Creativity is a key factor in the development of renewable energy sources (RES). It gives rise to new engineering solutions that enhance efficiency, reduce costs, and minimize negative environmental impact.
Some examples of creative projects related to RES include:
Artificial leaves that mimic the process of photosynthesis, producing oxygen and hydrogen from water and sunlight.
Flying wind turbines that harness stronger and more stable winds at high altitudes and transmit energy to the ground via cables.
Perovskite solar panels, which have the potential to achieve higher efficiency and lower cost compared to traditional silicon panels.
These and many other ideas illustrate how creativity supports the development of RES and provides innovative engineering solutions. Creativity is not only a source of inspiration but also a tool for problem-solving and creating a better world.
Example: Floating solar farms
Engineers and automation experts are constantly seeking new solutions like those mentioned above, as well as finding unconventional uses for existing solutions. Floating solar farms exemplify this approach and represent one of the latest trends in renewable energy. Here are some key facts about them:
Floating solar farms make use of water surfaces that are often underutilized or inaccessible for other purposes, such as recreation, tourism, or agriculture.
They exhibit higher efficiency compared to traditional land-based farms because they are cooled by the water and can track the movement of the sun.
Floating solar farms can also benefit the environment by reducing water evaporation, inhibiting algae growth, and preventing shoreline erosion.
If you are interested in innovations in the renewable energy sector, also read:
Hybrid Renewable Power Plants are those that combine different types of renewable energy sources, such as wind, solar, biomass, or water. The goal of this combination is to increase the efficiency and reliability of energy production, making it less dependent on weather conditions or time of day. Hybrid renewable power plants can also use energy storage systems, allowing them to store excess energy and utilize it during periods of shortage.
Advantages of Hybrid Renewable Power Plants include:
Reduction of investment and operational costs through shared infrastructure and equipment;
Reduced strain on the power grid and improved stability due to better alignment with energy demand;
Decreased greenhouse gas emissions and air pollution by using clean energy sources;
Increased energy independence and supply security through the diversification of energy sources.
Examples of hybrid renewable power plants are:
Photovoltaic Thermal (PVT) plants, which combine photovoltaic panels with solar thermal collectors;
Wind-Solar power plants, which combine wind turbines with photovoltaic panels;
Biogas power plants, which combine a biogas production installation with a biomass combustion installation.
Growth in Popularity of Hybrid Power Plants
Hybrid renewable power plants are becoming an increasingly popular solution worldwide as they address challenges related to energy transition and environmental protection. In Poland, hybrid renewable power plants are still in the development stage, but there are already initiatives and projects aimed at promoting and supporting them. The first hybrid renewable power plant in Poland is Kleczew Solar & Wind, combining solar and wind energy production. The EPC contractor for this project is Electrum Group.
Concept of Cable Pooling
One of the solutions implemented within the Polish legal framework to promote and support the development of hybrid renewable energy installations is the concept of cable pooling, which involves connecting at least two renewable energy sources to the same grid connection. This approach allows for savings on building new infrastructure and makes better use of existing resources.
Solar power plants are among the most promising sources of renewable energy, helping to reduce carbon emissions and save on costs. However, to fully benefit from this technology, proper solar power maintenance is essential.
In this article, you’ll learn about:
The process of solar power maintenance,
Diagnostic systems that monitor the condition of panels, inverters, meters, and other components of solar installations,
Analytical systems that use sensor data to detect anomalies, forecast energy production, optimize system performance, and generate reports,
Security systems that protect the farm from intrusions, fires, surges, or mechanical damage using motion, smoke, temperature, and humidity sensors.
How does solar power maintenance and servicing work?
Managing photovoltaic farms requires continuous attention and specialized knowledge.
24/7 Control Center
We ensure continuous operation and quick response to potential failures. Our team of farm specialists monitors systems around the clock, and if irregularities are detected, a diagnostic procedure is immediately initiated. If possible, repairs are done remotely, allowing for rapid restoration of full functionality.
Preventive Maintenance
This includes regular technical inspections conducted on a monthly, semi-annual, and annual basis. These inspections help anticipate potential problems and ensure long-term efficiency of the installation. They are tailored to the client’s specific needs and comply with both manufacturer recommendations and construction law.
We offer comprehensive corrective repairs that restore equipment to its pre-fault condition. We also support our clients in warranty and insurance claims processes, preparing necessary reports, damage assessments, and identifying elements that may require future attention.
At Electrum, we ensure that every solar power plant operates flawlessly. Our O&M services provide peace of mind and the assurance that our clients’ investments are in good hands.
EMACS is a modern diagnostic system that revolutionizes power plant management. With EMACS, operational costs are reduced through continuous infrastructure monitoring and quick response to failures, often with the option for remote repairs. This system not only improves technological processes through automation but also provides detailed insights into the energy balance, which is crucial for industrial installations.
With EMACS, you reduce the risk of failures and increase safety thanks to comprehensive insight into energy production and equipment condition. Moreover, the system provides full control over the facility, is easily accessible from any device, requires no specialized infrastructure, and offers intuitive operation with customizable access management.
Solar power maintenance and network diagnostics with Centrix Evolution
Centrix Evolution, offered by Electrum, provides unparalleled precision and safety in locating and repairing power network faults. As the only modern measurement vehicle of its kind in Poland, Centrix Evolution uses advanced technology to efficiently inspect and service power grids, delivering the fastest and most accurate results while minimizing risk and costs.
Features of Centrix Evolution
Centrix Evolution is more than just fault location. With functions like IFL, ICE, and Decay, ARM® Multishot, ProRange, and MFM 10, this system enables full network diagnostics. Integrated with advanced software, Centrix Evolution provides comprehensive information about the technical condition of infrastructure, allowing for intelligent repair predictions.
Teleflex® Locator for solar power maintenance
With Teleflex®, a top-class locator, Electrum ensures precise fault localization, saving time and resources. Additionally, Centrix Evolution supports electrical endurance tests and HV diagnostics, offering services like tg delta diagnostics, cable route location using the Signal-Select® method, and MeggerBook – an intelligent database for optimal data management.
SCADA: The heart of modern solar power monitoring and service
The SCADA (Supervisory Control and Data Acquisition) system is a key element ensuring the professional management of photovoltaic farms by providing security, reliability, and performance optimization. As a central IT system, SCADA collects valuable data from various measurement and execution devices, enabling their visualization and effective control of production processes.
With SCADA, solar farm operators have access to real-time measurements, can visualize data in clear diagrams, charts, and tables, and can automate the energy production process. This system also allows for the archiving of historical data and the generation of detailed reports, which are invaluable for long-term analysis and optimization.
Quick response to irregularities
SCADA is indispensable for solar farms, as it provides comprehensive oversight of areas where the farms are located, as well as the operational parameters of the equipment. Detecting and alerting about irregularities, such as intrusions or exceeding alarm thresholds, allows for a quick response and minimizing damage risk. The SCADA system also enables remote control of the energy production process, adjusting operational parameters to current weather conditions and energy demand. This results in increased efficiency and quality of the energy delivered to the grid.
Solar power maintenance – Summary
By utilizing maintenance solutions, photovoltaic farms can not only increase efficiency and reliability but also reduce maintenance costs. This makes photovoltaic farms an even more attractive source of renewable energy for homes, businesses, and communities.
Energy Systems and Devices Related to Renewable Energy
Renewable energy systems and devices are a crucial step toward sustainable and ecological development. Wind farms, as a part of the Polish energy system, are becoming an increasingly visible element of the landscape. At Electrum, we strive to create a sustainable energy future that delivers energy from alternative sources in a safe and environmentally friendly manner.
In this article, you will learn about:
The importance of energy devices and systems for the future of renewable energy.
The process of building wind farms as an investment in the national energy system.
The role of comprehensive energy solutions in modern energy systems.
The impact of innovative technology on the development of alternative energy.
The significance of wind farms for modern energy systems and their impact on sustainable development.
Building Wind Farms – An Investment in the National Energy System
Electrum, as a leader in the energy transition in Poland, guarantees the efficient execution of projects by leveraging technological maturity and innovative thinking.
Comprehensive Energy Solutions for Modern Energy Systems
Comprehensive energy solutions are crucial for integrating wind farms into Poland’s energy system. At Electrum, we specialize in designing, building, maintaining, and integrating with existing infrastructure. Our company is a pioneer in creating an alternative energy system. We create innovative wind power plants projects, taking into account location, terrain conditions, and energy efficiency.
We carry out the construction of wind farms, ensuring quality, safety, and compliance with standards. We provide regular inspections, maintenance, and repairs to ensure that wind farms operate smoothly. Our solutions involve the collaboration of wind farms with existing energy sources. This allows us to create an alternative energy system that is more sustainable and environmentally friendly.
Technology and Alternative Energy: The Direction of Development
Today, technological innovation plays a key role in the transformation of the energy sector. The development of technologies such as photovoltaic panels and modern wind turbines is becoming a cornerstone in building efficient wind farms and increasing the efficiency of the economy and energy systems.
At Electrum, as a leader in the field of energy and information, we aim to create and implement pioneering business solutions that will not only contribute to the sustainable development of the energy sector but also support our clients in achieving their energy and information management goals. Our company is engaged in research on the latest technologies to continuously improve our approach and offer innovative solutions that will contribute to building a better energy future for all of us.
The Climate Tech Trend
One of the trends is the development of so-called Climate Tech, which includes technologies aimed at reducing greenhouse gas emissions and adapting to climate change. This includes innovative solutions for the production, storage, and distribution of energy from renewable sources, such as smart grids, batteries, fuel cells, and electrolyzers. Climate Tech aims not only to increase the share of renewable energy sources in the energy mix but also to improve the efficiency and flexibility of energy systems.
Offshore Wind Farms
Another direction is the construction of increasingly larger and more powerful renewable energy sources. Examples include offshore wind farms, which can generate more energy than those on land due to stronger and more stable winds. Other examples include huge solar power plants that cover hundreds of hectares and use advanced sun-tracking techniques. Such energy sources, however, require adequate infrastructure for the transmission and distribution of energy over long distances.
Energy Storage
A third aspect is energy storage, which allows excess energy from renewable sources to be stored and used when needed. Energy storage can take various forms, such as mechanical (e.g., water dams), chemical (e.g., batteries), thermal (e.g., heat), or electrical (e.g., capacitors). Energy storage helps increase the reliability and stability of energy systems based on renewable energy sources.
In summary, the future of energy devices and systems in renewable energy sources will depend on many factors, such as technological development, energy policy, social preferences, and geographical conditions. One thing is certain: renewable energy sources will play an increasingly significant role in ensuring energy security and climate protection.
The construction of wind farms is an essential element in the development of modern energy systems. By utilizing the latest technologies, wind farms contribute to:
Increasing the share of renewable energy in the global energy mix
Promoting sustainable development
Environmental protection
Electrum is committed to actions that bring lasting change, not only by providing green energy but also by engaging in local community activities and promoting comprehensive renewable energy solutions.
Photovoltaic panels, also known as PV panels or solar panels, are devices that capture electrical energy from solar radiation. This is achieved by utilizing the photovoltaic effect, where solar photons generate electric current in specialized modules.
Photovoltaic panels (PV) are a technology that is gaining increasing popularity as a means of generating one’s renewable electrical energy. In simple terms, solar panels allow for the transformation of solar energy into electrical energy, which can significantly reduce electricity bills and positively impact the environment.
1.2 Structure of Photovoltaic Panels
PV panels consist of several key components, including:
photovoltaic cells,
a direct current to alternating current converter,
and protective frame.
Each of these components plays a crucial role in the process of converting solar energy into electricity.
II. How PV Panels Work
2.1 Processing Solar Radiation
The primary function of PV panels is to process solar radiation into electrical energy. This process involves the stimulation of electrons in photovoltaic cells by solar photons, which generates electric current.
2.2 Photovoltaic Modules
Photovoltaic modules are comprised of numerous photovoltaic cells connected into a single unit. These modules are responsible for converting solar energy into electrical energy. It’s essential to understand the differences between monocrystalline, polycrystalline, and amorphous cells, as they impact the efficiency of PV panels.
Solar panels operate based on the photovoltaic effect. This means that after being exposed to sunlight, photovoltaic modules generate electric current. Each panel consists of multiple individual photovoltaic cells, and the entire installation may contain multiple panels connected in one system.
III. Benefits of Using Photovoltaic Panels
3.1 Cost Savings
One of the primary reasons people choose to install solar panels is to reduce their electricity bills. Energy produced by photovoltaic panels can power a household, resulting in substantial long-term savings.
PV panels are an investment that yields financial savings over time. While the initial cost of purchase and installation may be significant, this investment pays off multiple times in the long run. Why? Because solar panels allow for the production of one’s electricity, reducing electricity bills. In some cases, surplus energy can be sold to the grid, generating additional income.
3.2 Environmental Impact
Using solar energy is not only economically beneficial but also environmentally friendly. PV panels do not emit harmful greenhouse gases or other air pollutants, contributing to a reduced impact on climate change.
Photovoltaic panels are environmentally friendly. They utilize solar energy, producing no emissions of harmful greenhouse gases or other air pollutants. Therefore, using solar panels not only leads to financial savings but also actively contributes to environmental protection.
IV. Installation and Maintenance of PV Panels
4.1 PV Panel Installation
PV panel installation is a complex process that requires technical knowledge. Before commencing the installation, it’s necessary to obtain the required permits and conduct a thorough assessment of the installation site.
The PV panel installation process begins with a precise evaluation of the installation site. Specialists take into account the direction and slope of the roof to optimize panel efficiency. Then, PV panels are mounted on an appropriate structure, and the entire system is connected to the electrical grid.
Solar panels require regular maintenance to maintain their efficiency at an optimal level. There are also servicing options available to address any breakdowns or installation issues.
PV panel maintenance involves monitoring their performance, cleaning the modules, and checking that all system components are functioning correctly. Regular inspections are advisable to prevent unplanned disruptions in electricity supply.
V. PV Panels and the Future of Energy
5.1 Alternative Energy Systems
Solar panels play a crucial role in the development of alternative energy systems. They are an integral part of the energy transition, reducing dependence on traditional energy sources.
Photovoltaic panels are an essential element of the future of energy. As energy demand grows, and concerns about greenhouse gas emissions rise, PV technology becomes increasingly vital. It contributes to sustainable energy development.
5.2 Climate Tech
In the context of the growing importance of climate technologies, PV panels are a vital component of the fight against climate change. By producing clean energy, they contribute to the protection of the planet.
Photovoltaic panels are part of the trend in climate technologies, aiming to reduce the negative impact of human activities on the environment. This solution combines economic and ecological aspects, creating a win-win situation for users and the planet.
How to choose PV panels? When choosing solar panels, important factors to consider include energy efficiency, performance in various weather conditions, and investment costs.
6.2 Technical Support
Finding the right supplier and technical support is crucial for a successful PV panel installation. A good partner can help in selecting the right system and provide essential post-installation support.
If you need a trusted partner for collaboration, contact us!
In summary, PV panels are an attractive solution from both an economic and ecological perspective. They enable the production of electricity, reducing electricity bills and positively impacting the environment. If you are considering investing in a renewable energy source, photovoltaic panels are worth considering.
VIII. Costs and Return on Investment
8.1 Initial Investment
Investing in PV panels involves initial costs, including panel purchase, installation, inverters, and other accessories. These costs may vary depending on the chosen system and supplier. However, it’s essential to remember that this is an investment that pays off over time.
8.2 Return on Investment (ROI)
The value of PV panels lies not only in electricity production but also in the return on investment. The ROI depends on various factors, including location, panel efficiency, energy prices, and financial support. For many people, the return on investment is achieved in a relatively short period, making solar panels an attractive solution.
IX. Technologies and Trends in PV Panel Development
9.1 Advancements in PV Technology
The photovoltaic industry is continuously evolving, introducing new technologies and improvements that enhance the efficiency of PV panels. One example is PERC (Passivated Emitter Rear Cell) technology, which boosts the efficiency of photovoltaic modules.
9.2 Energy Storage
Energy storage systems has become a significant trend in the energy industry. PV panels allow for the production of surplus energy that can be stored in batteries for use when it’s most cost-effective.
The PV panel market in Poland is growing rapidly. The increase in ecological awareness and government support in the form of grant programs have contributed to the popularity of this technology.
10.2 Current Trends
Currently, there is a growing number of households in Poland opting to install PV panels. This demonstrates the increasing awareness of society regarding the use of renewable energy sources.
XI. PV Panels in Industry
11.1 Industrial Utilization
Solar panels are not limited to residential use. An increasing number of companies and industrial facilities are adopting this technology to power their operations, reducing costs and gaining access to green energy.
Solar farms encompass extensive areas covered with PV panels, generating substantial energy. They are used to power cities, industrial plants, and other large consumers.
Solar panels are one of the elements of the future of renewable energy. Renewable sources are becoming increasingly competitive compared to traditional ones.
12.2 The Role of PV Panels
Photovoltaic panels will play a key role in the energy transformation. As the demand for energy grows, PV technology will be crucial in providing clean energy.
XIII. How to Choose the Optimal PV System
13.1 Consultation with Experts
When choosing the right PV system, it’s advisable to consult with experts who can help select the best solution based on individual needs.
13.2 Efficiency Analysis
It’s worth analyzing thoroughly the benefits that can be achieved by installing PV panels, taking into account local climate conditions, energy prices, and available financial support.
PV panels represent an innovative solution with enormous potential in the field of electricity production. Their growing popularity is due to numerous benefits, such as financial savings, a positive environmental impact, and advancing technology.
XV. Frequently Asked Questions
Is investing in photovoltaic panels profitable in the long run?
What financial support is available for those choosing to install PV panels?
Are solar panels environmentally friendly?
What are the costs and benefits of storing energy generated by photovoltaic panels?
What future technologies may impact the development of PV panels?
Is investing in solar panels cost-effective in the long term?
Yes, investing in photovoltaic panels is cost-effective in the long term. Although the initial costs may be significant, PV panels allow for the generation of your own electricity, leading to a reduction in electricity bills. In many cases, the return on investment is achieved in a relatively short period.
What financial support is available for those choosing to install PV panels?
In Poland, there are several forms of financial support for individuals installing PV panels. You can take advantage of government programs such as “Mój Prąd” or “Czyste Powietrze,” which offer grants or preferential loans for the installation of photovoltaic panels. Additionally, there are various EU funds and local initiatives supporting renewable energy sources.
Are solar panels environmentally friendly?
Yes, solar panels are environmentally friendly. They harness solar energy without emitting harmful greenhouse gases or other air pollutants. Therefore, using PV panels contributes to the protection of the natural environment and reduces the impact on climate change.
What are the costs and benefits associated with storing energy generated by photovoltaic panels?
The costs of storing energy generated by photovoltaic panels depend on the type and capacity of the storage system. However, energy storage can be cost-effective, allowing you to use your own energy when it is most profitable, such as during peak hours when electricity prices are higher. It also provides energy independence in case of power outages.
What future technologies may impact the development of solar panels?
The future of PV panels is promising, and evolving technologies can enhance their efficiency. One example is PERC (Passivated Emitter Rear Cell) technology, which increases the efficiency of photovoltaic modules. Additionally, energy storage technologies are advancing, enabling even more efficient utilization of energy generated by PV panels.
Considering these answers, the installation of PV panels represents an attractive investment from both an economic and environmental perspective.
Solar panels – an investment in the future
Photovoltaic panels are not just a source of energy but also an investment in the future that can bring many benefits to households, businesses, and the natural environment. If you are considering the installation of PV panels, it is a step toward a more sustainable and economically sound future. Properly adapting solar panels to your needs and local conditions can bring both economic and environmental advantages. Generating your electricity can lower electricity bills and contribute to environmental protection. PV panels are an investment that pays off in the long term while remaining eco-friendly. It’s worth considering the installation of photovoltaic panels as a way to increase energy independence and reduce the impact on climate change.
A power grid contractor is an entity that specializes in the comprehensive implementation of investments related to the construction and modernization of power grids. The general contractor provides its clients with services at every stage of the project, from technical and economic analysis to obtaining the necessary permits and approvals, through to construction and installation work, as well as maintenance and facility management.
Key Areas of Activity for General Contractors in Power Grids
One of the primary areas of power grid contractors activities is:
Solar and wind farms are alternative sources of renewable energy (RES). Photovoltaic and wind farms are installations that harness solar energy and wind to generate electrical power. They are increasingly chosen by investors due to their ecological, economic, and social benefits.
Key Responsibilities of the Power Grid Contractor
The construction of photovoltaic and wind farms requires power grid contractor to have the appropriate knowledge and experience in terms of:
design,
equipment selection,
installation,
and grid connection.
The General Contractor for Power Grids must also ensure the safety and quality of the work and comply with legal and regulatory requirements. Some of the key tasks of power grid contractors include:
Conducting a location analysis, considering climatic conditions, infrastructure availability, and energy potential (In this article, you will learn how to choose the best location for solar panels?).
Developing the technical and business concept of the project, including the choice of optimal technology, capacity, and scale of the farm.
Preparing project documentation, including negotiating grid connection terms with the system operator.
Obtaining the necessary permits, approvals, and administrative decisions, including environmental, construction, and energy-related.
Carrying out earthworks, foundation work, road construction, and other necessary tasks to prepare the land for farm construction.
Delivering, assembling, and connecting photovoltaic modules (PV panels) or wind turbines to the grid, along with the necessary electrical equipment and automation.
Conducting tests and technical acceptance of the installation, including power and energy quality measurements.
Handing over the farm to the investor or operator for operation.
After the construction…
After the construction of a photovoltaic or wind farm is completed, GWSE can also provide servicing and maintenance services for the installation. These services include:
Monitoring the operation of the farm using remote monitoring and control systems.
Performing periodic technical inspections and equipment maintenance.
Repairing any faults or malfunctions in the installation.
Optimizing the operation of the farm to increase its energy and economic efficiency.
Summary
The tasks of the General Contractor for Power Grids are diverse and demanding. GWSE must possess high technical, organizational, and legal qualifications, as well as flexibility and adaptability to meet the needs of the client. Only in this way can GWSE ensure the highest level of investment implementation and contribute to the development of the RES sector.
Alternative Energy as a New Path in Energy Production
Alternative energy is a field that is gaining popularity as the climate crisis advances. Alternative energy systems, such as the solar farm construction and wind farm construction, are becoming increasingly common to meet the demand for electrical power.
Alternative Energy and RES
Renewable energy sources (RES) are a key component of alternative energy. Among them, photovoltaic farms and wind farms stand out. The construction of photovoltaic farms involves the installation of PV panels that convert solar energy into electrical energy. PV panels are becoming more efficient and cheaper to produce, making them increasingly popular. Wind farm construction involves the installation of wind turbines that convert the kinetic energy of the wind into electrical energy. Wind farms are particularly effective in regions with strong winds.
Climate Tech
Alternative energy is a crucial component of Climate Tech – technologies aimed at combating climate change. Unlike traditional energy sources such as fossil fuels, RES do not emit greenhouse gases and do not contribute to global warming. Furthermore, RES are unlimited and available worldwide.
Challenges for Alternative Energy
One of the challenges for alternative energy is the lack of stability in the energy supply. In the case of photovoltaic and wind farms, energy is only produced when weather conditions are appropriate. To address this issue, it is necessary to develop new technologies for storing electrical energy.
Renewable Energy Systems as a Solution to Problems
In summary, alternative energy is a new path in electrical energy production. Alternative energy systems, such as the construction of photovoltaic and wind farms, are a key element of this field. RES are unlimited and available worldwide, and they do not emit greenhouse gases. One of the challenges for alternative energy is the lack of stability in the energy supply, but the development of new technologies for storing electrical energy can help address this issue.
Nearly 308,000 double-sided photovoltaic panels will generate enough energy to power over 100,000 households annually. The Przykona photovoltaic farm will be the second-largest installation of its kind in Poland, but with the potential to increase its capacity by an additional 40 MW, it has the potential to become one of the largest photovoltaic power plants in Central and Eastern Europe.
Solar farm construction lasted for over a year, with nearly 500 people working on the construction site during peak periods. The project has a total installed capacity of 200 MWp and will generate approximately 220 GWh annually, thus avoiding the use of traditional fossil fuels to produce the same amount of energy.
The Przykona Power Plant will also prevent the emission of over 208,000 tons of CO2 annually. It was installed on the site of a rehabilitated brown coal mine and covers an area of 270 hectares, equivalent to 375 soccer fields. This new photovoltaic power plant in the Przykona municipality represents a significant step in the development of renewable energy in Poland. The project, created in collaboration with EDP Renewables, is an excellent example of effective energy infrastructure implementation.
During the project, we made every effort to propose optimal and modern solutions to our partner, which will allow for the full utilization of the facility’s potential during its operational phase and add value to the investment. The Przykona PV photovoltaic farm is not the first project that Electrum has completed for EDP Renewables, and we hope it won’t be the last. We feel that in EDP Renewables, we have found a partner who shares our vision of a sustainable future and takes concrete actions towards building a green energy system – says Tomasz Taff from the Electrum Group.
The Przykona PV solar farm is another milestone in our collaboration with EDP Renewables, demonstrating our commitment to building a sustainable energy future.”
A charitable balloon filled with music will once again rise into the air over the most charming areas of Podlasie as part of the Second Flying Ambient Salon campaign. The project’s goal is to support the Prophet Elijah Hospice Foundation, which takes care of improving the lives of seniors. Those willing to support the campaign and experience a unique flight in the air with the sounds of Ambient still have a chance to participate in a special online fundraiser.
The unique formula of the Flying Ambient Salon combines unforgettable experiences offered by a balloon flight with an artistic feast for music lovers. The event is organized for the second time. Last year, thanks to the generosity of donors, the organizers of the campaign raised over 20,000 PLN, which was donated to the Give Children Strength Foundation.
In this year’s edition of the Flying Ambient Salon, we want to draw attention to the fact that by taking care of the future of our planet, it is worth remembering the people who took care of it in the past. For this reason, we have decided that the entire amount collected as part of the campaign will go to the Prophet Elijah Hospice Foundation. We are delighted that, just like last year, we can collaborate with the Up To Date Festival in such a noble cause, and an extraordinary artist from the domestic Ambient scene, known as Botanica, has also joined our efforts,– says Agata Kalinowska, Brand Business Partner at the Electrum Group, the organizer of the event.
The Second Flying Ambient Salon will be realized with the participation of a producer and DJ hiding under the pseudonym Botanica. Botanica creates relaxing ambient music, sometimes interspersed with rhythmic tracks bordering on dub techno and house. The artist is an enthusiast of field recordings, which he uses in his compositions and publishes on his Bandcamp profile. His recordings appear in film productions, during yoga classes, in relaxation and meditation apps, and as the musical background of design exhibitions. So far, Botanica’s productions have been released by labels such as MOST, Father And Son Records & Tapes, Dom Trojga, and Neoviolence. The artist’s recordings are available online on his profiles at https://sayyestobotanica.bandcamp.com/ and https://soundcloud.com/thisisbotanica.
“We are delighted that, as the Up To Date Festival, we have the opportunity to co-create the Second Flying Ambient Salon. In the past, we undertook various activities for seniors. We painted murals, organized intergenerational dances – it’s easy, light, and enjoyable to talk about it, but it’s not easy to talk about those who are slowly leaving us. Together with Electrum, we take on this challenge and invite you to help. Let’s remember the generations that were here before us and to whom we owe a lot,” – says Jędrzej Dondziło, co-creator of the campaign and Program Director of the Up To Date Festival.
People interested in participating in a visual and musical feast during a balloon flight over Narwia and Knyszyn Forest can still take part in the online fundraiser at https://zrzutka.pl/6zy4h9. The event is planned for September 25, 26, 27, and 28, depending on the weather. The launch is expected at around 4:00 PM. The campaign can also be supported in other ways, such as purchasing attractive “bricks,” for example, a yoga lesson.
About Electrum
The Electrum Group is a leading Polish Climate Tech business headquartered in Białystok, offering comprehensive solutions in the latest technology for the development, construction, and management of projects in the energy and information sectors. The technological maturity of its experts allows it to provide products and services that meet the changing needs of the industry and business as they evolve with the ongoing energy transformation. It creates and implements solutions and builds projects based on the idea of an individual energy mix, maintaining a balance between the social and environmental responsibility of business and the economic aspect.
Renewable energy sources (RES) are those that harness natural processes occurring in the environment, such as wind, sunlight, water, biomass, and geothermal energy. RES are increasingly popular and desirable because they offer numerous advantages over traditional energy sources like coal, oil, and gas.
Advantages of Renewable Energy Sources
Some of the benefits of RES include:
Environmentally friendly: They do not emit harmful greenhouse gases or other pollutants that contribute to global warming and climate change.
Renewable: They are inexhaustible and available regardless of geopolitical situations or raw material prices.
Diverse and flexible: They can be adapted to different geographical conditions and energy needs.
Economically beneficial: They create new jobs, stimulate technological innovation, and reduce dependence on energy imports.
Main Types of Renewable Energy Sources
Wind Power: Wind farms utilize the kinetic energy of the wind to drive turbines that generate electricity. They can be located onshore or offshore, depending on location and wind conditions.
Solar Energy: This involves using solar radiation to produce heat or electricity, often through photovoltaic panels. Solar farms are one of the cheapest and fastest-growing RES worldwide.
Hydropower: Uses the potential or kinetic energy of water to drive turbines or generators. Energy can be harnessed from rivers, lakes, oceans, or waves, and is one of the oldest and most reliable RES.
Biomass: Involves using organic material from plants or animals to produce heat, electricity, or biofuels. Biomass can come from agricultural, forestry, municipal, or industrial waste.
Geothermal Energy: Uses the heat stored within the Earth’s crust for heating, cooling buildings, or generating electricity. It is one of the cleanest and most stable RES since it doesn’t depend on weather conditions or seasons.
RES in Global Energy Production
Renewable energy is a key direction in the development of global energy. According to the International Energy Agency (IEA), the share of RES in global electricity production is expected to grow from 29% in 2020 to 43% in 2030 and 60% in 2050. Achieving these goals requires investments, policies, and cooperation at local, national, and international levels.
Alternative Energy Examples
RES has great potential for development in the field of alternative energy. This term encompasses various forms of energy production, distribution, and consumption that differ from the traditional fossil-fuel-based and centralized energy networks. Examples include:
Microgrids
Local energy systems that can operate independently or in conjunction with the main grid. Microgrids use RES, energy storage, and smart technologies to provide reliable and efficient energy access.
Hydrogen Economy
A vision where hydrogen, produced using RES, is the main energy carrier, which can be stored, transported, and used for various purposes like powering vehicles, heating buildings, or supplying industry.
Prosumers
Individuals or entities that both produce and consume electricity. Prosumers can install their own RES, such as solar panels or wind turbines, and sell excess energy back to the grid or share it with others.
Benefits of Alternative Energy
Alternative energy offers numerous benefits for society and the environment, including:
Enhancing energy security and reducing dependence on foreign energy suppliers.
Lowering energy costs and reducing energy poverty.
Improving air quality and public health by reducing pollutant emissions.
Supporting the development of local communities and economies by creating jobs and income.
Accelerating the energy transition and combating climate change by reducing greenhouse gas emissions.
Comprehensive RES Solutions
To fully exploit the potential of alternative energy, comprehensive RES solutions are needed. These integrate various technologies, services, and stakeholders within a sustainable energy system. This requires innovation at multiple levels:
Technology: Developing new or improving existing RES technologies, such as higher-efficiency photovoltaic panels, quieter wind turbines, or batteries with greater capacity.
Business: Creating new or adapting existing business models, such as equipment leasing, participation in energy communities, or offering energy management services.
Policy: Implementing new or modifying existing regulations and taxes, such as setting energy tariffs, subsidies for investments, or energy origin certificates.
Society: Building new or strengthening existing social and cultural relationships, such as citizen engagement, ecological education, awareness, and cross-sector cooperation.
