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This Project is Fundedby the European Union
COOPERATION AND BUSINESS OPPORTUNITIES FOR GREEN SOLUTIONS IN MEXICO!
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Proyecto financiadoPor la Unión Europea
CONTENTS
1. Identification of cooperation and business opportunities in “Low Carbon” sectors
2. What is LCBAM’s contribution to MEX and EUR entities?
3. How to participate?
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Proyecto financiadoPor la Unión Europea
1Identification of cooperation and business opportunities in “Low Carbon” sectors
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Proyecto financiadoPor la Unión Europea
1. Cooperation and Business opportunities. Maping report
Mapping of specific needs and gaps and identification of potential partners in targeted sectors in Mexico1
The report includes existing low carbon emissions initiatives in the sectors of Waste Management, Wastewater and Energy Efficiency to identify technology needs and gaps in Mexico
Focused on identifying commercial opportunities for European low carbon technologies to be implemented in Mexico through Cooperation Partnership Agreements (CPAs)
WASTE WATER MANAGEMENT
WASTEMANAGEM
ENT
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Proyecto financiadoPor la Unión Europea
A) WASTE MANAGEMENT
WASTEMANAGEMENT
•Less than 2% of the daily total waste generated is treated in separation plants
•Key areas:•Municipal solid waste management•Special Handling waste
Dimension: 55,000 companies
General remarks
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Proyecto financiadoPor la Unión Europea
1. Cooperation and Business opportunities. Waste Management
WASTE MANAGEMENT
Conclusions the Waste Management sector in Mexico
The lack of norms and technical guides make difficult to clearly identify specific opportunities in public sector (1/2)
• Three types of waste and there public administration involved:
• (i) Municipal solid waste (MSW). Responsible: municipalities
• (ii) Special handling waste. Responsible: States
• (iii) Hazardous waste. Responsible: federal authorities
• Municipalities do not charge fees on the collection, treatment and waste disposal, which impairs the correct waste management
• There are no official norms or technical guidance for the collection, transfer and handling of waste. The final disposal stage is the only phase that is ruled by norms.
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Proyecto financiadoPor la Unión Europea
1. Cooperation and Business opportunities. Waste Management
WASTE MANAGEMENT
Stages and process in the management of Solid Waste
Source: 2012 Diagnóstico Básico para la Gestión Integral de los Residuos, INECC, SEMARNAT.
Generation Collection Transfer Handling Disposal
Selective collection
Mixed collection
Industrial production
Unkown
Scavanging at collection
Separation plants
Recycling
Sanitary landfill and controlled landfills
Open air landfills
Scavanging at open air landfill
Treatment plants
Transfer stations
Recycling
The lack of norms and technical guides make difficult to clearly identify specific opportunities in public sector (2/2)
However, there is room for identifying collaboration opportunities in making more efficient the Industrial Waste management
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Proyecto financiadoPor la Unión Europea
1. Cooperation and Business opportunities. Waste Management
In absolute terms the largest proportion of big size companies is registered in Mexico City
Tabasco, Mexico City, Coahuila, Campeche and Chihuahua are the states with the largest proportion of mid-size companies in the sector
Heat map of the concentration of companies related to the waste management sector
0 to 180 companies
180 to 360 companies
360 to 440 companies
440 to 620 companies
620 to 800 companies
more than 800 companies
WASTE MANAGEMENT
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Proyecto financiadoPor la Unión Europea
1. Cooperation and Business opportunities. Waste Management
The collaboration opportunities to develop and provide solutions/technologies in Waste Management are distributed along the Waste Management cycle
WASTE MANAGEMENT
Needs and gaps in function of the Waste management cycle
Storage •Optimizing the collection system
•Smart collecting, eco-points
Handling•Processing techniques and machines (pelleting, briquetting, etc.)
Transport•Smart Collection – Dynamic routing software
Sorting•Automated sorting systems (magnetic systems, screens, etc.)
•Integrated stations (Municipal waste recovery)
Treatment and recycling•Recycling equipment
•Composting/compact and closed system
•Composting control systems
•Anaerobic Digestion: multiphase, dry fermentation, etc.
•Integrated systems
Final disposal•Integral projects
•Biogas Handling
•Leachate Handling
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Proyecto financiadoPor la Unión Europea
1. Cooperation and Business opportunities. Waste Management
Although the difficulties, there are a number of consolidated players in the market that offer and implement technological solutions within the waste management cycle
Examples of representative companies in the different stages of the waste management cycle
WASTE MANAGEMENT
VEOLIA has built and operated more than 10
landfills in Mexico managing nowadays 2.3 million
tons of municipal solid waste per year
GUASCOR has installed more than 10
biogas generation plants in Mexico
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Proyecto financiadoPor la Unión Europea
1. Cooperation and Business opportunities. Waste Management
Waste Management is one of the competitive keys in Agrifood Industry as well as the Mexican building Industry
There are existing opportunities in livestock breading and cultivation of plant foods, forestry and food processing sector
Identification of sector with potential to incorporate solutions
WASTE MANAGEMENT
Building Industry
Agricultural Industry (i): Livestock breeding and
cultivation of plant foods, forestry
Agricultural Industry (ii): food processing sector
Waste management of municipal, industrial and commercial solid waste
industry
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Proyecto financiadoPor la Unión Europea
1. Cooperation and Business opportunities. Waste Management
The lack of infrastructure in waste management derived form building sector generates business opportunities
SOLID URBANWASTE
•Integrated waste management of housing construction (specially demolition)
•There is insufficient installed capacity, mainly on the "Bajio" region and northern border
•a) Rubble recycling machines with high throughput, mobile, compact and low fuel consumption or hybrid.
•b) Fixed stations with complete recycling lines that provide service to the industry and municipalities.
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Building Industry
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Proyecto financiadoPor la Unión Europea
1. Cooperation and Business opportunities. Waste Management
The Agrifood industry are in the challenge of generating value from their transformation processes (1/2)
SOLID URBANWASTE
•Using some kinds of excreta and waste from the food crop
•Waste utilization of fisheries and aquaculture. Skin, bones, meat, shellfish shells and heads. Use of waste from the timber industry
•a) Integral Systems co-digestion of manure and waste in the food crop
•b) Package software-hardware control digesters
•c) Energy-efficient crushing and pumping systems of semi solids influent pre-treatment
•d) Equipment for production of biodiesel from animal fat from fish processing and aquaculture
•e) Briquette production-lines and biocharPo
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Agricultural Industry
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Proyecto financiadoPor la Unión Europea
1. Cooperation and Business opportunities. Waste Management
The Agrifood industry are in the challenge of generating value from their transformation processes (2/2)
SOLID URBANWASTE
• a) Use of whey from cheese production processes and yogurt
• b) Use bagasse from manufacturing processes of alcoholic drinks (more than 80% of the biomass discarded.
• c) Use of “cachazas” and molasses of sugar mills
• d) Use of waste from slaughterhouses and processing of cold cuts
• e) Use of the scale, mucilage and pulp production of coffee bean (Only 10% by weight of the coffee cherry is used as grain is 90% residual biomass)
• f) Use of the shell from cocoa processing. Approximately 90% of the weight of the fruit is discarded
• a) UASB Biodigestion systems
• a) Methanol extraction equipment from whey
• b) Modules of anaerobic treatment of bio solids and sludge from treatment plants wastewater
• c) Integral briquetting systems of bagasse
• d) Gasification systems for bio solids
• e) Production lines of bioethanol based on intermediates of sugar production
• f) Integral Systems dehydration and briquetting of “cachazas”
• g) Gasification systems of bio solids
• h) Equipment gasification of meat waste
• i) Modules anaerobic treatment of bio solids and sludge from treatment plants wastewater
• j) Comprehensive Systems of coffee husk briquetting
• k) Gasification systems of bio solids
• l) Integral Systems cocoa shell briquetting
• m) Gasification of bio solids systems Po
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Food Processing Sector
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Proyecto financiadoPor la Unión Europea
1. Cooperation and Business opportunities. Waste Management
Challenges in municipal, industrial and commer waste management
SOLID URBANWASTE• a) Pre-sorting systems that increase the recycling rate, simplifying the management and
professionalizing the industry
• b) Increase the materials recovery rate in existing sorting lines
• c) Energy recovery of existing incineration plants and implementation of demonstrative thermal systems
• d) Treatment and final disposition technologies for electronic waste gathered by the currently programs
• e) Optimization and odor control of composting plants
• f) Technical improvement of anaerobic digestion systems
• g) Upgrade the energy efficiency of biogas, syngas, and landfill gas combustion
• h) Technical improvement of design and operation of landfills
• a) Smart storage and collection systems, Eco-point programs and technologies
• b) Optical multiplexer sorting systems, water and air by density sorting systems and integrated stations, Specialized processing equipment previous to composting and anaerobic digestion systems
• c) Waste to energy systems: Pyrolysis, Circulating fluidized bed, Gasification
• d) Recycling lines of electronic with services kind glass to glass, End-of-life destruction, Asset recovery services, Retailer recalls & returns,
• e) Megatrends in composting: In vessel composting systems, household scale composting systems, Aeration active systems and passive systems, Inoculants, activators, tea extraction systems, Solids feeders, mixing and pumping technology
• f) Megatrends in anaerobic digestion
• g) Combined heat and power units (CHP), Combined cool, heat and power units (CCHP)
• h) Megatrends in landfilling:
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Waste management of municipal, industrial and commercial solid waste
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Proyecto financiadoPor la Unión Europea
B) Waste Water Management
•Mexico only treats 50.3% of the collected urban wastewater (TARGET 63% in 2018).
•9.33% of all wastewater in Mexico is employing septic tanks
•Key areas to incorporate technology: optimization, improvement and enhancement of current technologies, including energy recovery
General remarks
WASTE WATER MANAGEMENT
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Proyecto financiadoPor la Unión Europea
1. Cooperation and Business opportunities. Waste water Management
WASTE WATER MANAGEMENT
Heat map of the concentration of companies related to the waste management sector
The sector is mainly composed by small companies and some medium companies
Mexico City, Mexico State, Bajio Region, Jalisco, Nuevo León and Puebla are the states where there are more companies related to wastewater sector.-
Conclusions the Wastewater Management sector in Mexico
• Nearly nine million people lack clean water and 11 million lack sewage (5 million and 7.8 respectively in rural)
• Technologies used in urban wastewater treatment in Mexico are antiquated and they are only using tertiary or advanced treatment processes. Lack of maintenance of the current technologies.
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Proyecto financiadoPor la Unión Europea
1. Cooperation and Business opportunities. Waste water Management
WASTE WATER MANAGEMENT
Source: Elaborated by the authors
Examples of representative companies in the different business segments
In terms of construction and operation, the most important Mexican company would be Atlatec where they have are currently executing:
• 11 Design, build, finance and operate (DBFO) urban wastewater treatment plants
• and 21 Design, build, finance and operate (DBFO) industrial wastewater treatment plants.
Other key companies:• Grupo CARSO• OHL Medio
Ambiente• Inima• Marhnos SA de
CV• Sacyr Mexico
S.A.
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Proyecto financiadoPor la Unión Europea
1. Cooperation and Business opportunities. Waste water Management
One of the main challenges that Mexico is currently facing is the need to achieve sustainable integrated water management
WASTE WATER MANAGEMENT
Conclusions the Waste Water Management sector in Mexico
• Mexico uses untreated wastewater for irrigation where 73% of the total wastewater produced in Mexico is used to irrigate 260,000 ha of farmland across Mexico (CNA, 2004)
• One of the biggest aspects technical/technological challenge is the lack of maintenance. A total of 555 wastewater treatment plants were out of operation (Conagua 2014) .
Classification of the processes of Wastewater Treatment
Treatment level Description
Preliminary Removal of large objects (e.g. rags, sticks, other floating objects), grit and grease. This helps to avoid O&M issues with more advanced treatment technologies later on.
Primary Removal of some suspended solids and organic matter.
Advanced Primary Enhanced removal of suspended solids and organic matter. This is usually done by chemical addition or filtration.
Secondary Removal of biodegradable organic matter (in solution or suspension) and suspended solids. Disinfection typically is also included in the definition of
conventional secondary treatment.
Secondary with nutrient removal /
Recovery
Removal of biodegradable organic matter, suspended solids, and nutrients. Nutrient removal can involve nitrogen, phosphorus or both.
Tertiary Following secondary treatment, removal of the remaining suspended solids. This is typically ism achieved using some type of filtration. Tertiary treatment also encompasses disinfection, and nutrient removal is sometimes included
under this heading rather than under secondary treatment.
Advanced Treatment level required for certain applications, involving removal of TDS and/or trace constituents.
Source: Adapted from GWI 2010
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Proyecto financiadoPor la Unión Europea
1. Cooperation and Business opportunities. Waste water Management
Structure of Wastewater technologies
• xxxxxxx
A. 1 Pumps
• 2.1 Septic Tanks
• 2.2 Primary sedimentation tanks and chemically enhanced primary sedimentation
• 2.2.1 Imhoff Tanks
• 2.3 Anaerobic/facultative ponds
A.2 Primary Treatment
• 3.1 Activated Sludge
• 3.2 Upflow Anaerobic Sludge Blanket (UASB)
• 3.3 Trickling filter
• 3.4 Rotating biological contactor
• 3.5 Anaerobic Digestors / Anaerobic filter
• 3.6 Biological Reactor
• 3.7 Land Treatment (Maturation Ponds; Areated Ponds; Wetlands)
A.3 Secondary Treatment
•4.1 Micro-Filtration (MF)
•4.2 Ultra Filtration (UF)
•4.3 Nano-Filtratio (NF)
•4.4 Reverse Osmosis (RO)
•4.5 Membrane Bioreactors (MBR)
•4.6 Ion-exchange
•4.7 Chemical oxidation
•4.8 Granular media filtration (Sand Filters, Carbon Filters)
•4.9 Disinfection (Ultraviolet, Ozone treatment and Chlorine disinfection)
•4.10 Nutrient Removal
•4.11 Land Treatment: (Soil Aquifer Treatment (SAT); Maturation Ponds)
•4.12 Modular Wastewater Treatment Plants
A.4 Tertiary Treatment
•5.1 Micro-algae Bioreactor
•5.2 Codigestors
•5.3 Anaerobic Digestion
A5. Energy Conversion
•6.1 Automated Control
•6.2 Automated Monitoring
A6 Monitoring and Control
WASTE WATER MANAGEMENT
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Proyecto financiadoPor la Unión Europea
1. Cooperation and Business opportunities. Waste water Management
There are a total of 2 892 treatment plants that are currently in operation, but there exist significant competitive and technological gaps.
Needs and gaps in function of the Wastewater management cycle
WASTE WATER MANAGEMENT
Primary Treatment Processes
• Only 9.33% of all wastewater treatment plants employ septic tanks
• Market Potential here is EXTENSIVE
Secondary Treatment Processes
• Opportunity to optimize adopted configurations to maximize the efficiency
• The largest wastewater treatment facilities, all use non-membrane secondary process (GWI 2010).
• A disinfection step is required due to limitations in suspended solids removal.
Tertiary Treatment Processes
• Low Carbon Technologies in Urban Wastewater Treatment will potentially come from tertiary treatment technologies to:
- Recover nutrients
- Increase energy efficiency
- Recover energy
- Allow water to be reused
- Treat water at source (Modular wastewater treatment technologies)
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Proyecto financiadoPor la Unión Europea
C) Energy Efficiency
in Building
•Mexico ranks 16th from 16 largest economies in the Energy Efficiency Scorecard*
Dimension: 97,000 companies
General remarks
D) Energy Efficiency
in Industry
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Proyecto financiadoPor la Unión Europea
C) Energy Efficiency in
Building
•Key Areas Energy Efficiency in Building (non-residential):
•Building envelope: insulation tech., air sealing technologies, advanced thermal comfort technologies
•Renewable energies: nowadays limited to solar and photovoltaic energy
General remarks
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Proyecto financiadoPor la Unión Europea
1. Cooperation and Business opportunities. Energy Efficiency in Building
Manufacturing of equipment is the sector that stands for the higher number of companies in all federal entities, being Mexico, Puebla and Jalisco the states where there are more companies
Heat map of the concentration of companies related to energy efficiency*
Source: Elaborated by the authors based on data from DENUE
Main business segments considered in Energy Efficiency
• Utilities: companies aimed at selling energy • Industry: companies that producing goods aimed at
transforming energy or at improving efficiency Architecture, engineering and consultancy companies: service companies aimed at designing infrastructures or buildings
• Building, installation and maintenance companies: aimed and building infrastructures or buildings that consume energy, and to ensure their availability.
• ICT companies: a small percentage of ICT companies develop oriented software or hardware
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Proyecto financiadoPor la Unión Europea
1. Cooperation and Business opportunities. Energy Efficiency in Building
The American Council for an Energy Efficiency Economy (ACEEE), Mexico ranks in the 16th position (from 16) in the Energy Efficiency Scorecard
Conclusions the Energy Efficiency in Building in Mexico
•Mayor opportunities for cost-effective greenhouse gas emissions reductions
•Patterns of energy efficiency in buildings vary from one region to another, influenced by factors: climate, economic level., regulation and energy sources
•20% of Mexico City total greenhouse gas emissions come from buildings. Consumption increased from 17% in 2000 to 20% in the 2010
•Building mandatory NOM codes (12 in total) that apply in the entire country, are delegated to local authorities, unable to monitor their implementation.
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Proyecto financiadoPor la Unión Europea
1. Cooperation and Business opportunities. Energy Efficiency in Building
Structure of Energy Efficiency technologies in Building
• xxxxxxx
• 1.1. SHADING
• 1.2.1 WINDOWS: DOUBLE-GLAZED LOW-E GLASS
• 1.2.2 WINDOWS: FILMS /ATTACHMENTS
• 1.2.3 WINDOWS: HIGHLY INSULATING WINDOW (TRIPLE-GLAZED,... )
• 1.3 ROOFING
• 1.4.1 INSULATION: TYPICAL
• 1.4.2 INSULATION: ADVANCE
• 1.5 AIR SEALING
A1. BUILDING ENVELOPE
• 2.1 LUMINAIRES
• 2.2 LIGHTING CONTROL
• 2.3 APPLIANCES & ELECTRONICS
A2. LIGHTING & APPLIANCES
• 3.1 VENTILATION
• 3.2 THERMAL COMFORT
• 3.3 SENSORS/CONTROLS
A3. ENVIRONMENTAL QUALITY
• 4.1 PLUMBING FIXTURE & FITTINGS
• 4.2 WATER HEATERS
• 4.3 METER WATER SYSTEMS
• 4.4 ON-SITE/OFF-SITE TREATED WASTEWATER
• 4.5 RAINWATER HARVESTING SYSTEM
A4. WATER USE
• 5.1 POWER SUPPLY
• 5.2 GAS
A5. ON-SITE ENERGY
• 6.1 SOLAR PANEL
• 6.2 PHOTOVOLTAIC PANEL
• 6.3 BIOMASS
• 6.4 WIND
• 6.5 GEOTHERMAL
A6. ON-SITE RENEWABLE ENERGY
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Proyecto financiadoPor la Unión Europea
1. Cooperation and Business opportunities. Energy Efficiency in Building
Opportunities to develop and provide solutions/technologies in Energy Efficiency in Building
Needs and gaps in function of the Energy Efficiency in Building
Building Envelope
• Double glazing is available in Mexico
• Business Opportunities for European Companies:
- Insulation Technologies
- Air Sealing Technologies
- Advanced Thermal Comfort Technologies
Renewable Energies
• Need of incorporating new technologies (Opportunity for European Companies)
• Current technologies (Law but not monitored):
- Solar
- Photovoltaic Energy
Lighting & Appliances
• Residential and non-residential sectors are integrating energy efficitcy lighting and electronic devices.
• There is a growing market regarding LED luminaries in building and popular housing
Environmental Quality
• HVAC systems may account for more of 40% of the building total power consumption.
• Water efficiency is also basic when defining a HVAC building system. Almost in all regions in Mexico washed air cooling systems are used (evaporative cooling).
Water Use
•Local rules regarding water reusing and water treatment.
•The most important gap regarding water cycle in a building comes from domestic hot water generation. In Mexico, and based on cost reduction(electrical boiling)
On-site energy
• Gas as an alternative for electrical power supply (Cogeneration / Trigeneration), is still an incipient technology for buildings in Mexico.
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Proyecto financiadoPor la Unión Europea
D) Energy Efficiency in
Industry
•Key Areas renewable energy in Industry: •Cogeneration•Waste Valorization
•Higher business opportunities: combustion and air compressed generation, steam and HVAC*
•Law of Energy Transition (12/2015)
General remarks
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Proyecto financiadoPor la Unión Europea
1. Cooperation and Business opportunities. Energy Efficiency in Industry
Conclusions the Energy Efficiency in Industry in Mexico
•Mexico’s industry stands for 29.9% of the GDP (2009), and is the second sector in energy consumption (25.7% of gross domestic energy supply nationwide).
•Oil accounts for 55% of the energy mix, but the proportion of natural gas grew from 20% in 2000 to 30% in 2010
•Electricity generation from wind has risen sharply in recent years, although it accounted for only 2.6% of generation from renewables in 2010. Overall, the share of renewables in electricity production declined from 20% in 2000, to 18% in 2010.
•The National Program for Sustainable Use of Energy 2009-2012 promoted the development of cogeneration in industry. The cogeneration capacity in 2009 was of 2,800 MW, but it was expected to increase to 3,500 MW in 2014
•The new energetic transition law (“Ley de Transición Energética” 24/12) will track the public initiatives focused on changing the industrial energetic model
The new energetic transition law (“Ley de Transición Energética” 12/2015) will track the public initiatives focused on changing the industrial energetic model
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Proyecto financiadoPor la Unión Europea
1. Cooperation and Business opportunities. Energy Efficiency in Industry
Biomass is the most-used primary renewable fuel (48%), but hydro is the largest source of renewable electricity at 78%, followed by geothermal energy with 14% (OECD. 2013)
Structure of primary energy production (2013)
Fossil fuels88,03%
Nuclear energy1,36%
Carbon3,50%
Biomass4,20%
Hydroelectric1,12%
Geothermal 1,46%
Wind0,23%
Biogas0,02%
Solar0,08%
Renewable 0,0711
Fosseil fuels Nuclear energy Carbon Biomass Hydroelectric Geothermal Wind Biogas Solar
Source: 2012 Diagnóstico Básico para la Gestión Integral de los Residuos, INECC, SEMARNAT.
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Proyecto financiadoPor la Unión Europea
1. Cooperation and Business opportunities. Energy Efficiency in Industry
LAERFTE (Ley para el Aprovechamiento de energías renovables y el financiamiento de la transición energética) defines the limits of generationbased on fossil fuels: 65% in 2024, 60% in 2035 and 50% in 2050
Note+ : Chihuahua, Chiapas, Guerrero, Hidalgo, Jalisco, Mexico, Michoacán, Nayarit, Oaxaca, Puebla, Sinaloa, San Luis Potosí, Sonora and Veracruz.
Situation of the Renewable Energies
Biofuels
there is an installed capacity of production based on chaff of
184.2MW, while biogas represents 43.8MW.
Efficient cogeneration
Nowadays PEMEX is able to produce 367.4MW, and has de permissions needed to reach
1,587.12MW.
Eolic energy
In the period 2013-16, installed capacity in the South-East region is
expected to reach 1.216MW. Projects planned in Baja California,
Oaxaca and Tamaulipas.
Geothermal energy
in 2013, the installed capacity was 823.4MW, but there are different plants in construction in Nayarit
and other regions.
Hydraulic energy
Total capacity managed by CFE is 286.6MW, concentrated in 14
federal entities
Solar energy
Mexico is one of the 20 countries in the world according to their
installed capacity.
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Proyecto financiadoPor la Unión Europea
1. Cooperation and Business opportunities. Energy Efficiency in Industry
According to energy efficiency experts*, the Mexican industry has a potential to reduce its energy consumption in 15%, achieving 30% in some cases
The National Energy Strategy 2013-2027 is the referent national policy
Identification of the reduction potential of Industrial sectors in
Mexico
The sectors with a higher potential to reduce energy consumption are
•Chemicals, petrochemicals and paper (between 20% and 25%)
•Iron and steel (between 10% and 14%)
•Cement (between 4% and 8%)
Source* http://www.cnnexpansion.com/manufactura/tendencias/industria-eficiencia-energetica.
National Energy Strategy 2013-2027
Energy Sectorial Programme 2013 –2018 (PROSENER). to extend the use
of clean and renewable energy sources, energy efficiency and environmental responsibility
Sustainable Energy Fund (Fondo de Sustentabilidad Energética, FSE. Allocation of 0.63% of the annual
value of oil crude and gas to research and development activities on energy.
In 2013, only 2% of the FSE budget was used for energy efficiency projects
(USD 3.1 million) (SENER. 2015)
Programme of Energy Savings in the Electricity Sector (Programa de Ahorro de Energía del Sector
Eléctrico, PAESE) is managed by (Comisión Federal de Electricidad,
CFE). It aims to promote energy savings and efficient energy use in CFE’s production and distribution
Programme for Financing of Electric Energy Saving (PFAEE). The
Programme finances the substitution of old, inefficient refrigerators and air-conditioners with modern and more
efficient equipment
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Proyecto financiadoPor la Unión Europea
1. Cooperation and Business opportunities. Energy Efficiency in Industry
Structure of Energy Efficiency technologies in Industry
• xxxxxxx•1.1. BOILERS AND TURBINES
•1.2. THERMICAL TECHNOLOGIES
•1.3. COOLING TECHNOLOGIES
•1.4. NEW HOT TECHNOLOGIES
•1.5 INDUSTRIAL WASTE TECHNOLOGY
A1. SPECIFIC PRODUCTION TECHNOLOGY
•2.1 COMBUSTION
•2.2 AIR COMPRESSED GENERATION
•2.3 STEAM
•2.4 HVAC
•2.5 DRYING,SEPARATION AND CONCENTRATION PROCESSES
A2. INDUSTRIAL PROCESSES
•3.1 ELECTRIC POWER GENERATION
•3.2 TRANSMISSION
•3.3 DISTRIBUTION
•3.4 OPTIMISATION OF POWER CONSUMPTON
A3. ELECTRICAL & ELECTRONIC SYSTEMS
•4.1 THERMICAL STORAGE
•4.2 ELECTRICAL STORAGE
•4.3 WATER STORAGE
•4.4 MECHANICAL STORAGE
A4. POWER STORAGE
•5.1 BIOMASS
•5.2 PHOTOVOLTAIC
•5.3 WIND ENERGY
•5.4 SOLAR THERMAL APLICATIONS
•5.5 GEOTHERMAL TECHNOLOGY
•5.6 WAVE ENERGY
•5.7 HYDRO POWER
A5. RENEWABLE ENERGY
•6.1 COGENERATION INSIDE AND/OR OUTSIDE THE INSTALLATION
A6. COGENERATION
•7.1 USE OF WASTE
A7. WASTE
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Proyecto financiadoPor la Unión Europea
1. Cooperation and Business opportunities. Energy Efficiency in Industry
The Law on Energy Transition will foster the use of renewable energies (1/2)
Needs and gaps in function of the Energy Efficiency in Industry
Business Opportunities for European Companies:
• Renewable Energies
• Cogeneration
• Waste Valorization
The Law of Energy Transition has put the focus on Energy Consumption
Most of the industrial sectors are interested in improving their energy efficiency
Transversal Technologies can be applied to several industrial sectors
• Combustion and Air Compressed Generation
• Steam
• HVAC (Heating, Ventilating and Air Conditioning)
• Drying systems
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Proyecto financiadoPor la Unión Europea
1. Cooperation and Business opportunities. Energy Efficiency in Industry
The Law on Energy Transition will foster the use of renewable energies (2/2)
Needs and gaps in function of the Energy Efficiency in Industry
Specific Production Technologies
•INDUSTRIAL WASTE TECHNOLOGY
•THERMICAL TECHNOLOGIES
•INDUSTRIAL WASTE TECHNOLOGY
Industrial Processes
•COMBUSTION
•AIR COMPRESSED GENERATION
•HVAC
•DRYING,SEPARATION AND CONCENTRATION PROCESSES
Power Storage
•ELECTRICAL STORAGE
•WATER STORAGE
Electrical & Electronic Systems
•TRANSMISSION
•DISTRIBUTION
•OPTIMISATION OF POWER CONSUMPTON
Renewable Energy
•BIOMASS
•WIND ENERGY
Cogeneration
COGENERATION INSIDE AND/OR OUTSIDE THE INSTALLATION
Waste valorization
•USE OF WASTE DERIVED FROM TRANSFORMATION PROCESSES
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Proyecto financiadoPor la Unión Europea
2What is LCBAM’s contribution to MEX and EUR entities?
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Proyecto financiadoPor la Unión Europea
2. What is LCBAM’s contribution to MEX and EUR entities?
… During LCBAM… …In the future
40 CPAsTechnical assistance for
the identification of potential EUR-MEX partners
Organisation of a 3-day working
agenda (B2B, technical visits),
etc.
The EUR logistic costs (Flight + accomm.) are
covered!
Access to high-intensity grants for
Project managmenet
Potential fast-track to “LCBAM certified”
initiatives
38
Proyecto financiadoPor la Unión Europea
3How to participate?
39
Proyecto financiadoPor la Unión Europea
FACE-TO-FACE
MATCHMAKING
FACE-TO-FACE
MATCHMAKING
SELECTION OF ENTITIES
ON LINE MATCHMAKING
SELECTION OF ENTITIES
ON LINE MATCHMAKING
ONLINE AND FACE-TO-FACE MATCHMAKING
APPLICATION FORMAPPLICATION FORM
3. How to participate?
40
Proyecto financiadoPor la Unión Europea
How to participate?
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