Carbon Capture, Utilisation, and Storage (CCUS) is a comprehensive approach aimed at mitigating carbon dioxide (CO2) emissions from various sources, such as industrial processes and power generation, to combat climate change. CCUS encompasses three main components:
Carbon Capture: This involves capturing CO2 emissions from point sources, such as power plants and industrial facilities, before they are released into the atmosphere. Various technologies, including post-combustion capture, pre-combustion capture, and oxy-fuel combustion, are employed to separate and capture CO2.
- Feasibility study
- Generation licence/Quota approval
- Costing (EPCC, Operations & Maintenance)
- Commercial contract binding
- Standard EPCC scope of work
- Engineering design based on plant requirements
- Approvals: ST, SEDA, GreenTech, MIDA, etc.
1. Preliminary Engineering
- Competent operators (Engine drivers, chargemen)
- Skilled operators
- Performance data collection, analysis. etc
- Scheduled services on assets (Asset management)
- E-billing, collection, forecast operation and budget
- Annual calibration, testing and others
- Insurance and safety
- Service and maintenance contract (STSA/LTSA)
- Inventory management
- Preventive/corrective maintenance,upgrades, etc.
- Skilled service technicians and engineers
- Manufacturer’s recommended original tools
- Workplace-aided tools (Inspection, schedule, etc.)
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A hydroelectric power plant, often referred to as a hydro plant, is a facility designed to generate electricity using the energy of flowing water. The basic principle behind a hydro plant involves the conversion of kinetic and potential energy of water into mechanical energy, which is then transformed into electrical energy through generators.
Carbon Credit Trading
Carbon credit trading, also known as carbon offset trading, is a market-based approach aimed at reducing carbon emissions by allowing entities to buy and sell credits representing reductions in greenhouse gas emissions. This practice aligns with renewable energy initiatives and sustainability goals. Here's a brief summary of carbon credit trading in relation to renewable energy.
Biomass is a renewable energy source derived from organic materials, such as wood, agricultural residues, and even dedicated energy crops. These materials can be converted into heat, electricity, or biofuels through various processes like combustion, gasification, or biochemical conversion. Here's a summary of biomass energy, its output, and advantages:
Biomass energy involves the utilization of organic materials to produce heat, electricity, or biofuels. This energy source can be derived from a variety of sources, including agricultural waste, forestry residues, municipal solid waste, and dedicated energy crops like switchgrass and miscanthus. Biomass energy technologies encompass a range of conversion methods, each offering distinct benefits and applications...
Renewable Energy Certificate (REC)
Renewable Energy Certificates (RECs), also known as Green Certificates or Tradable Renewable Certificates, are market-based instruments that represent the environmental attributes and benefits associated with generating electricity from renewable sources. RECs provide a way to track and quantify the production and consumption of renewable energy and are used to support renewable energy development and sustainability goals.
Solar energy is a renewable and abundant source of power derived from the sun's rays. It is harnessed using various technologies to convert sunlight into electricity or heat. Solar power offers significant environmental benefits and has gained prominence as a key component in the transition to cleaner energy sources.
Carbon Capturing Utilisation And Storage (CCUS)
Hydrogen, often referred to as the "fuel of the future," is an energy carrier that has gained increasing attention due to its potential to address energy challenges and contribute to a more sustainable energy landscape. Hydrogen can be produced through various methods and used as a versatile fuel in a wide range of applications. Here's a summary of hydrogen energy and its implications for energy efficiency:
Hydrogen is an element that, when used as a fuel, emits only water vapor as a byproduct, making it a clean and environmentally friendly energy source. It can be produced from various feedstocks, such as water, natural gas, and biomass, through processes like electrolysis, steam methane reforming, and biomass gasification...
Sustainable Airline Fuel (SAF)
Operations And Maintenance
Energy efficiency refers to the practice of using less energy to achieve the same level of output, whether it's in homes, industries, transportation, or other sectors. It involves adopting technologies, strategies, and behaviors that minimize energy waste and maximize the utilization of available resources.
Waste-to-energy (WTE) is a process that involves converting various forms of waste materials into usable forms of energy, such as electricity, heat, or biofuels. This approach not only reduces the volume of waste going to landfills but also harnesses the energy potential of waste for various applications. Here's a summary of waste-to-energy:
Waste-to-energy is a sustainable solution that involves the conversion of waste materials, including municipal solid waste, industrial waste, and biomass, into energy. The process utilizes different technologies to extract energy from waste while minimizing environmental impacts...
Biogas is a renewable energy source produced through the anaerobic digestion of organic materials, such as agricultural waste, food scraps, and sewage. It is primarily composed of methane and carbon dioxide, and can be used as a clean fuel for electricity generation, heating, and cooking.
"LimaLima is on a mission to lead the charge in sustainable energy solutions, reshaping the world's energy landscape in perfect harmony with the Paris Agreement and 'Fit for 55' objectives. With relentless dedication, we pioneer innovative renewable technologies to significantly reduce global carbon emissions. Our unwavering commitment extends to crafting a healthier, more sustainable home for current and future generations. We firmly believe that renewable energy holds the transformative key to a brighter future, and at LimaLima, we are here to unlock its vast potential."
Sustainable Airline Fuel (SAF) is a critical component of the aviation industry's strategy to reduce its environmental footprint and address the pressing issue of climate change. SAF, also known as aviation biofuel or alternative aviation fuel, represents a departure from traditional fossil-based jet fuels towards more environmentally friendly options.
Key points regarding Sustainable Airline Fuel (SAF):
Origin and Composition: SAF is derived from sustainable and renewable sources, such as biomass, waste materials, or hydrogen. Common feedstocks include agricultural residues, algae, used cooking oil, and even municipal solid waste. These feedstocks are processed to create aviation fuels that can be blended with or used in place of traditional jet fuels like Jet A or Jet A-1.
Environmental Benefits: The primary motivation behind SAF is its significantly lower carbon footprint compared to conventional jet fuels. When produced and used correctly, SAF can result in substantial reductions in greenhouse gas emissions. This reduction arises because SAF feedstocks often involve the absorption of CO2 from the atmosphere during their growth or production, effectively making the aviation industry more carbon-neutral.
Energy storage is a critical component of modern energy systems, enabling the capture, storage, and efficient use of electrical energy for various applications. It plays a pivotal role in addressing the challenges posed by intermittent renewable energy sources, grid stability, and the overall transition to a cleaner and more sustainable energy landscape. Here's an in-depth look at energy storage:
LIMA LIMA GROUP (LLG) is an established provider of renewable energy solutions that is principally involved in businesses related to the use of biomass to produce renewable energy. We are also a service and solutions provider for the telecommunications industry. Our core competencies are in the following 6 sectors:
"At LimaLima, we envision a radiant future—a carbon-neutral world where the brilliance of renewable energy sources guides progress. Positioned at the forefront of this transformative journey, we set unmatched benchmarks for environmental stewardship and sustainability. With an unyielding commitment to the principles of the Paris Agreement and 'Fit for 55,' we strive to forge a future where clean energy is universally accessible, carbon emissions are minimized, and the global community is resilient to the challenges of climate change. LimaLima isn't just a company; it's a beacon of hope, illuminating the path towards a greener, more prosperous planet."
1. Parts Centre
2. After Sales Service
We have a proven track record serving our strong and diverse customer base of local and international clients.
4. Facility Managememt
5. Precision Engineering
1. Importance and Context:
Renewable Energy Integration: Energy storage systems are instrumental in integrating renewable energy sources like wind and solar into the grid. These sources generate power intermittently, and energy storage helps bridge the gap between energy production and demand, ensuring a stable and reliable electricity supply.
Grid Resilience: Energy storage enhances grid resilience by providing backup power during outages, reducing downtime, and preventing disruptions caused by extreme weather events or equipment failures.
Why Choose Lima Lima?
Responsive And Reliable
Highly Qualified Engineering And Support Team
Track Record With Proven Results
Affordable Solutions And Services To Suit Every Budget
Power Plant Installed Capacity
Number of Installations
CO2 Reduction Annually (Kg)
Group of Companies
“A transition to clean energy is about making an investment in our future.”
Gloria Reuben, actress and environmental activist
- United Nations Framework Convention on Climate
Change (UNFCCC), Clean Development Mechanism
(CDM) and Joint Implementation (JI)
- International Renewable Energy Agency (IRENA)
- European Union Emissions Trading System (EU ETS)
- Renewable Energy Guarantees of Origin (REGO)
- International Renewable Energy Agency (IRENA)
- Clean Development Mechanism (CDM) and Joint
- Clean Energy Regulator (CER)
- Renewable Energy Target (RET)
- Large-scale Renewable Energy Target (LRET) and the
Small-scale Renewable Energy Scheme (SRES)
Preliminary engineering is the first stage in project development. This is the stage when designers and project planners conduct early project-level planning and develop an overall design concept of what the new facility would look like. At this stage, projects that are identified in systems planning are handed over to the respective project planners and designers to further develop the project.
The main objective is to identify ways to implement the project, and develop appropriate plans and design concepts. Therefore, during preliminary engineering more project-specific information is collected and synthesized.
In preliminary engineering, planning is done at the project-level to identify and develop ways to implement the solution, identify potential issues/obstacles, and develop an implementation concept for the project. The focus of preliminary engineering is to identify ways to implement projects.
Preliminary engineering is also referred to as the first stage of design, whereas project design is an iterative process with several design stages.
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