Final conference: WP7 EU mirroring strategy from refractory metals to general mirrors in raw materials Santiago Cuesta-Lopez (ICCRAM)*, Rocío Barros (ICCRAM), Ana Diez de la Rosa (ADE – Junta Castilla y Leon) *contact: [email protected]/ [email protected]/ [email protected]9-10/3/2017
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Final conference: WP7
EU mirroring strategy from refractory metals to general mirrors in raw materials
Santiago Cuesta-Lopez (ICCRAM)*, Rocío Barros (ICCRAM), Ana Diez de la Rosa (ADE – Junta Castilla y Leon)
Part of the key results from MSP-REFRAM are the final model and lessons learnt provided. Such methodology is potentially transferrable to other CRMs through specific vehicles like regional smart specialization strategies. - EU projects that can benefit from MSP-REFRAM methods and results* - we have identified EU regions that can clearly benefit generally from MSP-REFRAM
following “Mirroring strategies”
Identification of other CRM – model of REFRAM is transferable
* See MSP-REFRAM D7.2. REPORT SUMMARISING THE BEST PRACTICES MORE SUITABLE TO BE EXPORTED TO THE ANALYSIS OF THE WHOLE VALUE CHAIN OF OTHER CRMs. December 2016. Santiago Cuesta-López, Rocío Barros, Sonia Martel Martín, Iris García Iglesias, Gloria Rodríguez
9-10/3/2017 REFRAM, Final Conference
http://www3.ubu.es/ccrms/
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The structure of the MIREU consortium follows the EIT Raw Materials Knowledge triangle model, with the regions adding a fourth, central dimension (Fig.) in the triangle where the sides are formed from Academic, Research and Business partners working together to bridge the knowledge gap. In this sense, the EIT triangle model is taken one step further in the MIREU consortium, where the partners with special skills in various aspects work together for the regions to provide them with the best available knowledge and skills across Europe. The ERRIN network is placed in the centre with the regions, as it has an essential role as the region multiplier, through which new mining and metallurgy regions may be reached during and after the project. ERRIN will host the CoMMER working group, which will act as a forum for networking regions after the end of the project lifetime.
Figure 4. The MIREU consortium knowledge triangle The regions in the MIREU consortium are divided into two categories based on their capacity to take part in the planning and implementation of the project and their need for development. The core regions (Lapland, Castilla y León, Andalucía, Ireland, Saxony, and Styria) have an active role in the project at the work package level. The regional authorities in these pioneer regions are actively developing the mining and metallurgical industry value chain in their regional strategies such as Smart Specialisation (RIS3) and the Raw Materials Strategies and are bringing in their expertise in the project development. For those regions that are committed to the objectives of the MIREU proposal, but whose regional authorities do not have the capacity or man-power to take an active part in the development of the project, the participation model is second tier. These benefiter regions have the full benefit of participating in the project activities and the CoMMER. They will gain new insights and provide their input to the project through participation in the project workshops and answering questionnaires created in the work packages. During the MIREU project, a third group of regions, “hidden regions”, will be contacted and added to network of regions and the CoMMER.
This proposal version was submitted by Laura LAURI on 07/03/2017 15:04:01 Brussels Local Time. Issued by the Participant Portal Submission Service.
Region of Portugal Norte (Portugal), where Panasqueira Mine is currently active, with 370 employees. A large tin-tungsten mine that started
production in 1898. Mining is dipping stacked quartz veins that lead into mineralized wolfram-bearing schist. The mineralized zone has
dimensions of approximately 2,500 m in length, varying in width from 400 m to 2,200 m, and continues to at least 500 m in depth. The mine
has a planned production for more 30 years.
Region of Castilla y León (Spain). Los Santos Mine is an open pit scheelite skarn deposit located approximately 50 kilometres from Salamanca
in western Spain and produces tungsten concentrate. The mine was originally opened in 2008 and commissioned in July 2010 by its former
owner, Almonty Industries (same as Panasqueira Mine). The mine is currently producing at a rate of around 0.5m tonnes per year of ore,
yielding some 70,000 metric tonne units (MTU) of tungsten in concentrate of ore grading 0.3% tungsten.
Austria owns one of the most substantial tungsten deposits in Europe,
Mittersill mine. For more than 30 years, the Wolfram Bergbau- und Hütten-
GmbH operates in Mittersill a tungsten mine to supply the smelter with
the necessary raw material. At present 430,000 tons of ore are mined per
year with an average grade of 0.38 % WO3. The underground part of the
mineralization within the Felbertal has a dip of 55° and plunges to the
WNW. The mined ore body thickness varies between 8 and 60 m. The
chosen mining method depends on the thickness, overburden and rock
stability of the ore bodies. Sublevel caving as well as sublevel stopping with
hydraulic backfill is being applied. The mine uses both, top hammer and
DTH drilling. Mucking is done by modern LHDs.
Devon (England). The Drakelands Mine at the Hemerdon
Tungsten and Tin Project has one of the Western world's
largest tungsten and tin resources, where more than 200
people are permanently employed on site. The mine was
out of operation since 1944, except for the brief operation
of a trial mine in the 1980s, but work started to re-open it in
2014. It hosts the fourth largest tin-tungsten deposit in the
world. The tungsten deposit at the Drakelands Mine is
essentially a north-northeast trending dyke, approximately
140 m wide dipping steeply to the east. It hosts a stock
work of greisen-bordered quartz veins, bearing wolframite
and cassiterite, with minor tourmaline and sulphide
minerals. The mineralisation has been demonstrated by
drilling to persist to 400 m below ground surface.
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Summary of strategic plan guidance for fostering mining (in particular W) within the region of Castilla y Leon*. Template model to be transferred
* See details of the full strategy in MSP-REFRAM D7.2. REPORT SUMMARISING THE BEST PRACTICES MORE SUITABLE TO BE EXPORTED TO THE ANALYSIS OF THE WHOLE VALUE CHAIN OF OTHER CRMs. December 2016. Santiago Cuesta-López, Rocío Barros, Sonia Martel Martín, Iris García Iglesias, Gloria Rodríguez
Estrategia de Recursos Minerales
de Castilla y León 2016-2020.
(STRATEGY OF MINERAL
RESOURCES IN CASTILLA Y
LEON 2016-2020). General
Directorate for Energy and Mining.
Castilla y León Regional
Government)
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OTHER ‘MIRRORING’ CRITICAL RAW MATERIALS IDENTIFIED
This 4 critical raw materials, we have identified (D7.2 REFRAM), are due
to their particularities, value-chain, properties and use, and importance for
EU, clear targets to apply the lessons learnt and the methodology from
MSP-REFRAM
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Summary
Beryllium, being a very expensive metal, tends to be used only where its properties are needed and no
reasonable substitute can deliver the desired result. In particular in safety related applications (e.g. anti-lock
brake systems in cars, some aerospace), reduced performance/durability is unacceptable.
Figure 3: Distribution of end-uses and corresponding substitutability assessment for beryllium. The manner
and scaling of the assessment is compatible with the work of the Ad-hoc Working Group on Defining
Critical Raw Materials (2010).
Distribution of end-uses and corresponding substitutability
assessment for beryllium. The manner and scaling of the
assessment is compatible with the work of the Ad-hoc Working
Group on Defining Critical Raw Materials (2010).
**Credit/Reference: CRM_innonet EU-FP7. D3.3 Raw Materials Profiles. September 2013.
Importance for Europe at a glance
Beryllium is not mined in the EU/EEA. However, given estimated global reserve levels and current consumption rates, the supply in the USA of the ores could satisfy EU and world demand for over 100 years.
Use over 56,000 Kg/year of beryllium in all forms. Over 500 SME and 40 larger enterprises use beryllium. Employing over 10,000 employees.
Mechanical Equipment
With a share of 25%, the manufacture of mechanical equipment represents a
key use of beryllium. Due to its high mechanical and thermal properties
relative to its weight, especially compared to other materials, beryllium is used
as a low-density metal
The electronics & ICT sector accounts for 20% of European beryllium end-
use. After further processing, it is primarily used to increase the electrical
conductivity
Electrical equipment & domestic appliances
The electrical equipment & domestic appliances sector has a share of 20%
and uses beryllium copper
Road transport
The road transport sector, which has a share of 15% in European beryllium
end-use, mainly uses beryllium copper alloys in automobile connectors for air-
bag crash sensor, anti-lock brake systems and modifier for aluminium and
magnesium castings
Aerospace11
A 13% share of total beryllium consumption goes to use in alloys for aircrafts,
mainly because of its mechanical properties.
Extraction of beryllium
Beryllium hydroxide or
oxide
Beryllium chloride or
fluoride
Reduction to metallic
beryllium
Refining process
Other treatments
Applications, recycling & end of life
Mining Processing Manufacturing End
use
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Min
e c
hr
om
ite
or
es
Extraction by alkaline dissolution
Roast ground chrome
Reduction Electrowinning
Crystallization Electrolysis -
Metallothermics
Extraction by acidic dissolution
Removing Fe, Al and Mg
Purification Production
electrolitic Cr
Production of chromium metal
Applications, recycling & end of
life
Chromium is a bluish-white, corrosion-resistant and hard metal mostly used in
chromium plating and as an essential component of stainless steel, other alloy
steels (e.g. ferrochromium) and nonferrous alloys. Pure chromium is magnetic and
brittle, but when alloyed, it is malleable and can be polished to a silvery and
lustrous finish.
The biggest share (>90%) of total chromite ore extracted is consumed by the metallurgical industry, as it has a strengthening effect and increases corrosion resistance in steel alloys. The remaining chromite is used in the aeronautics (e.g. protection of aluminium aircraft bodies) and in the refractory (e.g. manufacturing bricks, blast furnaces, cement kilns, metal casting, etc.), foundry (e.g. foundry sands) and chemical industry (e.g. leather tanning, cosmetics, wood preservatives, catalysts, etc.). Report on Critical Raw Materials for the EU Critical Raw Materials Profiles, European Commission, 2015
Presence in Europe
The EU has always been an importer of chromite ores
and concentrates, due to a lack of internal supply and
to demand from the steel industry. According to US
Geological Survey statistics, world resources are
greater than 12 billion tons of shipping-grade
chromite, sufficient to supply it for centuries. It is to
highlight that around 95% of the world’s chromium
resources is geographically concentrated in
Kazakhstan and Southern Africa.
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(*) The ‘Substitutability index’ is a measure of the difficulty in substituting the material, scored and weighted across all applications. Values are between 0 and 1, with 1 being the least substitutable.
120 For DG Enterprise and Industry
Annex E – Further Data and Detailed Results of Criticality Assessment
This Annex contains the following information: end uses, megasector assignment and substitution values, a summary of economic importance and supply risk calculations, a comparison of results for 2013 and 2010, and large format results charts.
End uses, megasector assignment and substitution values
Material Application Share Megasector Value (GVA) Substitutability
Beryllium Electrical equipment and domestic appliances
20% Electrical 88.1 0.9
Beryllium Electronics & IT 20% Electronics 104.9 0.7
Beryllium Road transport 15% Transport-Road 147.4 0.9
Beryllium Aircraft, shipbuilding and trains 10% Transport-Other 51.2 1.0
Beryllium Others 4% Other 63.3 0.5
Beryllium Rubber, plastics and glass 3% Plastic 98.1 0.7
Beryllium Metals 3% Metals 164.6 1.0
Borate Glass 51% Plastic 98.1 1.0
Borate Frits & ceramics 14% Construction 104.4 0.7
Borate Agriculture 13% Chemicals 108.8 1.0
Borate Chemicals 8% Chemicals 108.8 0.5
Borate Metallurgy 5% Metals 164.6 1.0
Borate Construction materials 4% Construction 104.4 0.7
Borate Industrial fluids 2% Chemicals 108.8 0.5
Borate Other 2% Other 63.3 0.5
Borate Detergents 1% Chemicals 108.8 0.7
Borate Flame retardants 1% Chemicals 108.8 0.3
Chromium Stainless steel 88% Metals 164.6 1.0
Chromium Steel 9% Metals 164.6 0.7
120 For DG Enterprise and Industry
Annex E – Further Data and Detailed Results of Criticality Assessment
This Annex contains the following information: end uses, megasector assignment and substitution values, a summary of economic importance and supply risk calculations, a comparison of results for 2013 and 2010, and large format results charts.
End uses, megasector assignment and substitution values
Material Application Share Megasector Value (GVA) Substitutability
Beryllium Electrical equipment and domestic appliances
20% Electrical 88.1 0.9
Beryllium Electronics & IT 20% Electronics 104.9 0.7
Beryllium Road transport 15% Transport-Road 147.4 0.9
Beryllium Aircraft, shipbuilding and trains 10% Transport-Other 51.2 1.0
Beryllium Others 4% Other 63.3 0.5
Beryllium Rubber, plastics and glass 3% Plastic 98.1 0.7
Beryllium Metals 3% Metals 164.6 1.0
Borate Glass 51% Plastic 98.1 1.0
Borate Frits & ceramics 14% Construction 104.4 0.7
Borate Agriculture 13% Chemicals 108.8 1.0
Borate Chemicals 8% Chemicals 108.8 0.5
Borate Metallurgy 5% Metals 164.6 1.0
Borate Construction materials 4% Construction 104.4 0.7
Borate Industrial fluids 2% Chemicals 108.8 0.5
Borate Other 2% Other 63.3 0.5
Borate Detergents 1% Chemicals 108.8 0.7
Borate Flame retardants 1% Chemicals 108.8 0.3
Chromium Stainless steel 88% Metals 164.6 1.0
Chromium Steel 9% Metals 164.6 0.7
120 For DG Enterprise and Industry
Annex E – Further Data and Detailed Results of Criticality Assessment
This Annex contains the following information: end uses, megasector assignment and substitution values, a summary of economic importance and supply risk calculations, a comparison of results for 2013 and 2010, and large format results charts.
End uses, megasector assignment and substitution values
Material Application Share Megasector Value (GVA) Substitutability
Perlite Plaster aggregate 1% Construction 104.4 0.3
Perlite High-temperature insulation 1% Construction 104.4 0.3
Perlite Concrete aggregate 1% Construction 104.4 0.3
Phosphate Rock
Wet-process phosphoric acid and superphosphoric acid (used as intermediate feedstocks in the manufacture of granular and liquid ammonium phosphate fertilizers and animal feed supplements)
95% Chemicals 108.8 1.0
Phosphate Rock Others 5% Other 63.3 0.5
PGMs Autocatalyst 55% Transport-Road 147.4 1.0
PGMs Jewellery 17% Other 63.3 0.3
PGMs Electronics 10% Electronics 104.9 1.0
PGMs Chemical & Electrochemical 7% Chemicals 108.8 1.0
* Credit: Study on Critical Raw Materials at EU Level, Oakdene Hollins and Fraunhofer ISI
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Conclusions
• MSP-REFRAM has produced a useful and successful methodology to map refractory metals in EU.
• MSP-REFRAM has identified a collection of EU projects with potential synergies to be exploited with respect to the lessons learnt in refractory metals.
• In particular, MSP-REFRAM has identified about 65 EU regions with Raw Materials strategy (direct or indirectly) declared within their RIS3. About 30 regions have been involved in a common EU initiative under the EIP MIREU commitment for a sustainable inter-regional mining roadmap.
• About 10 key regions are directly linkable to be transferred good practices from Castilla y Leon as result of REFRAM activity.
• 4 Regions have been identified in synchrony creating a model for W mining promotion.
• Importantly, 4 CRMs have been preliminary analysed (Cr, Mg, Be, Si) and proposed as future targets for applying REFRAM methods and good practices.