The Costs and Benefits of Solar Panels: 6 Factors to Consider

Solar panels are sliding into mainstream consumerism—and it’s posing a challenge. For instance, when you want to buy a car, there is a surge of first-hand information from friends and family who can walk you through the ins and outs of buying a vehicle.

Putting up solar panels on your roof, on the other hand, doesn’t carry the same level of hype from the people around you. What’s worse, they cost the same as a brand new car. To make matters dicier, the number of homeowners who’ve adapted to solar infrastructure isn’t all that many, too.

That aside, the stakes are high. You are, after all, going to install this on your roof. It’s also an adaptation you can’t easily shrug off as, “I’ll do better the next time if I make a mistake now.” Present figures tell us that solar installations are rising and the costs are becoming more feasible. But how much do we know about the said technology and are we personally ready to switch to natural energy?

Here are a few tips to research your solar panels:

Have you tried working on energy efficiency before turning to solar panels?

The whole point of using solar panels is for you to be able to store and conserve natural energy. But apart from that, have you started doing the little things to help better your energy consumption, like turning off the lights when they’re not in use or unplug the television cord when you’re not watching?

The extent of solar energy you need to come up with equates to how much you need. That said, it’s wiser for you to begin consuming your energy much more efficiently before turning to solar panels. You can begin by looking at efficiency upgrades starting with an energy audit before whipping up a blueprint.

Is your roof sturdy enough for solar panels?

This can make or break your solar panel situation. Additionally, if, for most of the day, your roof is covered in shade, then having to splurge a hefty amount for solar panels might not be worth it. You should consider that condition before marching onward.

Also, how sturdy is your roof? Even the lightest panels can be heavy for a decaying house covering. Make sure your roof is in structurally good shape. The usual warranty for solar installations can last up to 25 years and if your roof will need renovation in the next couple of months, you might want to rethink your strategy. Having it renovated first is often the smartest route versus putting up these panels straight away.

Moving forward, another factor is ownership. Many times, house dwellers can’t call the shots because they simply rent the place such a vacation rental property with solar energy system. A good solution to this is resorting to a community solar. This alternative lets more clients buy a stake in these installations and receive electricity bill credits.

Do you trust your installer?

Advertising comes easy nowadays. Don’t trust the first solar installer who hands you a flyer or presents you an ad. You have to remember that solar projects are a combination of electrical work and home improvement. References, credentials, and certifications are important. For instance, do they have accreditation under the North American Board of Certified Energy Practitioners (NABCEP)? It goes without saying that you wouldn’t hire an electrician to come to your home and shake things around when they don’t have sufficient experience. Consider an expert’s number of years in the industry.

It also comes as no surprise that these installations call for big checks. Shop around for installers and get as many quotes as you can before inking a deal. This can be challenging, but try looking for a company that will be available for you throughout your installation. While solar cells are stationary, you’re going to want to work with an installer who will emphatically extend their services even after your warranty period is over.

Which solar-type should you go for?

There are two prevailing solar sciences: the first one is photovoltaic. This technology produces electricity sourced from sunlight. Thermal, the second one makes use of sunlight to heat air or water for your everyday needs. At the end of the day, your context and living conditions help determine what you need the most. Despite that, those who use solar thermal are rare and qualified installers for this aren’t that many.

Buy or lease?

Before diving right into the world of solar panel usage, run a cost-benefit analysis. Is buying your own solar infrastructure the wisest decision you can make? Purchasing your costs more in the beginning, but you’ll have more evident benefits in the long run. On the other hand, renting grants you access to more affordable electricity bills. On top of that, you spend little to no money upfront in this arrangement. The tradeoff, however, is that there are limited monetary benefits for you.

When you rent your system, the company who you ink a deal with owns the infrastructure and you only shell out a certain fee for the electricity. When your rental period is over, they can either take the solar infrastructure back or sell it to you. But if you own your infrastructure, you can reap its advantages long after you’ve bought it. To snag a better deal, weight the lifecycle cost of both arrangements to see where you benefit the most. Factor in how much you earn at present and how much you see yourself earning in the near future. You have to put in a lot of research before you make a decision.

What should your contract contain?

As with any other contract, your welfare should be upheld as these last for long periods. The deal you ink should break down ownership, financing, and performance expectations. You should also factor in data-collecting technology if your infrastructure contains web-enabled devices. Determine who has access to it, if this applies. When there are things or contract segments you’re unsure of, it’s best to consult a legal advisor.

After everything’s been said and done, you’re not only cutting back on costs, you’re also contributing to a healthier planet.

Bioenergy in the Middle East

The Middle East region offers tremendous renewable energy potential in the form of solar, wind and bioenergy which has remained unexplored to a great extent. The major biomass producing Middle East countries are Egypt, Algeria, Yemen, Iraq, Syria and Jordan. Traditionally, biomass energy has been widely used in rural areas for domestic purposes in the Middle East. Since most of the region is arid/semi-arid, the biomass energy potential is mainly contributed by municipal solid wastes, agricultural residues and agro-industrial wastes.

MENA_Bioenergy

Municipal solid wastes represent the best resources for  bioenergy in the Middle East. The high rate of population growth, urbanization and economic expansion in the region is not only accelerating consumption rates but also accelerating the generation of municipal waste. Bahrain, Saudi Arabia, UAE, Qatar and Kuwait rank in the top-ten worldwide in terms of per capita solid waste generation. The gross urban waste generation quantity from Middle East countries is estimated at more than 150 million tons annually.

In Middle East countries, huge quantity of sewage sludge is produced on daily basis which presents a serious problem due to its high treatment costs and risk to environment and human health. On an average, the rate of wastewater generation is 80-200 litres per person each day and sewage output is rising by 25 percent every year. According to estimates from the Drainage and Irrigation Department of Dubai Municipality, sewage generation in the Dubai increased from 50,000 m3 per day in 1981 to 400,000 m3 per day in 2006.

The food processing industry in Middle East produces a large number of organic residues and by-products that can be used as source of bioenergy. In recent decades, the fast-growing food and beverage processing industry has remarkably increased in importance in major countries of the Middle East.

Since the early 1990s, the increased agricultural output stimulated an increase in fruit and vegetable canning as well as juice, beverage, and oil processing in countries like Egypt, Syria, Lebanon and Saudi Arabia. There are many technologically-advanced dairy products, bakery and oil processing plants in the region.

date-wastes

Date palm biomass is found in large quantities across the Middle East

Agriculture plays an important role in the economies of most of the countries in the Middle East.  The contribution of the agricultural sector to the overall economy varies significantly among countries in the region, ranging, for example, from about 3.2 percent in Saudi Arabia to 13.4 percent in Egypt. Cotton, dates, olives, wheat are some of the prominent crops in the Middle East

Large quantities of crop residues are produced annually in the region, and are vastly underutilised. Current farming practice is usually to plough these residues back into the soil, or they are burnt, left to decompose, or grazed by cattle. These residues could be processed into liquid and solid biomass fuels or thermochemically processed to produce electricity and heat in rural areas.

Energy crops, such as Jatropha, can be successfully grown in arid regions for biodiesel production. Infact, Jatropha is already grown at limited scale in some Middle East countries and tremendous potential exists for its commercial exploitation.

The Middle Eastern countries have strong animal population. The livestock sector, in particular sheep, goats and camels, plays an important role in the national economy of the Middle East countries. Many millions of live ruminants are imported into the Middle Eastern countries each year from around the world. In addition, the region has witnessed very rapid growth in the poultry sector. The biogas potential of animal manure can be harnessed both at small- and community-scale.

A Glance at Biggest Dumpsites in Nigeria

Waste dumping is the predominant method for solid waste disposal in developing countries worldwide, and Nigeria is no exception. Nigeria is home to six of the biggest dumpsites in Africa, according to Waste Atlas 2014 report on World’s 50 Biggest Dumpsites published by D-Waste. These dumpsites are located in three most important cities in Nigeria namely, Lagos, Port Harcourt and Ibadan.

Let us have a quick look at the major landfills in Nigeria:

Olusosun

Olusosun is the largest dumpsite not only in Lagos but in Nigeria and receives about 2.1 million tonnes of waste annually comprising mostly of municipal solid waste, construction waste, and electronic waste (e-waste). The dumpsite covers an area of about 43 hectares and it is 18 meters deep.

The dumpsite has been in existence since 1992 and has housed about 24.5 million tonnes of waste since then. A population of about 5 million people lives around 10km radius from the site and numerous health problems like skin irritation, dysentery, water-related diseases, nausea etc. have been reported by residents living around 3km radius from the site.

Solous 2

It is located in Lagos and occupies around 8 hectares of land along Lasu-Iba road. The dumpsite receives about 820,000 tonnes of waste annually and has since its existence in 2006 accepted around 5.8 million tonnes of MSW.

Solous is just 200 meters away from the nearest dwellings and almost 4 million people live within 10km radius from the site. Due to the vulnerable sand formation of the area, leachate produced at the dumpsite flows into groundwater causing its contamination.

Epe

Epe dumpsite also in Lagos occupies about 80 hectares of land. The dumpsite was opened in 2010 and has an annual input of 12,000 tonnes of MSW. Epe is the dumpsite which the Lagos State government is planning to upgrade to an engineered landfill and set to replace Olusosun dumpsite after its closure.

Since its existence, it has received about 47,000 tonnes of waste and it is just 500 meters away from the nearest settlement. The dumpsite is also just 2km away from Osogbo River and 7km away from Lekki Lagoon.

Awotan (Apete)

The dumpsite is located in Ibadan and has been in existence since 1998 receiving 36,000 tonnes of MSW annually. It covers an area of 14 hectares and already has in place almost 525,000 tonnes of waste.

The dumpsite is close to Eleyele Lake (2.5km away) and IITA Forest Reserve (4.5km away). The nearest settlement to the dumpsite is just 200 meters away and groundwater contamination has been reported by nearby residents.

Lapite

Lapite dumpsite is also located in Ibadan occupies an area of 20 hectares receiving around 9,000 tonnes of MSW yearly. Since its existence in 1998, it has housed almost 137,000 tonnes of MSW. It is 9km away from IITA Forest Reserve and surrounded by vegetations on both sides of the road since the dumpsite is directly opposite a major road.

Olusosun is the largest dumpsite in Nigeria

The nearest settlement is about 2km away but due to the heavy metals present in the leachate produced in the waste dump, its leakage poses a great threat to groundwater and biodiversity in the area.

Eneka

It is located in Port Harcourt, the commercial hub of South-South, Nigeria along Igwuruta/Eneka road and 9km from Okpoka River and Otamiri River. It receives around 45,600 tonnes of MSW annually and already has about 12 million tonnes of waste in place.

The site lies in an area of 5 hectares and it is flooded almost all year round as rainfall in the area exceeds 2,500mm per annum. Due to this and the resultant flow of the flood which would have mixed with dumpsite leachate; groundwater, surface water, and soil contamination affect the 1.2 million people living around 10km radius from the site as the nearest building is just 200 meters away.

Electricity Prices Drop 19% in 2 Days Due to Wind Power

Americans are spending over $100 a month on electricity, leading to many poorer people having to go without when cash is running low. Anything that can be done to reduce costs will help people to live comfortably and meet their basic electricity needs. One way to do this is by increasing the production of wind energy. Fortunately, this is exactly what is happening across the European Union and latest figures confirm this.

renewable-energy-germany

AleaSoft is a forecaster of energy production and usage. They regularly do in depth analysis into the energy sector, so that governments and businesses can determine which source of energy is most effective at lowering costs and creating a cleaner atmosphere.

Consistently, research from AleaSoft has shown that as wind power production increases, the overall price of electricity goes down. In the two days between October 7 and October 10 2019, the cost of the average electric bill fell by 19% and further analysis showed that this was as a direct result of investment in wind energy.

Change Between October 7 and October 10

There has been a general trend across the European continent suggesting a fall in prices. However, during the weekdays between Monday October 7 and Thursday October 10, the decline in costs was most significant. The average fall in the price of electricity markets was 19%, although there was significant variation between countries.

Most strikingly, Belgium was able to slash prices by 32%, cutting the cost of the average Belgian’s electricity bill by a third. Other electricity markets showed less of a price fall, such as in Spain and Germany were costs fell by just 7%. Wherever you happen to live in Europe, however, the news is hugely positive. Any drop in prices helps ordinary and low income people to power their homes without feeling restricted.

What is Driving the Fall in Price?

A fall in electricity costs can be for many reasons, so AleaSoft’s research delved into the possible causes of such a significant decline in the energy markets. The sudden drop in prices came at the same time that wind energy production has been ramped up. When wind turbine usage fell, electricity market prices increased. The correlation is so close that this is the only reasonable explanation for the fluctuations in price. 

14% of energy provided in the European Union is produced by wind farms, but 95% of new energy source investments are put towards renewables. This suggests that the overall percentage of electricity from wind will rise exponentially. The UK, Ireland, Germany, and Denmark are the main countries where wind farms are located.

Improved Maintenance Techniques

One of the reasons that European countries are so capable of building new wind farms is improved maintenance techniques. The aerial platform is the easiest way to clean and repair wind turbines, so a dedication to the aerial life has helped to provide turbines which function more efficiently. New generations of aerial lift equipment, skylifts and other aerial platforms are making it easier and cheaper to produce wind power consistently and over long periods of time.

Wind turbines have a reputation of being inefficient. Many believe that their construction is harmful to the environment and that they spend most of their lives switched off and inactive. This is no longer the case, however, and the spike in wind energy production detected by AleaSoft supports the view that maintenance is improving and so too are the capabilities of wind farms.

Even if the environment isn’t a priority, all homeowners long for cheaper electricity. This new report showing the direct link between wind power and lower costs is a great sign. It should boost investment in the technology and ensure a long term and consistent decline in energy costs, as well as a cleaner environment.

Biodiesel Program in India – An Analysis

The Government of India approved the National Policy on Biofuels in December 2009. The biofuel policy encouraged the use of renewable energy resources as alternate fuels to supplement transport fuels (petrol and diesel for vehicles) and proposed a target of 20 percent biofuel blending (both biodiesel and bioethanol) by 2017. The government launched the National Biodiesel Mission (NBM) identifying Jatropha curcas as the most suitable tree-borne oilseed for biodiesel production.

The Planning Commission of India had set an ambitious target covering 11.2 to 13.4 million hectares of land under Jatropha cultivation by the end of the 11th Five-Year Plan. The central government and several state governments are providing fiscal incentives for supporting plantations of Jatropha and other non-edible oilseeds. Several public institutions, state biofuel boards, state agricultural universities and cooperative sectors are also supporting the biofuel mission in different capacities.

renewable-diesel

Biofuels are increasingly being used to power vehicles around the world

State of the Affairs

The biodiesel industry in India is still in infancy despite the fact that demand for diesel is five times higher than that for petrol. The government’s ambitious plan of producing sufficient biodiesel to meet its mandate of 20 percent diesel blending by 2012 was not realized due to a lack of sufficient Jatropha seeds to produce biodiesel.

Currently, Jatropha occupies only around 0.5 million hectares of low-quality wastelands across the country, of which 65-70 percent are new plantations of less than three years. Several corporations, petroleum companies and private companies have entered into a memorandum of understanding with state governments to establish and promote Jatropha plantations on government-owned wastelands or contract farming with small and medium farmers. However, only a few states have been able to actively promote Jatropha plantations despite government incentives.

Key Hurdles

The non-availability of sufficient feedstock and lack of R&D to evolve high-yielding drought tolerant Jatropha seeds have been major stumbling blocks in biodiesel program in India. In addition, smaller land holdings, ownership issues with government or community-owned wastelands, lackluster progress by state governments and negligible commercial production of biodiesel have hampered the efforts and investments made by both private and public sector companies.

Another major obstacle in implementing the biodiesel programme has been the difficulty in initiating large-scale cultivation of Jatropha. The Jatropha production program was started without any planned varietal improvement program, and use of low-yielding cultivars made things difficult for smallholders. The higher gestation period of biodiesel crops (3–5 years for Jatropha and 6–8 years for Pongamia) results in a longer payback period and creates additional problems for farmers where state support is not readily available.

The Jatropha seed distribution channels are currently underdeveloped as sufficient numbers of processing industries are not operating. There are no specific markets for Jatropha seed supply and hence the middlemen play a major role in taking the seeds to the processing centres and this inflates the marketing margin.

Biodiesel distribution channels are virtually non-existent as most of the biofuel produced is used either by the producing companies for self-use or by certain transport companies on a trial basis. Further, the cost of biodiesel depends substantially on the cost of seeds and the economy of scale at which the processing plant is operating.

The lack of assured supplies of feedstock supply has hampered efforts by the private sector to set up biodiesel plants in India. In the absence of seed collection and oil extraction infrastructure, it becomes difficult to persuade entrepreneurs to install trans-esterification plants.

Biomass Pyrolysis Process

Biomass pyrolysis is the thermal decomposition of biomass occurring in the absence of oxygen. It is the fundamental chemical reaction that is the precursor of both the combustion and gasification processes and occurs naturally in the first two seconds. The products of biomass pyrolysis include biochar, bio-oil and gases including methane, hydrogen, carbon monoxide, and carbon dioxide.

Pyrolysis

Depending on the thermal environment and the final temperature, pyrolysis will yield mainly biochar at low temperatures, less than 450 0C, when the heating rate is quite slow, and mainly gases at high temperatures, greater than 800 0C, with rapid heating rates. At an intermediate temperature and under relatively high heating rates, the main product is bio-oil.

Pyrolysis can be performed at relatively small scale and at remote locations which enhance energy density of the biomass resource and reduce transport and handling costs.  Pyrolysis offers a flexible and attractive way of converting solid biomass into an easily stored and transported liquid, which can be successfully used for the production of heat, power and chemicals.

A wide range of biomass feedstocks can be used in pyrolysis processes. The pyrolysis process is very dependent on the moisture content of the feedstock, which should be around 10%. At higher moisture contents, high levels of water are produced and at lower levels there is a risk that the process only produces dust instead of oil. High-moisture waste streams, such as sludge and meat processing wastes, require drying before subjecting to pyrolysis.

The efficiency and nature of the pyrolysis process is dependent on the particle size of feedstocks. Most of the pyrolysis technologies can only process small particles to a maximum of 2 mm keeping in view the need for rapid heat transfer through the particle. The demand for small particle size means that the feedstock has to be size-reduced before being used for pyrolysis.

Pyrolysis processes can be categorized as slow pyrolysis or fast pyrolysis. Fast pyrolysis is currently the most widely used pyrolysis system. Slow pyrolysis takes several hours to complete and results in biochar as the main product. On the other hand, fast pyrolysis yields 60% bio-oil and takes seconds for complete pyrolysis. In addition, it gives 20% biochar and 20% syngas.

Bio-oil

Bio-oil is a dark brown liquid and has a similar composition to biomass. It has a much higher density than woody materials which reduces storage and transport costs. Bio-oil is not suitable for direct use in standard internal combustion engines. Alternatively, the oil can be upgraded to either a special engine fuel or through gasification processes to a syngas and then biodiesel. Bio-oil is particularly attractive for co-firing because it can be more readily handled and burned than solid fuel and is cheaper to transport and store.

Bio-oil can offer major advantages over solid biomass ands gaification due to the ease of handling, storage and combustion in an existing power station when special start-up procedures are not necessary. In addition, bio-oil is also a vital source for a wide range of organic compounds and speciality chemicals.

The Development of Backup Batteries for Renewable Energy

Renewable energy is a force that can help combat climate change. However, without the right proactive steps, there can be pitfalls. For instance, solar power is becoming more widely available but can use some improvements. Solar backup batteries are a critical solution when renewable energy fails.

solar-battery-storage

The Need for Renewability

Renewability is one of the keys to stopping and reversing the climate crisis. It’s time to phase out fossil fuels and harmful environmental practices and focus on sustainable energy sources. There are various deadlines when people must act, and stopping climate change becomes more pressing every day.

However, while renewable energy is a solution, these sources may need a backup system. Often, resources like solar and wind energy are durable and hold up through harsh weather and high demands. When they fail, though, it can leave millions without power. A full renewable system requires constant clean energy.

During the 2020 California wildfires, residents reported their photovoltaic (PV) panels were no longer working, and they were losing power. The ash from the fires was covering the panels, and the smog in the sky was disrupting the transfer of sunlight. During instances like these, a backup plan is necessary.

Battery power is the solution. If solar fails, then the backup system can kick in and keep residents’ homes, schools and companies running.

Integrating Backup Batteries

A backup battery system will most prominently help solar energy setups. While PV panels are versatile, they can nevertheless use assistance. Microgrids will especially benefit from solar backup batteries. The ultimate goal is to keep emissions low at all times — but people will still need power. If a solar system fails, like those in California during the wildfires, then it’s not operating on a fully renewable level.

Experts can integrate batteries into the electrical setup with the proper enclosing tools to prevent surges and stalling. They’ll connect to the lights, HVAC system and other necessities of the building. For schools, internet access may be required to contact parents during blackouts. Businesses may need to keep computers running to prevent data loss.

solar-microgrid

Each system will depend on the supply demands of the location. A smaller home may not need a large network. However, if a solar microgrid powers a university, then the backup battery system will need to account for that demand. Experts must consider the power level of the PV panels, too. That is what will bring solar backup batteries to the next level.

Battery systems can generate power when renewables can’t. It maintains a sustainable impact while still providing people with electricity at all times.

Why It Matters

Renewable energy is groundbreaking. It shows the way forward with no carbon emissions, lower pollution and benefits for public health as well as the environment. While there can be power outages and mishaps with fossil fuels, renewable energy can draw more people in with foolproof generation.

Batteries don’t produce any emissions, so the renewability continues — as does the consistent supply of power. Outages and surges can become less common and not as much of a setback if they do happen.

The partnership of batteries and renewable energy opens up the future. From here, experts will want to work on scalability. Microgrids are a prime area for integrating backup batteries with renewable energy. On larger scales, though, the possibilities could be endless.

Better system setups mean bigger solar and wind farms could also use battery power. While these operations have less chance of failure due to the amount of energy going into them, batteries could still facilitate optimal energy flows and provide backup assistance.

In Development

With energy companies expanding their renewable energy services and integration, every step must receive a backup. Batteries are long-lasting and durable. Adding them to renewable energy setups will create a more foolproof dynamic — one that’s sustainable and always providing power.

Applications of Epoxy Resin in Clean Energy Sector

Epoxy resin is a kind of reactive prepolymer and polymer that contains epoxide groups. It is important to note that epoxy resin is different from other polyester resins in terms of curing. Unlike other resins, instead of using a catalyst as a curing agent, it is cured by an agent known as the hardener. It possesses many desirable properties such as high tensile strength, high adhesive strength, high corrosion resistance, and excellent moisture & chemical resistance. It is also resistant to fatigue, has a long shelf life, and has good electrical and insulating properties. The ability of epoxy resins to be used in various combinations and reinforcements makes it the foundation of a plethora of industries, including clean energy systems.

Applications of Epoxy Resins

Because of the versatile properties of epoxy resins, it is used widely in adhesives, potting, encapsulating electronics, and printed circuit boards. It is also used in the form of matrices for composites in the aerospace industries. Epoxy composite laminates are commonly used for repairing both composite as well as steel structures in marine applications.

Due to its high reactivity, epoxy resin is preferred in repairing boats that have been damaged by impact. Its low shrinking properties and ease of fabrication make it well suited for many tooling applications such as metal-shaping molds, vacuum-forming molds, jigs, patterns etc.

Use of Epoxy Resins in Clean Energy

A variety of industries have been actively trying to find a path that’s moving towards a society that puts less load on the the environment and also contributes towards reducing the carbon footprint. The accelerated use of epoxy resins in generating renewable energy has lead to a rise in its production demand. This is why the epoxy resin market is projected to witness a high demand and growth rate by 2022. Here are some of the sectors contributing to the production of clean energy and how they utilize epoxy resin for their functioning:

  • Solar Energy

The harnessing of solar energy dates back to 700 B.C, when people used a magnifying glass to focus the sun’s rays to produce fire. Today solar power is a vigorously developing energy source around the globe. It not only caters to the rising energy requirements but also the need to protect the environment from the exploitation of exhaustible energy resources.

A piece of average solar equipment endures intense environmental conditions such as scorching heat, UV radiations, bitter cold,  pouring rain, hail, storms, and turbulent winds. To withstand such conditions, the sealing and mounting application of epoxy resins increase the environmental tolerance of the solar equipment.

With their high mechanical strength, impressive dimensional stability and excellent adhesion properties, they are used to protect the solar panels from a wide range of temperatures. Epoxies are cheap, less labor-intensive and easy to apply.

  • Wind Energy

The global wind industry has quickly emerged as one of the largest sources of renewable energy around the world. The wind energy in the U.S. alone grew by 9% in 2017 and today is the largest source for generating clean energy in the country. With such a tremendous demand for wind power, the need for fabricating bigger and better wind turbine blades is also rising. The industry is in a dearth of long-lasting blades, that endure the harsh climatic conditions and wear tear and are able to collect more wind energy at a time.

Sealing and mounting application of epoxy resins increase the environmental tolerance of the solar equipment

Epoxy thermosets are used for making the blades more durable because of their high tensile strength and high creep resistance. Mixing of epoxy resins with various toughening agents and using them on the blades have shown positive results towards making the blades corrosion resistant and fatigue-proof.

  • Hydropower

Hydropower is an essential source of renewable and clean energy. As the hydropower industry is developing rapidly, the solution for protecting the hydropower concrete surfaces against low temperatures and lashing water flow has also been looked into.

As a solution to this issue, epoxy mortar, a mixture of epoxy resins, binder, solvent, mineral fillers, and some additives has proven to be the most effective material used for surface protection. Owing to the properties like non-permeability, adhesive strength, anti-erosive nature, and non-abrasiveness, epoxy mortar paste has been used as a repairing paste in the hydropower industry.

Over the last few decades, epoxy resins have contributed immensely in the maintenance and protection of clean energy sources, helping them to become more efficient and productive.

Final Thoughts

While many argue that factors like a relatively high cost when compared to petroleum-based resins and conventional cement-mortar alternatives has affected the epoxy resin market growth, the fact remains that epoxy resin never fails to deliver top-notch and unmatchable results in the areas of application.

Biomass Wastes from Palm Oil Mills

The Palm Oil industry generates large quantity of wastes whose disposal is a challenging task. In the Palm Oil mill, fresh fruit bunches are sterilized after which the oil fruits can be removed from the branches. The empty fruit bunches (are left as residues, and the fruits are pressed in oil mills. The Palm Oil fruits are then pressed, and the kernel is separated from the press cake (mesocarp fibers). The palm kernels are then crushed and the kernels then transported and pressed in separate mills.

palm-biomass

In a typical palm oil mill, almost 70% of the fresh fruit bunches are turned into wastes in the form of empty fruit bunches, fibers and shells, as well as liquid effluent. These by-products can be converted to value-added products or energy to generate additional profit for the Palm Oil Industry.

Palm Kernel Shells (PKS)

Palm kernel shells (or PKS) are the shell fractions left after the nut has been removed after crushing in the Palm Oil mill. Kernel shells are a fibrous material and can be easily handled in bulk directly from the product line to the end use. Large and small shell fractions are mixed with dust-like fractions and small fibres.

Moisture content in kernel shells is low compared to other biomass residues with different sources suggesting values between 11% and 13%. Palm kernel shells contain residues of Palm Oil, which accounts for its slightly higher heating value than average lignocellulosic biomass. Compared to other residues from the industry, it is a good quality biomass fuel with uniform size distribution, easy handling, easy crushing, and limited biological activity due to low moisture content.

Press fibre and shell generated by the Palm Oil mills are traditionally used as solid fuels for steam boilers. The steam generated is used to run turbines for electricity production. These two solid fuels alone are able to generate more than enough energy to meet the energy demands of a Palm Oil mill.

Empty Fruit Bunches (EFBs)

In a typical Palm Oil mill, empty fruit bunches are abundantly available as fibrous material of purely biological origin. EFB contains neither chemical nor mineral additives, and depending on proper handling operations at the mill, it is free from foreign elements such as gravel, nails, wood residues, waste etc. However, it is saturated with water due to the biological growth combined with the steam sterilization at the mill. Since the moisture content in EFB is around 67%, pre-processing is necessary before EFB can be considered as a good fuel.

In contrast to shells and fibers, empty fruit bunches are usually burnt causing air pollution or returned to the plantations as mulch. Empty fruit bunches can be conveniently collected and are available for exploitation in all Palm Oil mills. Since shells and fibres are easy-to-handle, high quality fuels compared to EFB, it will be advantageous to utilize EFB for on-site energy demand while making shells and fibres available for off-site utilization which may bring more revenues as compared to burning on-site.

Palm Oil Mill Effluent (POME)

Palm Oil processing also gives rise to highly polluting waste-water, known as Palm Oil Mill Effluent, which is often discarded in disposal ponds, resulting in the leaching of contaminants that pollute the groundwater and soil, and in the release of methane gas into the atmosphere. POME could be used for biogas production through anaerobic digestion. At many palm oil mills this process is already in place to meet water quality standards for industrial effluent. The gas, however, is flared off.

In a conventional Palm Oil mill, 600-700 kg of POME is generated for every ton of processed FFB. Anaerobic digestion is widely adopted in the industry as a primary treatment for POME. Liquid effluents from palm oil mills can be anaerobically converted into biogas which in turn can be used to generate power through gas turbines or gas-fired engines.

Conclusions

Most of the Biomass residues from Palm Oil Mills are either burnt in the open or disposed off in waste ponds. The Palm Oil industry, therefore, contributes significantly to global climate change by emitting carbon dioxide and methane. Like sugar mills, Palm Oil mills have traditionally been designed to cover their own energy needs (process heat and electricity) by utilizing low pressure boilers and back pressure turbo-generators. Efficient energy conversion technologies, especially thermal systems for crop residues, that can utilize all Palm Oil residues, including EFBs, are currently available.

In the Palm Oil value chain there is an overall surplus of by-products and their utilization rate is negligible, especially in the case of POME and EFBs. For other mill by-products the efficiency of the application can be increased. Presently, shells and fibers are used for in-house energy generation in mills but empty fruit bunches is either used for mulching or dumped recklessly. Palm Oil industry has the potential of generating large amounts of electricity for captive consumption as well as export of surplus power to the public grid.

Trends in Global Waste to Energy Market

Waste-to-Energy is the use of modern combustion and biochemical technologies to recover energy, usually in the form of electricity and steam, from urban wastes. These new technologies can reduce the volume of the original waste by 90%, depending upon composition and use of outputs. The main categories of waste-to-energy technologies are physical technologies, which process waste to make it more useful as fuel; thermal technologies, which can yield heat, fuel oil, or syngas from both organic and inorganic wastes; and biological technologies, in which bacterial fermentation is used to digest organic wastes to yield fuel.

WTE_Market

The global market for waste-to-energy technologies was valued at US$6.2bn in 2012 which is  forecasted to increase to US$29.2bn by 2022. While the biological WTE segment is expected to grow more rapidly from US$1.4bn in 2008 to approximately US$2.5bn in 2014, the thermal WTE segment is estimated to constitute the vast bulk of the entire industry’s worth. This segment was valued at US$18.5bn in 2008 and is forecasted to expand to US$23.7bn in 2014.

The global market for waste to energy technologies has shown substantial growth over the last five years, increasing from $4.83 billion in 2006, to $7.08 billion in 2010 with continued market growth through the global economic downturn. Over the coming decade, growth trends are expected to continue, led by expansion in the US, European, Chinese, and Indian markets.

By 2021, based on continued growth in Asian markets combined with the maturation of European waste management regulations and European and US climate mitigation strategies, the annual global market for waste to energy technologies will exceed $27 billion, for all technologies combined.

Asia-Pacific’s waste-to-energy market will post substantial growth by 2015, as more countries view the technology as a sustainable alternative to landfills for disposing waste while generating clean energy. In its new report, Frost & Sullivan said the industry could grow at a compound annual rate of 6.7 percent for thermal waste-to-energy and 9.7 percent for biological waste-to-energy from 2008 to 2015.

The WTE market in Europe is forecasted to expand at an exponential rate and will continue to do so for at least the next 10 years. The continent’s WTE capacity is projected to increase by around 13 million tonnes, with almost 100 new WTE facilities to come online by 2012. In 2008, the WTE market in Europe consisted of approximately 250 players due in large to the use of bulky and expensive centralized WTE facilities, scattered throughout Western Europe.