularly heating by coke powder combustion, it proposed a new heating method driven by synergistic
combustion of gas fuel and solid fuel. The hydrogen-rich gas fuel is fed into the material layer with its amount
varying piecewise along the direction of the trolley. By replacing the solid fuel with gas fuel, the heat supply
at the vertical height of the material layer would be finely controlled, which would dramatically reduce energy
consumption. In addition, the replacement of carbon with hydrogen for reduction has significantly reduced
the carbon consumption. Besides, by broadening the combustion zone and delaying the condensation
temperature speed, the amount of returned minerals in the process has been significantly reduced. The above
improvements of three aspects have completed technology upgrade of sintering low-carbon production, with
which the carbon emission has reduced by more than 12 %. Simultaneously, a series of new technologies and
equipment have been developed to solve the problems of easy escape, easy ignition, difficulty in inhalation
and high moisture content as hydrogen-rich gas fuel is used in the sintering process.
5.2.3.3 Technological advancement and feasibility
The low-carbon and hydrogen-rich sintering technology in stratified heating mode consists of five key
technologies, namely oxygen-enriched ignition for surface heating, cascade insulation for upper layer heating,
natural gas cascade injection for middle layer heating, multiple energy carrier gas coupled
...