SIST EN 19694-6:2017

SLOVENSKI STANDARD
oSIST prEN ISO 19694-6:2014
01-november-2014
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Stationary source emissions - Determination of greenhouse gas (GHG) emissions in
energy-intensive industries - Part 6: Ferroalloy industry (ISO/DIS 19694-6:2014)
Emissionen aus stationären Quellen - Bestimmung von Treibhausgasen (THG) aus
energieintensiven Industrien - Teil 6: Ferrolegierungsindustrie (ISO/DIS 19694-6:2014)
Émissions de sources fixes - Détermination des émissions des gaz à effet de serre dans
les industries à forte intensité énergétique - Partie 6: Industrie des ferro-alliages
(ISO/DIS 19694-6:2014)
Ta slovenski standard je istoveten z: prEN ISO 19694-6
ICS:
13.040.40 (PLVLMHQHSUHPLþQLKYLURY Stationary source emissions
oSIST prEN ISO 19694-6:2014 en,de
2003-01.Slovenski inštitut za standardizacijo. Razmnoževanje celote ali delov tega standarda ni dovoljeno.

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oSIST prEN ISO 19694-6:2014

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oSIST prEN ISO 19694-6:2014
DRAFT INTERNATIONAL STANDARD
ISO/DIS 19694-6
ISO/TC 146/SC 1 Secretariat: NEN
Voting begins on: Voting terminates on:
2014-08-21 2015-01-21
Stationary source emissions — Determination of
greenhouse gas (GHG) emissions in energy-intensive
industries —
Part 6:
Ferroalloy industry
Émissions de sources fixes — Détermination des émissions des gaz à effet de serre dans les industries à
forte intensité énergétique —
Partie 6: Industrie des alliages de fer
ICS: 13.040.40
ISO/CEN PARALLEL PROCESSING
This draft has been developed within the International Organization for
Standardization (ISO), and processed under the ISO lead mode of collaboration
as defined in the Vienna Agreement.
This draft is hereby submitted to the ISO member bodies and to the CEN member
bodies for a parallel five month enquiry.
Should this draft be accepted, a final draft, established on the basis of comments
received, will be submitted to a parallel two-month approval vote in ISO and
THIS DOCUMENT IS A DRAFT CIRCULATED
formal vote in CEN.
FOR COMMENT AND APPROVAL. IT IS
THEREFORE SUBJECT TO CHANGE AND MAY
NOT BE REFERRED TO AS AN INTERNATIONAL
STANDARD UNTIL PUBLISHED AS SUCH.
To expedite distribution, this document is circulated as received from the
IN ADDITION TO THEIR EVALUATION AS
committee secretariat. ISO Central Secretariat work of editing and text
BEING ACCEPTABLE FOR INDUSTRIAL,
composition will be undertaken at publication stage.
TECHNOLOGICAL, COMMERCIAL AND
USER PURPOSES, DRAFT INTERNATIONAL
STANDARDS MAY ON OCCASION HAVE TO
BE CONSIDERED IN THE LIGHT OF THEIR
POTENTIAL TO BECOME STANDARDS TO
WHICH REFERENCE MAY BE MADE IN
Reference number
NATIONAL REGULATIONS.
ISO/DIS 19694-6:2014(E)
RECIPIENTS OF THIS DRAFT ARE INVITED
TO SUBMIT, WITH THEIR COMMENTS,
NOTIFICATION OF ANY RELEVANT PATENT
RIGHTS OF WHICH THEY ARE AWARE AND TO
©
PROVIDE SUPPORTING DOCUMENTATION. ISO 2014

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oSIST prEN ISO 19694-6:2014


Copyright notice
This ISO document is a Draft International Standard and is copyright-protected by ISO. Except as
permitted under the applicable laws of the user’s country, neither this ISO draft nor any extract
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ii © ISO 2014 – All rights reserved

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oSIST prEN ISO 19694-6:2014
General information regarding the preparation of EN ISO 19694 Part 1 to 6

By end of 2010 the European Commission/EFTA gave Mandate M/478 to CEN entrusting CEN
to produce and adopt Standards, in particular containing harmonized methods for:

a. Measuring, testing and quantifying greenhouse gas (GHG) emissions from sector-
specific sources

b. Assessing the level of GHG emissions performance of production processes over
time, at production sites;

c. Establishing and providing reliable, accurate and quality information for reporting and
verification purposes.

Based on a gap analysis it was agreed to describe the assessment methodologies of the five
energy-intensive industry sectors steel-, cement -, aluminum-, lime- and ferroalloy industry as
well as general aspects in the six standards. As sector-specific knowhow was essential, the
concerned industry sectors (companies and associations) have been engaged extensively in the
development of the methodologies as well as the draft standards.
The methods of determination of green house gases (GHG) in these five energy intensive
industries were subject to comprehensive verification exercises (field tests) which were
financially supported by EC/EFTA and which reflect especially the uncertainties obtained.

The scope of the six standards is limited to the above described mandated frame and cannot be
arbitrarily enlarged.

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oSIST prEN ISO 19694-6:2014
TC 264 WI 00264147:2014 (E)
Contents
Page
Foreword .3
Introduction .4
1 Scope .5
2 Normative references .6
3 Terms and definitions .6
4 Symbols and abbreviations .7
5 Determination of GHGs - Principles.8
6 Boundaries .8
7 Direct emissions and their determination . 10
8 Indirect emissions . 18
9 Baselines, acquisitions and disinvestments . 19
10 Reporting . 19
11 Uncertainty of GHG inventories . 22
Annex A (normative) Tier 1 Emission factors . 25
Annex B (normative) Minimum frequency of analysis . 28
Annex C (normative) Country wise emission factors for electricity . 29
Annex D (informative) Relationship with EU Directives . 33
Bibliography . 34


2

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Foreword
This document (TC 264 WI 00264147) has been prepared by Technical Committee CEN/TC 264 “Air quality”,
the secretariat of which is held by DIN.
This document is currently submitted to the CEN Enquiry.
This document has been prepared under a mandate given to CEN by the European Commission and the
European Free Trade Association, and supports essential requirements of EU Directive(s).
For relationship with EU Directive(s), see informative Annex D, which is an integral part of this document.
3

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Introduction
Overview of the ferro-alloy manufacturing process
Ferroalloy production involves a m etallurgical reduction process that results in significant carbon dioxide
emissions. These emissions are the results of a carbothermic reaction which is intrinsic to the process. In
ferroalloy production, ore, carbon materials and slag forming materials are mixed and heated to high
temperatures for smelting.
Smelting in an electric arc furnace is accomplished by conversion of electrical energy to heat. An alternating
current applied to the electrodes creates current to flow through the charge between the electrode tips. The
heat is produced by the electric arcs and by the resistance in the charge materials. Emissions from the
smelting process are therefore not to combustion emissions. The furnaces may be open, semi-closed or
closed.
Submerged Electric Arc Furnaces (SEAF) with graphite electrodes or self- baking Søderberg electrodes are
used (see Figure 1).
The reduction process is the main source of direct CO emissions. O ther CO sources include direct
2 2
emissions from calcination of calcium, magnesium and other carbonates (e.g. limestone) in some processes
and from non-smelting fuels (e.g. dryers for ladles and refractory linings), room heating,), and indirect
emissions from e.g. external power production.

Figure 1 — Submerged Electric Arc Furnace (SEAF)
CO from the smelting of raw materials
2
CO emissions from reducing agents and electrode use
2
4

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In the smelting process, CO is released due to the carbothermic reduction of the metallic oxides occurring
2
with the consumption of both carbonaceous reductants and carbon based electrodes. The carbon in the
reductants reacts with oxygen from the metal oxides to form CO and then CO (in different ways depending on
2
the process), and the ores are reduced to molten base metals. All CO is assumed to be converted in the
furnace to CO .
2
The reductant carbon is used in the form of coke, coal, pet coke, anthracite, charcoal and wood-chips. The
first four are fossil based and the charcoal and wood-chips are bio-carbon.
In the carbothermic process, only the fixed carbon content is used as a reducing agent, which means that
volatile matter, ashes and moisture mostly leave the furnace with the off-gas and slag.
The nature of reducing agents and electrodes is depending of the localization of the plant, the raw material
availability and it is presented in Table 1. It is variable from one site to another and from one year to another
and also from one ferro-alloy to another.
Table 1 — Type of reducing agents and electrodes used in the electrometallurgy Sector

Reducing agents Electrodes
Crude petroleum coke Graphite electrode
Calcinated petroleum coke Prebaked electrodes
Coal coke Södeberg paste
Coke from coal Composite electrode
Wood
Calcinated wood
Charcoal
Graphite powder
Anthracite

CO emissions are estimated with/calculated from the consumption of the reducing agents and electrodes,
2
1
their carbon content and the carbon content of the final products .
ores + reducing agent → ferro-alloys/metal* + CO + dust/by-product (i.e. slags)*
2

* amount of carbon can be found in the products
Default emission factors suggested in these documents are used, except where more recent, industry-specific
data has become available.
1 Scope
This standard provides a harmonised methodology for calculating GHG emissions from the ferro-alloys
2
industry based on the mass balance approach . It also provides key performance indicators over time of ferro-
alloys plants. It addresses the following direct and indirect sources of GHG:
 Scope 1 – Direct GHG emissions from sources that are owned or controlled by the company, such as
emissions result from the following sources:
 Smelting (reduction) process:
 Decomposition of carbonates inside the furnace

1
The basic calculation methods used in this standard are compatible with the 2006 IPCC Guidelines for National
Greenhouse Gas Inventories issued by the Intergovernmental Panel on Climate Change (IPCC), and with the Regulation
601/2012  but the objectives of this standards are of different nature implying that the data gathered can cover a broader
(or reduced) boundaries as compared to the objectives of the Regulation.
2
based on European Commission Regulation 601/2012
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 auxiliaries operation related to the smelting operation (i.e. aggregates, drying processes, heating of
ladles, etc.).
 Scope 2 – Indirect GHG emissions from:
 the generation of purchased electricity consumed in the company’s owned or controlled equipment
2 Normative references
The following referenced document is indispensable for the application of this document. For dated
references, only the edition cited applies. For undated references, the latest edition of the referenced
document (including any amendments) applies.
ISO/DIS 19694-1:2014, Stationary source emissions – Determination of Greenhouse Gas (GHG) emissions in
energy intensive industries – Part 1: General aspects
3 Terms and definitions
For the purposes of this document, the following terms and definitions apply:
3.1.
Auxiliaries
equipment consuming electricity/power related to the smelting process: fans, pumps, gas abatement systems
(filter bags, venture scrubbers …)
3.2
biomass emissions
CO emissions originating from biomass fuels plus the ones originating from biomass fraction of mixed fuels
2
3.3
Silica Fume: Amorphous silicon dioxide particles from the volatilization and vaporization of furnace feed
materials in the manufacture of ferrosilicon and silicon, the process off-gas that contains silica fumes beings
cleaned in a baghouse using fabric filters of the open or semi-closed SEAF
3.4
Ferro-alloy:
Ferroalloy is the term used to describe concentrated alloys of iron and one or more metals such as
silicon,manganese, chromium, molybdenum, vanadium and tungsten.
3.5
Silicon:
Silicon is a metalloid produced by carbo-thermic reduction of quartz in an electric submerged arc furnace.

3.6
Smelting:
Industrial process where one or more ores or ore concentrates are heated and reduced (i.e. chemically
modified) by e.g. aluminino-carbo-silico thermic reduction –to manufacture and mix the metals in one step.
Examples of smelted alloys are ferro-alloys.

3.7
Gross GHG emissions
Absolute gross GHG emissions excluding GHG emissions from on-site power production
3.8
Absolute gross GHG emissions
Total direct emissions of GHGs within the boundaries excluding GHG emissions from biomass or biogenic
emissions (i.e. woodchips and charcoal)

6

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3.9
Submerged Electric Arc Furnace (SEAF)
An electric arc-heating furnace in which the arcs are completely submerged under the charge. The arc forms
between the electrode (graphite electrodes or self- baking Søderberg electrodes) and metal surface or bottom
lining. The heat being produced by the electric arcs and by the resistance in the charge materials initiates the
reduction process. The furnaces may be open, semi-closed or closed. A commonly used technology is the
submerged-arc (electric) furnace (SEAF).
3.10
Fossil fuels
All fossil fuels listed by IPCC or any fuel which contains organic and inorganic carbon that is not biomass.
3.11
Biomass Fuels
Fuels with only biogenic carbon
3.12
Petcoke
Petroleum coke, a carbon-based solid fuel derived from oil refineries
3.13
Sintering/Sinter
Process to form a coherent mass by heating without melting.

3.14
Søderberg Electrodes
A continuously self-baking carbon electrode used in electro-metallurgical furnaces for production of ferroalloys
and silicon (the “Søderberg paste” is a preparation of coal tar pitch and carbonaceous dry aggregate).

3.15
Composite electrodes
In composite electrodes the core is composed of graphite while the exterior is a self baking carbon paste (
which is a “Søderberg paste”).

3.16
Pre-baked electrodes
The carbonaceous paste (a mixing of coal tar pitch with a dry carbonaceous aggregate) is baked so as to
carbonize coal tar pitch in order to form a solid pitch coke binder phase.
4 Symbols and abbreviations
For the purposes of this document, the following symbols and abbreviations apply
AF Alternative fuels
EF Emission Factor
EU ETS The CO Emissions Trading Scheme of the European Union
2
GHG Greenhouse gases
FA Ferro-alloys
FABP Ferro-alloys and related by-products
IPCC Intergovernmental Panel on Climate Change
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oSIST prEN ISO 19694-6:2014
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KPI Key Performance Indicator.
LHV Lower heat value (synonym for net calorific value)
MIC Mineral components
TC Total Carbon (the sum of TOC and TIC)
TIC Total Inorganic Carbon
TOC Total Organic Carbon
t ton ( 1,000 kg)
3 3
m normal m (at 0 ºC and at a pressure of 1 atmosphere)
n
GJ Giga Joule
CO carbon monoxide
CO carbon dioxide
2
5 Determination of GHGs - Principles
GHG emissions are determined by the mass balance method (section 5.1).
5.1 Major GHG in ferro-alloys
CO is the only GHG relevant for the ferro-alloys industry.
2
5.2 Determination based on mass balance
In installations where carbon stemming from input materials used remains in the products or other outputs of
the production, e.g. for the reduction of metal ores, a mass balance approach is applied. In installations where
this is not the case combustion emissions and process emissions are calculated separately.
Emissions from source streams are calculated from input or production data, obtained by means of
measurement systems, and additional parameters from laboratory analyses including calorific factor, carbon
content and biomass content. Standard factors may also be used; these are provided in the General Aspects
Standard (see normative references).
5.3 Use of waste gas/heat recovery
Direct GHG emissions related to waste gas and heat recovery will be reported as scope 1 emissions.  Waste
gas including CO and CO can be subtracted from the direct emission, when exported outside the boundaries
2
of the location, as a negative carbon flow in the mass balance (for example when exporting waste gas to
another installation).
6 Boundaries
Drawing appropriate boundaries is one of the key tasks in an emissions inventory process.
6.1 Operational boundaries
Operational boundaries refer to the types of sources covered by an inventory. A key distinction is between
direct and indirect emissions:
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a) Direct emissions are emissions from sources that are owned or controlled by the reporting company.
For example, emissions from smelting are direct emissions of the company owning (or controlling) the
furnace.
b) Indirect emissions are emissions that result as a consequence of the activities of the reporting company
but occur at sources owned or controlled by another company. For example, emissions from the generation of
grid electricity consumed by a ferro-alloy company will qualify as indirect.
Chapter 7 of this standard provides detailed guidance on the different sources of direct emissions occurring in
ferro-alloys plants. Indirect emissions are addressed in Chapter 8.
Companies shall use the operational boundaries outlined in table 2 and the relevant process steps in table 3,
for the determination of the GHG emissions for the smelting/carbo-thermic reduction operations part of the
ferro-alloy plant. Any deviation from these boundaries shall be reported and explained.
Table 2 — Operational boundaries
Included within boundaries Excluded
Smelting (carbo-thermic reduction) Mobile transport
Electrodes
Reducing agents
Non furnace fuels
Electricity consumption for whole production Room heating / cooling (negligible)
process
Mobile transport in plant
Onsite power production
Waste Heat Recovery
Stock inventories carbon materials

Table 3 — Process steps
Process Step Scope  Inclusion?
Smelting Scope 1 Yes
Electricity consumption for Scope 2 Yes
whole production process
Scope 1 Yes
Onsite power production

Waste Heat Recovery Scope 1 Yes
Room heating / cooling Scope 1 yes, but negligible
Stock changes Scope 1 Yes

6.2 Organizational boundaries
The major source of GHG emissions in the ferroalloys sector is the process-related emissions from the
Submerged Electric Arc Furnaces operations, the reduction of the metallic oxides and the consumption of the
electrodes during the process. There are practically no fuel related process emissions and heat is a negligible
input factor in the production. The operational boundaries for this standard GHG emissions covers only the
smelting/carbo-thermic reduction operations considered as core activities and the related auxiliaries.
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7 Direct emissions and their determination
Direct emissions are emissions from sources of the respective plant. In ferro-alloys plants, direct GHG
emissions may result from the following sources:
a) CO emissions from reducing agents and electrode use in the smelting process
2
b) raw materials (e.g. decomposition of limestone, dolomite, and c arbon containing metal ores and
concentrates),
c) combustion of conventional fuels (e.g. natural gas, coal and coke, or fuel oil)
d) combustion of biomass fuels;
In installations where carbon stemming from fuels or input materials used at this installation remains in the
products or other outputs of the production, e.g. for the reduction of metal ores, a mass balance approach is
applied.
Generally, companies are encouraged to measure the required parameters at plant level for specific raw
materials. Where plant- or company-specific data are not available, approved factors should be used.
7.1 Mass balance approach
7.1.1 Generic Approach
In the mass balance approach, the CO2 quantity corresponding to each source stream included in the mass
balance has to be calculated by multiplying the activity data related to the amount of material entering or
leaving the boundaries of the mass balance, with the emission factor for each material.
The methodologies for determining i.e. activity data and em ission factors are referred to as tiers. The
increasing numbering of tiers from one upwards reflects increasing levels of accuracy, with the highest
numbered tier as the preferred tier.
For emission sources which emit more than 10 % of the total annual emissions of the installation the operator
shall preferably apply the highest tier given the less uncertainty. For all other emission sources, the operator
shall apply at least one tier lower than the highest tier.
In case the application of the highest tier is technically not feasible or incurs unreasonable costs a next lower
tier shall be used for the relevant emission source, with a minimum of tier 1.
For marginal flows, which jointly emit 1,000 t CO or less, or less than 2% of the “total of all monitored
2,eq
items” (whichever is highest and not exceeding 20,000 t CO )), it is allowed to calculate activity data and
2,eq
emission factors using a conservative estimation, instead of using tiers (unless it is possible to use tiers
without additional effort or costs).
With:
(a) Activity data
The operator shall analyze and report the mass flows into and from the installation and respective stock
3
changes for all relevant fuels and materials separately (generally in GJ (for energy) or in t or m for mass or
n
volume).
Tier 1
Activity data over the reporting period are determined with a maximum uncertainty of less than ± 7,5 %.
Tier 2
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Activity data over the reporting period are determined with a maximum uncertainty of less than ± 5 %.
Tier 3
Activity data over the reporting period are determined with a maximum uncertainty of less than ± 2,5 %.
Tier 4
Activity data over the reporting period are determined with a maximum uncertainty of less than ± 1,5 %.
(b) Emission factors
3
Emission factors are expressed as tCO /GJ, tCO /t or as tCO /m .
2eq 2eq 2eq n
Tier 1 International reference for emission factors (IPCC data)
The emission factor of input or output streams is derived from reference emission factors for fuels or materials
named in Annex A.
Tier 2 National reference
The operator applies country-specific emission factors for the respective fuel or material as reported by the
respective Member State in its latest national inventory submitted to the Secretariat of the United Nations
Framework Convention on Climate Change.
Tier 3 Industry specific reference
The emission factor of input or output stream shall be derived following the provisions of this standard in
respect to representative sampling of fuels, products and by-products, the determination of their carbon
contents and biomass fraction. These emission factors are usually determined by analysis of the carbon
content. For the conversion of carbon content into the respective emission factor for CO a factor of 3.664 [t
2
CO /t C] shall be used.
2
Requirements for analysis should retain the preference for use of laboratories accredited in accordance with
the harmonized standard General requirements for the competence of testing and calibration laboratories (EN
ISO/IEC 17025) for the relevant analytical methods, and introduce more pragmatic requirements for
demonstrating robust equivalence in the case of non-accredited laboratories. Company measurements are
carried out by applying methods based on corresponding EN standards. Where such standards are not
available or applicable, the methods shall be based on suitable ISO standards (EN ISO/IEC 9001) or national
standards” or on industrial best practices, limiting sampling and measurement bias.
7.1.2 Sampling
The operator shall provide evidence that the derived samples are representative and free of bias. The
respective value shall be used only for the delivery period or batch of fuel or material for which it was intended
to be representative.
Generally, the analysis will be carried out on a sample which is the mixture of a larger number (e.g. 10-100) of
samples collected over a period of time (e.g. from a day to several months) provided that the sampled fuel or
material can be stored without changes of its composition.
The sampling procedure and frequency of analyses shall be designed to ensure that the annual average of
the relevant parameter is determined with a maximum uncertainty of less than 1/3 of the maximum uncertainty
which is required by the approved tier level for the activity data for the same source stream.
If the operator is not able to meet the allowed maximum uncertainty for the annual value or unable to
demonstrate compliance with the thresholds, he shall apply the frequency of analyses as laid down in Annex
B as a minimum, if applicable.
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7.1.3 Alternate approach
The alternate approach for the Tier 3 method is to use emission factors for the reducing agents only, which is
adopted here. The simplified adopted equation is the following:
Equation n° 1:

Emissions of CO (t) = Consumption of reducing agents /electrodes x EF Reducing agent/ electrode
2

With :
• Consumption of reducing agents/electrodes (in t): total consumption of reducing agents/electrodes
• EF reducing agent/electrodes: emission factor (in t CO /t) of reducing agents of electrodes
2


The emission factor of the reducing agent is based on its carbon content:

Equation n° 2 (Simplified equation):


EF CContentreducing agent, i) • 3.664
reducing agent, =

The total C-contents of reducing agents is calculated by the following equation.
Equation n° 3:


CContentreducing agent,i = FFixC,i +
Fvolatiles,i •Cv


Where:

CContentreducing agent, i = carbon content in reducing agent i, ton C/ton reducing agent
FFixC,i = mass fraction of Fix C in reducing agent i, ton C/ ton reducing agent
Fvolatiles,i = mass fraction of volatiles in reducing agent i, ton volatiles/ ton reducing agent
Cv = carbon cont
...