Manage & Analyze Your Solar Plant | Renewable Energy Asset Management - Mahindra TEQO

Manage your solar asset with Mahindra TEQO which offers turnkey asset management solutions that help renewable energy asset owners maximize returns. A fully equipped and expert team to complete the asset management journey without disturbing your peace of mind. Mahindra TEQO aims to enhance value through maximize solar energy generation. 

For more details -  https://www.mahindrateqo.com/services/solar-pv-asset-management/ 

Made-in-India Solar Panels Powering the Nation's Future Learn how Made-in-India solar panels are altering the country's energy destiny. Learn about the benefits of locally manufactured solar technology for sustainability, economic growth, and energy independence. For more: Made-in-India Solar Panels Powering the Nation's Future

Harnessing Innovation: The Impact of Solar Farms and Tokenizing Individual Solar Panels

The intersection of advanced technology and renewable energy is giving rise to exciting new developments, particularly in the realm of solar farms and tokenizing individual solar panels. This combination is not only reshaping how energy is produced but also revolutionizing investment opportunities within the renewable sector. Let's delve into the intricate world of solar farms and tokenizing individual solar panels to understand their transformative potential.

What Are Solar Farms?

Solar farms, or photovoltaic (PV) power stations, are large-scale installations of solar panels designed to generate substantial amounts of electricity. These farms harness solar energy on a massive scale, converting sunlight into electrical power that can be distributed through the power grid. The primary benefits of solar farms include:

High Energy Output: Solar farms can produce vast amounts of electricity, contributing significantly to the power supply.

Sustainability: By generating clean, renewable energy, solar farms help reduce the environmental impact of electricity production.

Economies of Scale: Larger installations can achieve cost efficiencies, making solar energy more affordable.

Understanding Tokenizing Individual Solar Panels

Tokenizing individual solar panels involves creating digital tokens that represent ownership or a stake in specific panels within a solar farm. This concept uses blockchain technology to ensure secure, transparent, and efficient management of these investments. Key aspects of tokenizing individual solar panels include:

Fractional Investment: Investors can purchase tokens representing small portions of solar panels, lowering the barrier to entry.

Blockchain Security: Blockchain provides a tamper-proof ledger for all transactions, ensuring ownership records are secure and transparent.

Tradable Assets: Tokens can be bought and sold on digital marketplaces, offering liquidity to investors.

Benefits of Combining Solar Farms and Tokenizing Individual Solar Panels

The fusion of solar farms and tokenizing individual solar panels offers numerous advantages, creating a symbiotic relationship that enhances both energy production and investment opportunities:

Broadened Investment Base: Tokenization democratizes investment, allowing individuals to invest in renewable energy projects with small amounts of capital.

Increased Funding: More accessible investment opportunities can lead to higher funding levels for solar projects, accelerating development and expansion.

Operational Improvements: Investment capital from token sales can be reinvested into the solar farms, enhancing efficiency and productivity.

Community Involvement: Local residents can invest in nearby solar projects, fostering community support and engagement.

Practical Applications and Future Outlook

Several pioneering projects are already exploring the synergy between solar farms and tokenizing individual solar panels. These initiatives showcase the potential of this innovative approach:

Global Accessibility: Platforms are emerging that enable people worldwide to invest in solar panels located in different regions, promoting global participation in renewable energy.

Smart Contracts and Automation: The use of smart contracts on blockchain platforms can automate revenue distribution, ensuring timely and accurate payouts to token holders.

Data-Driven Transparency: IoT devices can provide real-time data on panel performance and energy production, offering investors detailed insights and fostering trust.

Looking Ahead

The future of solar farms and tokenizing individual solar panels is bright, with several trends poised to drive growth and innovation:

Regulatory Advancements: As governments recognize the potential of decentralized renewable energy investments, supportive regulatory frameworks are likely to emerge.

Technological Integration: Continued advancements in blockchain and IoT technologies will further enhance the efficiency and transparency of solar investments.

Scalability: The success of early projects will pave the way for larger, more ambitious solar farms, attracting even more investors and driving further growth.

Conclusion

The convergence of solar farms and tokenizing individual solar panels represents a groundbreaking shift in the renewable energy landscape. By leveraging blockchain technology, this innovative approach democratizes investment, enhances operational efficiency, and drives the expansion of clean energy projects. As awareness and adoption of these technologies grow, solar farms and tokenizing individual solar panels are set to play a pivotal role in creating a sustainable, energy-secure future.

Captive Power Generation: Key Strategies for Businesses in 2024

As businesses grapple with rising energy costs and the imperative for sustainability, Captive Power Generation (CPG) has become a strategic asset. Not only does it provide energy security, but it also aligns with global efforts to reduce carbon footprints. This article explores the evolution and strategic implementation of captive power systems, focusing on advanced technologies and regulatory landscapes that are shaping the industry today. 

1. Technological Advancements in Captive Power Systems

Captive Power Plants (CPPs) are increasingly incorporating cutting-edge technologies that enhance both efficiency and environmental sustainability. This shift is significantly driven by stringent emissions regulations and the escalating demand for energy independence across industries. Here are some pivotal advancements:

Solar and Wind Integration:

The integration of solar and wind technologies into Captive Power Plants (CPPs) is transforming the landscape of industrial power generation. These renewable sources are not only abundant and free but also produce zero emissions, aligning perfectly with global sustainability goals.

Solar Power Systems: Modern CPPs are integrating photovoltaic (PV) panels to harness solar energy efficiently. Advances in solar technology, such as bifacial panels and solar tracking systems, have significantly improved the efficiency and output of these installations. Solar power provides a reliable daytime energy source that can be coupled with energy storage systems to extend its utility to non-sunlight hours.

Wind Power Systems: Wind power has become a more attractive option for Captive Power Plants (CPPs) due to technological improvements in turbines. Modern turbines are engineered to operate efficiently at lower wind speeds, which broadens their applicability across diverse geographical areas. These advancements allow turbines to be installed directly at industrial sites or nearby, significantly cutting energy costs and bolstering energy security. By producing power on-site, these installations help reduce reliance on the grid and enhance operational resilience.

Combined Heat and Power (CHP) Systems: These systems represent a leap in operational efficiency. By capturing and utilizing waste heat from electricity generation for heating or industrial processes, CHP systems can achieve primary energy savings of up to 80% compared to traditional grid power. This not only optimizes energy use but also substantially cuts energy costs, making it a favored choice for energy-intensive industries​. 

Energy Storage Integration: Modern CPPs are increasingly being equipped with advanced battery energy storage systems. These systems are crucial for managing energy load, providing emergency power during outages, and optimizing energy costs by storing excess power, especially from intermittent renewable sources. The strategic use of energy storage is enhancing the reliability and flexibility of captive power solutions​. 

2. Regulatory and Market Trends

Captive Power Generation regulation is evolving, with a distinct push towards more sustainable and reliable energy solutions. Here’s how recent changes are shaping the market:

Supportive Regulatory Frameworks: Regions like Gujarat & Karnataka have streamlined the setup processes for CPPs with clearer, more favorable captive power generation regulation. Such initiatives are crucial for fostering an environment conducive to the growth of captive power solutions, especially those integrating renewable energy sources​. 

Market Growth Projections: The global market for captive power is on a significant upward trajectory, expected to achieve robust growth by 2030. This growth is supported by increasing industrialization, rising energy costs, and supportive government policies that encourage the adoption of CPPs​. 

Incentives and Financial Support: Governments worldwide are offering various incentives for CPPs, including tax benefits, subsidies, and grants. These incentives aim to reduce the financial burden on businesses and encourage the adoption of sustainable energy practices​. 

3. Strategic Implications for Businesses

The strategic deployment of CPPs is becoming a cornerstone for businesses aiming to ensure energy reliability and cost-effectiveness:

Enhanced Energy Security: By generating their own power, businesses are not only insulated from grid unreliability but also gain control over their energy costs. This is especially vital in regions where energy supply can be sporadic and unpredictable​. 

Cost Management: CPPs allow businesses to lock in energy costs, making financial planning more predictable. This is increasingly important in a global economy where energy prices are volatile and can impact operational budgets significantly​. 

Competitive Advantage: Companies that invest in advanced CPP technologies can achieve greater operational efficiencies, reduce their environmental impact, and enhance their market competitiveness. This strategic advantage is crucial in industries where energy demand and sustainability standards are intensifying​. 

Adaptability: The ability to quickly adapt to changes in energy demand and supply conditions allows businesses to maintain efficient operations without the risks associated with energy price volatility and supply disruptions.

4. Global Adoption and Future Outlook

The global adoption of captive power plants is rapidly increasing, driven by the need for reliable energy solutions and the shift towards sustainable practices. This trend is particularly pronounced in regions like Asia and Africa, where industrial growth often outpaces the development of reliable grid infrastructure. Captive power systems provide a viable solution by enabling businesses to generate their own energy, thereby reducing reliance on unstable power grids and mitigating the risks associated with energy shortages.

Renewable Energy Integration: The integration of renewable energy sources into captive power systems is gaining traction worldwide. Technologies like solar photovoltaics and wind turbines are increasingly being incorporated into captive setups, driven by declining costs and the push for carbon neutrality.

Technological Innovation: Continuous advancements in technology are making captive power plants more efficient and adaptable. Innovations in energy storage, such as battery systems, are enhancing the flexibility of captive power by allowing energy to be stored during low-demand periods and used during peak times.

Policy Support: Many governments are facilitating the growth of captive power through supportive policies and incentives. These policies are designed to promote energy self-sufficiency and sustainability, aligning with global energy and environmental goals.

5. Energy Management and Optimization

Effective energy management is crucial for maximizing the efficiency and sustainability of captive power plants. Businesses are increasingly adopting sophisticated energy management systems (EMS) that allow for real-time monitoring and control of energy production and consumption. These systems play a critical role in optimizing energy usage and reducing operational costs, making them an indispensable tool for modern energy management strategies.

Demand-Side Management: Advanced EMS enables businesses to implement demand-side management strategies, which involve adjusting power consumption patterns to match energy availability. This can significantly enhance energy efficiency and reduce costs.

Peak Shaving: One of the key benefits of captive power plants integrated with energy storage is peak shaving. This practice involves using stored energy during peak demand periods to reduce reliance on grid power, which is often more expensive and less reliable during these times.

Sustainability Practices: By optimizing energy usage, businesses can not only achieve cost savings but also enhance their sustainability profiles. Reduced dependence on non-renewable power sources and lower carbon emissions are direct benefits of effective energy management in captive power systems.

Conclusion: About KP Group

KP Group leading the development of Captive Power Plants in Surat recognizes the strategic importance of energy independence. With over 30 years in the industry, our commitment extends beyond just providing solutions. We strive to create eco-friendly and energy-efficient systems that not only meet today's energy demands but also pave the way for a sustainable future. Our projects span across Solar, Wind, Hybrid, and the pioneering Green Hydrogen technologies, making businesses in India self-reliant in energy. Trust in KP Group to power your tomorrow with innovative and sustainable energy solutions.

Source URL:

Energy Storage Systems Revolutionizing Energy Management with Lithium-ion Batteries

Energy Storage Systems (ESS) are at the forefront of revolutionizing the way we manage and utilize energy resources. Among the various technologies powering ESS, lithium-ion batteries have emerged as a game-changer, offering unparalleled efficiency, scalability, and versatility. In this article, we delve into the role of lithium-ion batteries in ESS and their impact on the energy landscape.

Unleashing Potential: The Role of Lithium-ion Batteries in ESS

Lithium-ion batteries have gained widespread adoption in ESS due to their exceptional energy density, fast response times, and long cycle life. These batteries are capable of storing large amounts of energy in a compact and lightweight form factor, making them ideal for both stationary and mobile applications.

One of the primary advantages of lithium-ion batteries in ESS is their ability to efficiently capture and store energy from renewable sources such as solar and wind. This stored energy can then be deployed during periods of high demand or when renewable generation is low, helping to balance the grid and reduce reliance on fossil fuels.

Moreover, lithium-ion batteries play a crucial role in enhancing grid stability and reliability. By providing fast-response energy storage capabilities, these batteries can mitigate voltage fluctuations, frequency deviations, and other grid disturbances, ensuring a smoother and more resilient power supply. And your search for the best Lithium-ion battery ends with Sakthi Batteries, the best Lithium-ion battery manufacturer in Karnataka. 

Unlocking Flexibility: Applications of Lithium-ion ESS

The versatility of lithium-ion ESS enables a wide range of applications across various sectors:

Grid-Scale Energy Storage: 

Large-scale lithium-ion ESS installations are deployed at grid substations or utility-scale facilities to provide grid stabilization, frequency regulation, and peak shaving services. These systems help utilities manage fluctuations in supply and demand more effectively, leading to improved grid efficiency and cost savings.

Residential Energy Storage: 

Lithium-ion batteries are increasingly being adopted in residential settings to store excess solar energy generated during the day for use during peak hours or at night. This enables homeowners to reduce their reliance on grid electricity, lower energy bills, and increase self-consumption of renewable energy.

Commercial and Industrial Applications: 

Businesses and industries utilize lithium-ion ESS to optimize energy usage, reduce demand charges, and provide backup power in case of outages. These systems help improve energy efficiency, enhance operational resilience, and lower overall electricity costs.

Electric Vehicle Charging Infrastructure: 

Lithium-ion ESS is integrated into EV charging stations to support rapid charging, manage peak demand, and provide grid services such as demand response and vehicle-to-grid (V2G) capabilities. This enables faster adoption of electric vehicles and contributes to the decarbonization of transportation.

Looking Ahead: Future Trends and Innovations

As technology advancements continue, the future of lithium-ion ESS holds promising developments:

Advancements in Battery Chemistry: Ongoing research efforts focus on improving the energy density, cycle life, and safety of lithium-ion batteries through innovations in materials science, electrode design, and manufacturing processes.

Integration with Renewable Energy Systems: Lithium-ion ESS will play a pivotal role in enabling higher levels of renewable energy penetration by providing reliable and dispatchable power to balance intermittent generation sources.

Emergence of Virtual Power Plants (VPPs): VPPs, consisting of interconnected distributed energy resources including lithium-ion ESS, solar PV, and demand-side assets, will enable more dynamic and responsive grid management while empowering consumers to participate in energy markets.

In conclusion, lithium-ion batteries are driving a paradigm shift in the way we generate, store, and consume energy. As ESS technology continues to evolve, the integration of lithium-ion batteries will play a vital role in building a more sustainable, resilient, and efficient energy infrastructure for the future.

Experience the power of Sakthi’s lithium-ion batteries. Contact us today to learn more and embark on a journey towards efficient and sustainable energy management. Choose Sakthi, the premier lithium-ion battery manufacturer in Karnataka!

Photovoltaic Waste Handling: E-waste Management in the UK

Photovoltaic (PV) solar panels are precious assets for the renewable energy sector. From opting for green energy to saving natural resources, solar panels have emerged as an integral power source in the country. The dilemma of photovoltaic waste handling surfaces when the panels reach the end of their cycle. While pounds of solar panels have already been replaced, thousands may end up in the garbage in the coming years. Considering the importance of recovering potential components for remanufacturing and the hazards of improper disposal, it is safe to contact certified recyclers. Recycling solar panel modules is the safest option to avoid environmental toxicity and rising landfills. Are you struggling with non-functional PV panels? We will guide you through the core aspects of managing defunct PV panels. Don't let non-operational panels hold you back.

Overview of PV Module Recycling in the UK

Recycling PV modules is the most convenient option at the end of productive life. Here are the reasons to consider recycling solar panels and avoid heaps of landfills.

#1. PV Panels are Hazardous E-waste

Dr. Vasilis Fthenakis, Department of Earth & Environmental Engineering and Founder and Director of the Center for Life Cycle Analysis (CLCA) at Columbia University, highlights the impact of lead halide perovskite (LHP) photovoltaics on the environment – soil, water, and air. Perovskite PV products contain toxic lead compounds. Exposure to LHP can cause multiple health issues in humans. These crystallographic substances can raise blood pressure levels, cause anaemia, and harm the foetus in pregnant women. Lead ingestion in children can lower IQ, retard physical and brain development, and affect hearing abilities. Recycling is the ideal option for removing solar panels from domestic and commercial premises without risky, accidental contamination. Professional recyclers leverage safe removal methods to prevent exposure of toxic elements to the surroundings.

#2. Recovering Precious Materials

The valuable materials salvaged from the old and inoperable photovoltaic modules can be repurposed for producing new solar panels. The e-waste comprises precious items, especially silicon, silver, and aluminium frames. Moreover, the panels consist of large quantities of glass and plastic, recovered for further use during disassembling. Up to 95% of the glass sheets extracted from the conveyor belt can be recycled. Hence, solar module recycling is a safe method of removing and repurposing valuable assets for future manufacturing.

#3. Alarming Rise of Landfills across the Country

The load of waste is constantly rising across 500 landfill sites in the UK. Every year, over 100,000 tonnes of cheap electronic goods are thrown into waste bins (according to a survey by Material Focus, a non-profit organisation). These items can be recycled to recover the resources for remanufacturing quality products. In the wake of overflowing garbage wastes and shortage of landfill space across the country, it is wise to recycle valued items rather than throwing away.

#4. Economic Growth Prospects of the Solar Panel Recycling Market

The growth of the global solar panel recycling market is estimated at £1.29 billion by 2028. There has been a massive switch to renewable and sustainable energy opportunities in the commercial zones in the last few decades. Large volumes of panels are about to reach the end of life in the next few years. Eyeing the responsible e-waste handling and imposition of WEEE regulations, the recycling industry is booming worldwide, and the UK is not an exception.

Wrapping Up,

Recycling is by far the most effective end-of-life management of PV modules. At least 80-95% of the solar panel components are recyclable, employing safe and permissible extraction methods. When the energy efficiency of worn-out solar panels drops, it is time to replace them with new modules. Rather than discarding it in the garbage, contact us for photovoltaic recycling. At Evolution Solar Recycling, the team of certified recyclers use state-of-the-art equipment for safe PV panel removal to prevent mishaps and accidental exposure to high-risk e-waste chemicals.

Distributed Generation Market: A Closer Look at Microgrid Development

Rise of Distributed Generation - The future of power generation The traditional model of centralized power generation, where large power plants generate electricity and transmit it through long transmission and distribution lines, has been the mainstay of the power sector for over a century. However, with technological advancements and policy support, Distributed Generation (DG) has emerged as a viable alternative to centralized power systems. DG refers to small-scale electricity generation located close to the end user of power. This article explores how DG is gaining prominence and reshaping the power landscape. What is Distributed Generation?

A distributed generation system produces electricity from renewable and non-renewable energy sources close to the point of consumption. Such localized power generation resources include rooftop solar PV systems, natural gas/diesel generators, combined heat and power systems, small wind turbines, etc. located at residential, commercial or industrial premises. DG systems range from a few kilowatts to 10 megawatts in size, supplying small amounts of power on site or exporting excess electricity back to the main grid. Rise of Renewables drives DG Adoption

The declining costs of solar PV modules and energy storage technologies have provided the necessary push for widespread DG adoption. Rooftop solar installations are seeing exponential growth in many countries as individuals and commercial buildings opt for self-generation to reduce electricity bills and support clean energy goals. Declining battery costs are also enabling greater integration of solar and wind power through energy storage. Many homeowners and businesses now have the capability to not just produce but also store electricity from DG systems for use after dark or during grid outages, gaining energy independence. Benefits of Distributed Generation

DG provides multiple economic and environmental benefits compared to centralized generation. Localized power generation avoids transmission and distribution losses that typically range between 15-30% over long distances. It also requires less investment in grid infrastructure expansion as power is produced near load centers. Distribution utilities benefit through deferred capital investments. DG systems also help harness renewable energy more efficiently by locating generation resources close to consumption points. This decentralized model results in improved energy security, resilience and reliability of power supply. Challenges to Widespread Adoption

While DG offers several advantages, there are also technical and regulatory challenges that have slowed large-scale adoption. Power produced from DG systems is variable and dependent on weather conditions. High penetration of intermittent renewables like solar and wind on the distribution grid poses technical challenges related to grid stability and power quality that require solutions like energy storage and demand response. Regulatory and policy barriers around grid interconnection issues, compensation mechanisms and liability terms have deterred many small power producers. Utilities also perceive DG resources as a threat to centralized control and revenue streams. Harmonizing regulations to encourage bidirectional power flows is key. The Future of Power Systems

Most experts believe that the centralized conventional power model cannot sustain as the sole source of electricity in the future. A hybrid system combining large centralized plants with distributed decentralized resources is likely to emerge. An intelligent two-way grid that facilitates seamless transfer of power between multiple distributed generation assets and the main grid will become necessary. Technologies like blockchain, artificial intelligence and Internet of Energy will play a growing role in managing such complex multi-directional power flows. The distributed power paradigm enables a smarter, flexible and resilient grid that can better integrate variable renewable resources to address energy and climate goals. Countries supporting favorable policies for DG are better placed to transition smoothly to this distributed future of power systems. In conclusion, distributed generation is an idea whose time has come. Falling technology costs, stringent emissions targets and changing customer preferences are compelling forces driving the widespread adoption of small-scale localized power resources. While technical and regulatory challenges remain, most experts agree that DG will play a pivotal complementary role along with centralized generation in transforming energy systems sustainably over the coming decades. Countries aligning policy frameworks to encourage distributed energy technologies stand to gain energy security and economic benefits in the process.

Solar Pv Analytics - Mahindra TEQO

Pv analytics? Solar Pv analytics is crucial to maximize your solar PV plant durability and neglect the component's failure Mahindra TEQO offers 24/7 real-time data and health reports of PV plants and various other features.

The Rise of Domestic Solar Panel Production and Its Impact on the Indian Energy Landscape

The Indian sun has always been a source of awe and inspiration. Now, it's also becoming a powerful engine of progress, thanks to the growing trend of solar panel manufacturing facilities in India leading to the the surge in domestic solar panel production. This isn't just a technical shift; it's a game-changer for India's energy landscape, promising a brighter future on multiple fronts. 

From Reliance to Self-Reliance: Empowering India's Energy Security 

For decades, India relied heavily on imported solar panels. While it provided access to this clean energy source, it also meant fluctuating prices and a dependence on external factors. That's changing. The rise of best solar epc companies in india, establishing state-of-the-art manufacturing facilities within the country, is fostering a spirit of self-reliance. This not only reduces dependence on imports but also strengthens India's position as a global solar leader. 

The Economic Sunshine: A Boon for Jobs and Growth 

The boom in domestic solar panel production isn't just about energy independence; it's also creating a wave of economic opportunities. As more solar module manufacturers set up shop in India, it translates to increased job creation, from skilled engineers to production personnel. Additionally, the establishment of a robust domestic solar ecosystem stimulates local businesses and boosts overall economic growth. Think of it as sunlight nourishing the seeds of a flourishing economy. 

A Breath of Fresh Air: Environmental Benefits of Going Local 

Although solar energy is unadulterated, shipping solar panels from companies abroad has an adverse effect on the environment. The expanded solar photovoltaic module manufacturing in India considerably lowers the transport's carbon footprint. This, coupled with the inherently green nature of solar power, creates a win- win situation for both energy security and environmental well-being. Breathe easy, India – the future is looking cleaner and brighter. 

Building a Sustainable Future 

The rise of domestic solar panel production in India is a testament to the country's commitment to a sustainable future. By fostering self-reliance, boosting the economy, and minimizing environmental impact, this trend is paving the way for a brighter tomorrow. 

Making Sunshine Affordable: A Focus on Accessibility 

The potential for this home production boom to provide access to solar power is one of its most attractive features. The price of solar panels is anticipated to drop as a result of less reliance on imports and healthy competition among India's leading solar enterprises. This translates to a more affordable and clean energy option for everyone across the country. Imagine a future where the power of the sun is not just a symbol of hope, but a tangible reality for everyone. 

How is GREW a major contributor of this Domestic Solar Revolution 

At GREW, a leading solar manufacturing and EPC company in India, we're proud to be at the forefront of this exciting transition. We're not just building solar panels; we're building a more secure, sustainable, and prosperous future for India. From utilizing cutting-edge technology in our manufacturing facilities to offering comprehensive solar solutions – including installation and solar asset management services in India – we are dedicated to assisting companies to maximize business with the sun's power. Additionally, we focus on creating accessible solutions through flexible financing options and efficient project management. 

Join us as we harness the power of the Indian sun! Explore our website to learn more about our high-efficiency solar pv modules and how GREW can help you create your own sustainable energy solution. Together, let's make India shine even brighter, ensuring everyone benefits from the clean, powerful and affordable domestic solar energy.

For more: The Rise of Domestic Solar Panel Production and Its Impact on the Indian Energy Landscape

Dunas Capital secures loan from Cheyne for Spanish Logistics Scheme

Independent real estate asset management platform Dunas Capital Real Estate has successfully closed a   50 mln financing agreement with the global alternative asset manager, Cheyne Capital Management, to support the development of the PTL Logistics Park in Noblejas, Spain.

Located 50 km to the South of Madrid with a total area of 338 ha, PTL Noblejas will offer large size land plots, ranging between 30,000 m2 and 500,000 m2, suitable for large format logistics and industrial platforms.

The project has met all planning approvals and work is due to begin with immediate effect. The site stands at the crossroads of four main highways, the A-4, the A-40, the AP-36 and the R-4, and benefits from proximity to the ports at Valencia and Algeciras.

The site itself will be one of a few BREEAM certified logistics parks in Europe, which will allow tenants to achieve top environmental certifications.

Additionally, PTL-Noblejas will be powered by a PV-solar energy plant, will use ecological materials for the construction of roads, includes more than 34 hectares of parks, 200,000 m2 of plots destined for sport facilities and services, implements rainwater recycling technologies and will have electric vehicle charging stations.

Javier Quintela (Madrid) and Daniel Schuldes (London) of Cheyne Capital said: 'Spain is a region in which we have been very active in recent years, and we continue to see a wealth of opportunities in the region.

'We are pleased to be expanding our presence through this development with Dunas Capital Real Estate, and look forward to seeing this project come to life.'

Rafael de Andrés and David Angulo, principals at Dunas Capital, said: 'This is surely the most important transaction in the development of logistics land in Spain in 2023 and the loan provided by Cheyne Capital secures the placing on the market of a large amount of quality logistics surface in the next two years, which has great demand from operators and retailers.'

Dunas Capital secures loan from Cheyne for Spanish Logistics Scheme

Independent real estate asset management platform Dunas Capital Real Estate has successfully closed a   50 mln financing agreement with the global alternative asset manager, Cheyne Capital Management, to support the development of the PTL Logistics Park in Noblejas, Spain.

Located 50 km to the South of Madrid with a total area of 338 ha, PTL Noblejas will offer large size land plots, ranging between 30,000 m2 and 500,000 m2, suitable for large format logistics and industrial platforms.

The project has met all planning approvals and work is due to begin with immediate effect. The site stands at the crossroads of four main highways, the A-4, the A-40, the AP-36 and the R-4, and benefits from proximity to the ports at Valencia and Algeciras.

The site itself will be one of a few BREEAM certified logistics parks in Europe, which will allow tenants to achieve top environmental certifications.

Additionally, PTL-Noblejas will be powered by a PV-solar energy plant, will use ecological materials for the construction of roads, includes more than 34 hectares of parks, 200,000 m2 of plots destined for sport facilities and services, implements rainwater recycling technologies and will have electric vehicle charging stations.

Javier Quintela (Madrid) and Daniel Schuldes (London) of Cheyne Capital said: 'Spain is a region in which we have been very active in recent years, and we continue to see a wealth of opportunities in the region.

'We are pleased to be expanding our presence through this development with Dunas Capital Real Estate, and look forward to seeing this project come to life.'

Rafael de Andrés and David Angulo, principals at Dunas Capital, said: 'This is surely the most important transaction in the development of logistics land in Spain in 2023 and the loan provided by Cheyne Capital secures the placing on the market of a large amount of quality logistics surface in the next two years, which has great demand from operators and retailers.'

Dunas Capital secures loan from Cheyne for Spanish Logistics Scheme

Independent real estate asset management platform Dunas Capital Real Estate has successfully closed a   50 mln financing agreement with the global alternative asset manager, Cheyne Capital Management, to support the development of the PTL Logistics Park in Noblejas, Spain.

Located 50 km to the South of Madrid with a total area of 338 ha, PTL Noblejas will offer large size land plots, ranging between 30,000 m2 and 500,000 m2, suitable for large format logistics and industrial platforms.

The project has met all planning approvals and work is due to begin with immediate effect. The site stands at the crossroads of four main highways, the A-4, the A-40, the AP-36 and the R-4, and benefits from proximity to the ports at Valencia and Algeciras.

The site itself will be one of a few BREEAM certified logistics parks in Europe, which will allow tenants to achieve top environmental certifications.

Additionally, PTL-Noblejas will be powered by a PV-solar energy plant, will use ecological materials for the construction of roads, includes more than 34 hectares of parks, 200,000 m2 of plots destined for sport facilities and services, implements rainwater recycling technologies and will have electric vehicle charging stations.

Javier Quintela (Madrid) and Daniel Schuldes (London) of Cheyne Capital said: 'Spain is a region in which we have been very active in recent years, and we continue to see a wealth of opportunities in the region.

'We are pleased to be expanding our presence through this development with Dunas Capital Real Estate, and look forward to seeing this project come to life.'

Rafael de Andrés and David Angulo, principals at Dunas Capital, said: 'This is surely the most important transaction in the development of logistics land in Spain in 2023 and the loan provided by Cheyne Capital secures the placing on the market of a large amount of quality logistics surface in the next two years, which has great demand from operators and retailers.'

Dunas Capital secures loan from Cheyne for Spanish Logistics Scheme

Independent real estate asset management platform Dunas Capital Real Estate has successfully closed a   50 mln financing agreement with the global alternative asset manager, Cheyne Capital Management, to support the development of the PTL Logistics Park in Noblejas, Spain.

Located 50 km to the South of Madrid with a total area of 338 ha, PTL Noblejas will offer large size land plots, ranging between 30,000 m2 and 500,000 m2, suitable for large format logistics and industrial platforms.

The project has met all planning approvals and work is due to begin with immediate effect. The site stands at the crossroads of four main highways, the A-4, the A-40, the AP-36 and the R-4, and benefits from proximity to the ports at Valencia and Algeciras.

The site itself will be one of a few BREEAM certified logistics parks in Europe, which will allow tenants to achieve top environmental certifications.

Additionally, PTL-Noblejas will be powered by a PV-solar energy plant, will use ecological materials for the construction of roads, includes more than 34 hectares of parks, 200,000 m2 of plots destined for sport facilities and services, implements rainwater recycling technologies and will have electric vehicle charging stations.

Javier Quintela (Madrid) and Daniel Schuldes (London) of Cheyne Capital said: 'Spain is a region in which we have been very active in recent years, and we continue to see a wealth of opportunities in the region.

'We are pleased to be expanding our presence through this development with Dunas Capital Real Estate, and look forward to seeing this project come to life.'

Rafael de Andrés and David Angulo, principals at Dunas Capital, said: 'This is surely the most important transaction in the development of logistics land in Spain in 2023 and the loan provided by Cheyne Capital secures the placing on the market of a large amount of quality logistics surface in the next two years, which has great demand from operators and retailers.'

Dunas Capital secures loan from Cheyne for Spanish Logistics Scheme

Independent real estate asset management platform Dunas Capital Real Estate has successfully closed a   50 mln financing agreement with the global alternative asset manager, Cheyne Capital Management, to support the development of the PTL Logistics Park in Noblejas, Spain.

Located 50 km to the South of Madrid with a total area of 338 ha, PTL Noblejas will offer large size land plots, ranging between 30,000 m2 and 500,000 m2, suitable for large format logistics and industrial platforms.

The project has met all planning approvals and work is due to begin with immediate effect. The site stands at the crossroads of four main highways, the A-4, the A-40, the AP-36 and the R-4, and benefits from proximity to the ports at Valencia and Algeciras.

The site itself will be one of a few BREEAM certified logistics parks in Europe, which will allow tenants to achieve top environmental certifications.

Additionally, PTL-Noblejas will be powered by a PV-solar energy plant, will use ecological materials for the construction of roads, includes more than 34 hectares of parks, 200,000 m2 of plots destined for sport facilities and services, implements rainwater recycling technologies and will have electric vehicle charging stations.

Javier Quintela (Madrid) and Daniel Schuldes (London) of Cheyne Capital said: 'Spain is a region in which we have been very active in recent years, and we continue to see a wealth of opportunities in the region.

'We are pleased to be expanding our presence through this development with Dunas Capital Real Estate, and look forward to seeing this project come to life.'

Rafael de Andrés and David Angulo, principals at Dunas Capital, said: 'This is surely the most important transaction in the development of logistics land in Spain in 2023 and the loan provided by Cheyne Capital secures the placing on the market of a large amount of quality logistics surface in the next two years, which has great demand from operators and retailers.'