1.1 Programmable Controllers for water treatment plants with multiple cycle condensation
1.2 Robotics, Automation and monitoring critical plant variables using integrated and hierarchical models
1.3 Process Line Control for the characterization of products in real time, using models and selective sensors
1.4 Electric positioner of loads with remarkable accuracy and energy efficiency, powered by batteries of lithium iron phosphate and servo hydraulic block with PWM feedback

2.1 Technology for the development of microprocessor control pellet boilers and turbo air distribution of 30kw and performance to 85%
2.2 Technology for the development of automatic systems feeding pellet with sensors and electric motors for industrial applications
2.3 Technology boiler of return circulators and motorized valves and buffer tanks to improve productive life
2.4 Technology for the anaerobic decomposition of biomass into biogas by bacteria, followed by drying, filtration, desulphurisation, enrichment, particle separation and purification

3.1 Development of catalytic isomerization for process oriented to production of gasoline with high NO and cracking process optimization
3.2 Technology for H2 production using catalyzed decomposition of light hydrocarbons by mesostructured carbons materials
3.3 Developing technology of silicon nanostructured catalysts designed to improve the photovoltaic conversion efficiency of solar panels, as well as to catalyze the production of electricity in the fuel cells
3.4 Developing technology of niobium oxide catalyst with a microporous structure and intended to be accommodated in the zeolite framework to configure active walls in reversible redox process
3.5 Developing technology of tin catalysts housed in frames beta zeolite having a higher efficiency than the enzymes for the conversion of biomass to sugars fructose. They can also work in harsh environments and acid pH
3.6 Developing new technology of lithium bismuth composites with remarkable change in the transition between the energy levels as insulator – conductive material. Activation under influence of pressure and temperature combinations
3.7 Technology development of new generation of nano-wire based LED GaN. This involves knowing to modify emitting surface flat thin film circuit, by the cylindrical shape one. Get a special adaptation to energy transformation with the subsequent improvement in the LED light brightness

4.1 Blades Modeling Technology, selection of nanoalloys and control electronics for developing micro turbines and turbines in combined cycle plants
4.2 Development Technology of accumulators with electronic storage temperature difference, flow meter and multi-functional cutoff device
4.3 Modelling Technology of proportional power control in the continuous system Bus, via voltage regulation and improved of total harmonic distortion THD rates ​​<1%

5.1 Thermodynamic solar cooling technology by absorption or compression by combining thermal lithium bromide and water
5.2 Technology of combined usage of condensing boilers with solar thermal panels to yield significant improvement in heating and sanitary hot water
5.3 Technology modeling and calculation the energy efficiency by the joint use of solar thermal and installing adequate insulation
5.4 Heat pump technology with high efficiency coefficient (6) by the usage of low temperature emitting elements and photovoltaics panels
5.6 Technology for calculating and sizing probes and horizontal- vertical collectors in ground-water heat pump systems
5.7 Technology of rotating heat exchangers with high efficiency
5.8 Technology of power modulating Pumps for electronically controlled Boilers with high power variation ratio of up to 1:10

6.1 Wood drying technology using uniform moisture absorption evaporator, heat pump and condenser
6.2 Drying technology and malt controlled germination by heat pump vapor compression for Brewing and whiskey
6.3 Dehumidification and cured Technology sausages by compression heat pump with electric motor and reversal of roles between the evaporator and condenser
6.4 Regenerative technology in the production process of bread by exchangers and heat pump
6.5 Technology growth of farmed marine species by using heat pump water- water which compresses steam by electric motor
6.6 Technologies of mechanical vapor recompression and separation by distillation, for chemical and petrochemical industry with heat pump
6.7 Technology for waste heat recovery in metallurgy by transformer set with heat pumps and heat exchangers

7.1 Solar Desalination Technology thermocompressors / heat pumps and vacuum assisted multiple effect
7.2 Ultrasonic technology using low power piezoelectric transducers for cleaning algae in ponds and backwaters
7.3 Ultrasonic technologies using high power piezoelectric transducers for MSW disposal in water treatment plants
7.4 Technology surface water purification combining reverse osmosis membranes and exposure to ultraviolet radiation from solar PV
7.5 Chemical technology for nitrate removal of groundwater through selective catalytic hydrogenation

8.1 Technology vacuum flat solar collectors with incorporating a photovoltaic part to activation of the pump and temperature control/variation
8.2 Technology of differential thermostats coupled with proportional valves for flow control on individual facilities
8.3 Regulation and control technology in solar panels of several homes with centralized and distributed support
8.4 Telealarm technology and remote control of solar thermal installations
8.5 Improved technology parabolic trough solar thermal concentrators. Collectors are both heat exchangers and feeding a superheated steam generator connected to a turbine-generator PMSM. The collectors are parabolic, circular or longitudinal and guidance can be provided with fixed or variable (with solar tracking)
8.6 Enclosures design Technology of high thermal efficiency (Trombewall) for energy management of day-night in shelters and other buildings in desert or high mountain and generally with high thermal gradients between day and night
8.7 Developing technology and energy storage of improved heat exchange efficiency in the parabolic trough or heliostat models by circulating sand at 1200 ° C. It means a remarkable improvement with respect to the molten salt ones
8.8 Developing technology for capturing solar thermal and photovoltaic simultaneously with high efficiency by depositing antimony telluride on dimensionally nanostructured substrate of the same material. Unidimensionado optimizing the energy uptake is related to the wavelength of solar radiation

9.1 Technology IGBT inverter high efficiency and low harmonic distortion, 3phase and 3G communication
9.2 Technology autonomous photovoltaic system equipped with night lighting panel, controller, battery, lamp or light motion detector
9.3 Technology development of photovoltaic energy conversion high yield (50%) through the use of organic-inorganic interfaces nanoscale
9.4 Technology development of transparent ternary oxides in preparation for photovoltaic energy conversion as efficiently as possible
9.5 Technology development of solar energy photovoltaic solar panels with high efficiency through nanostructured Fe2O3 particles arranged in layers so as to promote energy absorption by such molecules
9.6 Developing technology polymer photovoltaic cell in which self-assembly or by controlled growth from the molecular level causes the appearance of approximately 10 nm nanochannels with plenty of electrical current flow. Technology keeps said channels for preventing life merging between them, which would mean loss of the high efficiency achieved in the photovoltaic conversion
9.7 Technology Development of solar capturers designed to meet or exceed the “natural sensors” of sunlight that perform photosynthesis and chlorophyll function of plants. They cover three areas of R & D. The first investigates the molecular and cyanobacteria pigments or the like. The second is to identify the most efficient configuration or biohíbridal bacterial antenna on an inorganic surface. The third section investigates how to capture the largest possible range of the electromagnetic spectrum
9.8 Technology (upgrade stage) for photovoltaic conversion by semiconductor junctions PbS and ZnO-efficient technique using nanoscale colloidal. Efficiency is maintained for about 1000 hours of operation
9.9 Technology development of graphene self-assembled solar cells with complementary shapes and defining interlocking interfaces in photoactive nanostructures. Both the anodes and cathodes are used by transparent graphene. Load transfer is the result of “contact doping.” Efficiency can reach 30% because it is built from the molecular level

10.1 Wind turbine technology with direct torque control for power between 450kW and 2.5 Mw, water or air cooling and voltages up to1700v
10.2 Technology until 50kw autonomous wind turbine optimizing the resisting torque under no-load conditions (cogging torque) through the development of non-uniform air gaps. It is also possible to optimize the operation by a variable angular displacement between the rotor poles and stator

11.1 Technology Network configuration (Grid) connecting smart- simultaneously various renewable energy sources (including biogas) and conventional multiple receivers (including air conditioning)
11.2 Electronic technology for dynamic control of electrolysis operations providing modularity and mitigating potential fluctuations of a solar or wind variable generation
11.3 Electronic technology for electrolyzers control, capable of specifying purity H2 produced (by removing the generated one in the first seconds), while ensuring rapid implementation of the electrolysers and take advantage of all the excess of energy. Overload Capacity up to 200% for short periods
11.4 Variant of electronic technology to fast start of electrolyzers ,intended to conversion and storage of H2; stabilizing the DC bus in a remote or isolated network versus its load variations

12.1 Technology of carbon membranes combined with palladium thin membranes for selective separation of H2; conducted through natural gas pipelines for storage or electricity production by fuel cells
12.2 Technology Development of electrochemical H2 separation procedure in pipelines natural gas through Nafion membranes for low H2 pressures (concentrations 8-10%)
12.3 Development technology of comparative gravimetric Analysis and / or volumetric density over the storage capacity of hydrogen in borides and nitrides of ammonium or metal alloys (lithium or other alkali). Also on amines or carbozoles
12.4 Filtration and purification technology of H2 for fuel cells by double circuit high and low pressure flow rate control. Includes proportional valves, electronically programmable via DSP
12.5 Filtering technology, and mass measurement centrifugal compression of air (oxygen) incorporating cooling said compressed air with controlled temperature and humidity thereof. Is performed by intelligent sensors looped stoichiometric control of the stack. Includes expansion loop between membrane humidifier and the compressor equipped with heater to prevent misting
12.6 Improved Technology uptake and direct application to photovoltaic electrolyser cells and proton exchange with polymeric membranes. 2kw scalable modules
12.7 Enhanced photovoltaic conversion Technology and direct application to alkaline electrolyser with automatic control of pH and H2 purity. Electrodes nickel coated steel. 5kw scalable modules
12.8 Technology Development of reversible electrolysers Fuel Cells based on molten oxides and water vapor state with ceramic electrolyte
12.9 Developing technology of molecular sieves for separation of CO2 from thermal power plants of coal and Fuel. Sieve filling implies organometallic material nanostructured and micro porous configuration
12.10 Development of new technology in polymer fuel cells in which the storage and supply of hydrogen is carried out similarly. The H2 is stored using an organic trigonals amine and thereby circulated through the stack. It applies a reverse electrocatálisis separating the hydrogen from the amines to bind oxygen in the act, with release of electrons ; that is the regular operation of the battery
12.11 Technology of improved H2 storage by coordinated compounds of nickel and architecture bipyramidal, trigonal and octahedral amine. The basic process of either formation or storing of these compounds or hydrogen fixe the proton in jointly forms with electrons during electrocatalysis. The reverse process is reinforced with an oxidation which releases H2

13.1 Enzymatic reactor technology for the production of biodiesel from algae diatoms fed jointly with specific nutrients and CO2 from power plants. The plant is partially fed from biodiesel generated in the reactors, enabling a combined cycle with a progressive reduction, within suited limits, of he CO2
13.2 Technology development of artificial photosynthetic devices using nanoporous materials containing peptide bonds at specified positions Redox reactions rise in the molecule water, breaking it down into its components of H2 and O
13.3 Selective oxidation Technology of titanium oxide for cleaning, moisturizing and even organic therapies, by preparing nanoparticles of the same in which the activation energy level has decreased .That is due to the molecular coupling, in shape and size, between the environment and oxidized molecules

14.1 Analysis tool to determine the combination of various conventional and renewable energy technologies, integrated into one application, so as to achieve the most efficient configuration for a particular building in a specific location
14.2 Technology development of mathematical models to simulate the metabolism of biofuel producing plants like Camelina and Clamidonona. The models simulate the energy transformations and accumulation of oil in the algae during seed development. This is to optimize the levels of enzyme which in turn significantly increases the yield in the production of biodiesel