We develop innovative and sustainable operational solutions for renewable energy, CCUS, CCS, and carbon credits. Our primary activity is the development of integrated solutions for environmental characterization, implementation of carbon capture and storage technologies, and carbon credit management in renewable energy and emission reduction projects. Through the integration of advanced data collection technologies, intelligent analysis algorithms, and carbon mitigation strategies, we ensure the effectiveness and sustainability of these projects. We utilize cutting-edge technologies such as remote sensing, continuous monitoring systems, and advanced data analysis methods to assess and characterize the environment in which projects will be implemented. Additionally, we develop and implement efficient and secure carbon capture and storage systems, as well as emissions offset strategies through the generation and management of carbon credits. Our expertise, commitment to sustainability, innovation, and quality position us as leaders in providing solutions for renewable energy, CCUS, CCS, and carbon credits. We are dedicated to making a significant contribution to the transition to a low-carbon economy by delivering high-performance, cost-effective, and environmentally responsible operational solutions.
Is to provide comprehensive and integrated solutions for environmental characterization, implementation of carbon capture and storage technologies, and carbon credit management throughout the lifecycle of renewable energy and emission reduction projects. We are committed to developing and implementing advanced data collection tools, intelligent analysis algorithms, and carbon mitigation strategies to ensure the effectiveness and sustainability of these projects.
Our aim is to lead the development of sustainable and efficient operational solutions for renewable energy projects, CCUS (Carbon Capture, Utilization, and Storage), CCS (Carbon Capture and Storage), and carbon credits. We seek to drive the advancement of these initiatives by offering innovative technologies that promote environmental preservation, CO2 emissions reduction, and operational efficiency.
Our aim is to lead the development of sustainable and efficient operational solutions for renewable energy projects, CCUS (Carbon Capture, Utilization, and Storage), CCS (Carbon Capture and Storage), and carbon credits. We seek to drive the advancement of these initiatives by offering innovative technologies that promote environmental preservation, CO2 emissions reduction, and operational efficiency.
We work with wind, solar, geothermal, biomass and ocean energy.
Team of engineers specialized in oil, gas and renewable energy projects..
Multidisciplinary team to operate and maintain the project.
This research project proposes the development of a solids reinjection cell and a risk analysis simulator to optimize gravel reinjection projects in oil wells in Brazil. Gravel reinjection is an environmentally effective approach to eliminate drilling fluid waste, however, it requires a deep understanding of the geological and geomechanical characteristics, along with a comprehensive analysis of associated risks. The partnership between a research institution and an environmental solutions company aims to integrate academic expertise with practical field experience. The objectives include developing laboratory equipment to determine optimal reinjection rates, creating a risk analysis simulator, conducting geomechanical and petrophysical studies to identify suitable receptor formations, among others. The methodology spans from literature review to result validation, including laboratory and field tests. The project is expected to produce a robust and reliable solution, contributing to the environmental and operational sustainability of the oil industry, while promoting more sustainable and responsible practices.
This project focuses on the feasibility analysis of injecting carbon dioxide (CO2) in hydrate form into porous geological formations as a strategy to reduce greenhouse gas emissions from oil production. CO2 is a common byproduct in oil production, especially in Brazilian pre-salt reservoirs, and its atmospheric emission is detrimental due to its role in global warming. The study aims to test in laboratory the injectivity of this CO2 in hydrate form using a method known as coreflooding, aiming to understand the effectiveness and safety of this process for potential industrial-scale applications. The ultimate goal is to contribute to the development of more effective and environmentally sustainable carbon capture and storage (CCS) techniques in the oil industry.
Submarine Exploration: Technological Innovations for Mapping Benthic Communities and Restoration of Seaweed and Corals in the Shallow Portion of the Pernambuco/Paraíba Basin Abstract: This project aims to map the diversity of benthic habitats in shallow marine ecosystems using satellite and aircraft remote sensing data. Focusing on coastal regions of Paraíba, it seeks to identify specific characteristics of coral reefs and submerged seaweed. Robust mapping methodologies and classification algorithms, such as SVM, RF, and KNN, will be applied. The results obtained in Phase 1 will be used to estimate the biomass growth rate of corals. In subsequent phases, the project aims to develop and implement techniques for replanting seaweed and coral polyps to restore the ecosystem and generate carbon sequestration growth models.
This project aims to develop a continuous conversion system of thermal energy, derived from solar water heating or geothermal water sources, into electrical energy. The goal is to harness small temperature differences to convert thermal energy into electricity sustainably. Although challenging, the research purpose is to explore thermodynamic limits, innovate, contribute to energy sustainability, educate, and develop knowledge. The proposed project is at the technology readiness level TRL 3 and represents a sustainable solution for generating up to 1000 W of electricity per motor, with no greenhouse gas emissions.
The offshore wind farm market has been growing globally, driven by vast and dispersed wind resources, demand for sustainable energy, and cost reductions. In Brazil, wind energy represents a significant portion of the energy matrix, with a projected growth to 30 GW by 2024, mainly in the Northeast region. Rio Grande do Norte stands out as the country's largest producer of wind energy but faces environmental challenges, especially related to the installation of wind turbines and submarine cables. The literature highlights the need for multidisciplinary approaches to address potential environmental impacts, as well as the transfer of knowledge from the oil and gas industry to the wind sector. More suitable and low-cost operational solutions are required, especially for shallow-water operations, to reduce carbon emissions and address specific challenges of this environment. With this purpose in mind, we have created the CMBC project.
We develope solutions to reduce emissions and mitigate climate changes.
We have a SME team dedicated to deliver accurated consulting solutions for identify climate risks and propose sustainable de- risks solutions.
Real Time Remote Monitoring Solutions with technical expertise and advantage data interpretation and modelling.
The key to an emissions-free world, driven by the inexhaustible force of nature.