Monthly Archives: October 2022

5 Solar Panel Facts You Might Not Know

  By | | , , ,
3 Comments

Over the last decade, it seems that the cost of electricity has risen in most areas. This is one of the reasons why so many people are getting solar energy systems installed in their homes. Due to its rise in popularity, we have seen prices for solar panels and other equipment needed to make your home more eco-friendly decrease.

Because solar energy is still fairly new technology, many people still know very little about the industry. To help you out, we have compiled a few interesting facts about solar panels which you might find interesting.

As the industry grows, you will probably be hearing much more about solar panels and the benefits of using this eco-friendly method to provide energy for your home. Below are solar panel FAQs to remember:

solar-energy-diy

 

1. The First Solar Panel Cell was Discovered in 1941

Although it seems like solar panels have only been around for the last few decades, the world’s first solar panel cell was invented by Russell Ohl in 1941. Shortly after the invention of the first solar panel cell was invented, Bell Laboratories came up with the world’s first commercial panel in 1954.

Although it seems we are still at the stone age of solar power, photovoltaic (the conversion of light into electricity) was discovered by French scientist Alexandre Edmond Becquerel in 1839.

2. In the Long Run, Solar Power can help Save you Money

Although the initial cost of installing a solar system in your home might be frightening, the overall running cost of the system can save you a lot of money. Although prices of installation and equipment are becoming more affordable, it still is expensive for the average household.

However, try to keep in mind that you won’t ever have to pay to heat or cool down your house again (assuming your solar panels power system can provide enough energy throughout the year for your home). The average household spends $1,300 annually on their electricity bill.

Throughout the world, it seems more and more governments are trying to encourage homeowners and business owners to invest in solar panels. Lots of governments have offered people incentives and tax breaks in the hope that the number of households using this eco-friendly method will increase. In some states in America, people who purchase solar panels are eligible for a 30% tax break. Also, some states allow those who own solar power to sell their excess energy, so they can make some profit from their system.

3. A Communal Effort

Community solar systems are becoming more common these days. Instead of just having an individual solar system in your home, more communities are investing in community solar systems instead.

Over the last 15 years or so, instead of each household having individual systems installed, whole communities are getting together and investing in a system that will provide energy for the entire community. If you are considering making your home more eco-friendly, why not speak to others in your community to see if everybody on the block is interested in getting a communal solar system installed instead?

what-is-community-solar

4. The Industry is Growing Extremely Fast

Between 2018 and 2010, the number of households and businesses having solar power installed in their buildings grew 23 times in the United States. Solar power is not only becoming more appealing to homeowners in the United States, but it seems like people all over the world are deciding to go green and install solar power systems into their homes.

China uses more solar power than any other country on the planet. The Chinese government has been offering the residents of the country plenty of incentives that has resulted in many people installing a solar power system in their home.

If you are thinking about installing a solar power system inside your home, check out Solar Panels Network USA for more information. If you are still on the fence about joining the solar power movement, ask them for advice.

5. Maintaining a Solar Power System

Maintaining your solar power system tends to be fairly cheap too. In fact, once the system is fully installed there is actually very little maintenance needed. Apart from cleaning the panels now and again, and making sure that it’s getting sunlight and not shaded, it should work smoothly. You may have to trim some trees at times but that’s about it.

solar-panels-pigeon-issue

Most solar panels have been installed on a tilted roof, so when the rain hits it will clean any dust and dirt from the panel so you won’t have to clean it too often.

Most solar power system suppliers offer 25 year warranty, but it is not too uncommon to see a quality solar power system last for 40 years. If your system does manage to last for that length of time, you can imagine how much money you will save on electricity.

6 Easiest Ways to Save Money on Your Utility Bills

  By | | , ,
11 Comments

As the climate warms, it’s more important than ever to consider how you can lower your carbon footprint as a homeowner.And lowering your carbon footprint has another huge benefit: you can often save money as a result of green upgrades to your home. For example, solar energy can save you around $600 a year in energy costs. Of course, there are many other reasons why you should use solar energy, but the primary reason to use it is that it is a renewable source, i.e., it will last for billions of years.

Besides making structural changes—like adding solar panels, for example, to your home, there are other ways to save on your utility bills such as turning off lights you’re not using. Below, we’ve gathered our tops tips for saving money on utility bills – and helping out the planet, too!

1. Take advantage of sunshine during the winter

The sun is basically free heat for your home. Homeowners can take advantage of what’s called passive solar design. During the day, open the curtains on south-facing windows to let the sunshine inside so it can warm up your house. This will keep your home considerably hotter during the colder months.

Don’t forget to close the curtains when the sun sets so you can keep as much of that trapped solar heat as possible. Consider investing in thick, insulated curtains, which will help keep heat inside your living spaces.

2. Pay attention to your ceiling fan’s rotation in winter and summer

As you may know, warm air rises. Instead of letting that warm air go up, up and away, you can leverage your ceiling fan to keep that warm air close to you and your family. Reverse your ceiling fan’s rotation so that it turns clockwise instead of counterclockwise. This will keep the hot air in your living spaces. And during the hotter months, make sure the fan is spinning counterclockwise to pull hot air away from you. It is also advisable to hire reputed electricians like ADC Electric who provide quality service and safety to electrical systems in residential properties.

3. Get a new roof

A new roof can make a huge difference in your energy savings. Best of all? Energy-efficient roofing helps you save money in both the colder and warmer months. Many new types of roofing are “cool roofs” which reflect more of the sun’s rays instead of allowing solar heat to permeate into the home. This means that you don’t have to run the AC as low or as often. In the winter, a new roof helps prevent warm air from escaping.

Plus, in many areas, you might be eligible for a government tax incentive for replacing an old roof with an energy-efficient version.

4. Seal drafts around windows, doors, and other areas of your home

One of the best methods for determining what areas of your home can be more energy-efficient is by conducting a DIY energy audit. To do an energy audit, light an incense stick and watch to see if smoke is pulled to cracks in the windows or under the doors. You can also sometimes feel drafts by simply putting your palm up around the edges of windows and doors. Once you find drafty areas, it’s important to seal up those holes with weather stripping or caulking.

Fixing air leaks will benefit you both in the summer and the winter because it helps keep your HVAC system from working overtime.

5. Invest in a smart thermostat

A smart thermostat is a prudent investment, especially if you regularly forget to turn off the A/C or heat when you leave for work or errands. That wasted energy can add up to a big utility bill at the end of the month. A smart thermostat regulates the temperature and automatically programs a specific range to keep you comfortable but turns off in unoccupied rooms.

6. Schedule regular maintenance

Routine maintenance is essential to promote the longevity of your HVAC system and to ensure that your home isn’t wasting energy. Make sure to replace filters at least once a month and keep tabs on how old your HVAC system is, most systems need to be replaced every 15-20 years.

Takeaways

There are a variety of reasons as to why it’s in your best interest to find ways to make your home greener. Not only do green upgrades ultimately save you money, they also help the planet during a time when a climate emergency is threatening our very existence. If you want to see a smaller utility bill and live a more eco-friendly life, utilize some of the tips mentioned in this article. You’ll save money and help save earth, too. However, if you can’t pay your bills with savings, consider getting a loan. KashPilot does not consider your credit history when granting loans.

Biochemical Method for Ethanol Production

  By | | , ,
5 Comments

Ethanol from lignocellulosic biomass is produced mainly via biochemical route. The three major steps involved in the biochemical method for ethanol production are pretreatment, enzymatic hydrolysis, and fermentation. Biomass is pretreated to improve the accessibility of enzymes. After pretreatment, biomass undergoes enzymatic hydrolysis for conversion of polysaccharides into monomer sugars, such as glucose and xylose. Subsequently, sugars are fermented to ethanol by the use of different microorganisms.

Bioethanol-production-process

Pretreated biomass can directly be converted to ethanol by using the process called simultaneous saccharification and cofermentation (SSCF). Pretreatment is a critical step which enhances the enzymatic hydrolysis of biomass.

Basically, it alters the physical and chemical properties of biomass and improves the enzyme access and effectiveness which may also lead to a change in crystallinity and degree of polymerization of cellulose. The internal surface area and pore volume of pretreated biomass are increased which facilitates substantial improvement in accessibility of enzymes. The process also helps in enhancing the rate and yield of monomeric sugars during enzymatic hydrolysis steps.

Pretreatment methods can be broadly classified into four groups – physical, chemical, physio-chemical and biological. Physical pretreatment processes employ the mechanical comminution or irradiation processes to change only the physical characteristics of biomass. The physio-chemical process utilizes steam or steam and gases, like SO2 and CO2. The chemical processes employs acids (H2SO4, HCl, organic acids etc) or alkalis (NaOH, Na2CO3, Ca(OH)2, NH3 etc).

The acid treatment typically shows the selectivity towards hydrolyzing the hemicelluloses components, whereas alkalis have better selectivity for the lignin. The fractionation of biomass components after such processes help in improving the enzymes accessibility which is also important to the efficient utilization of enzymes.

The pretreated biomass is subjected to enzymatic hydrolysis using cellulase enzymes to convert the cellulose to fermentable sugars. Cellulase refers to a class of enzymes produced chiefly by fungi and bacteria which catalyzes the hydrolysis of cellulose by attacking the glycosidic linkages. Cellulase is mixture of mainly three different functional protein groups: exo-glucanase (Exo-G), endo-glucanase(Endo-G) and ?-glucosidase (?-G).

The functional proteins work synergistically in hydrolyzing the cellulose into the glucose. These sugars are further fermented using microorganism and are converted to ethanol. The microorganisms are selected based on their efficiency for ethanol productivity and higher product and inhibitors tolerance. Yeast Saccharomyces cerevisiae is used commercially to produce the ethanol from starch and sucrose.

Escherichia coli strain has also been developed recently for ethanol production by the first successful application of metabolic engineering. E. coli can consume variety of sugars and does not require the complex growth media but has very narrow operable range of pH. E. coli has higher optimal temperature than other known strains of bacteria.

Lower GHG emissions and empowerment of rural economy are major benefits associated with bioethanol

The major cost components in bioethanol production from lignocellulosic biomass are the pretreatment and the enzymatic hydrolysis steps. In fact, these two process are someway interrelated too where an efficient pretreatment strategy can save substantial enzyme consumption.

Pretreatment step can also affect the cost of other operations such as size reduction prior to pretreatment. Therefore, optimization of these two important steps, which collectively contributes about 70% of the total processing cost, are the major challenges in the commercialization of bioethanol from 2nd generation feedstock.

Enzyme cost is the prime concern in full scale commercialization. The trend in enzyme cost is encouraging because of enormous research focus in this area and the cost is expected to go downward in future, which will make bioethanol an attractive option considering the benefits derived its lower greenhouse gas emissions and the empowerment of rural economy.

Breaking Down the Process of Biofuel Production

  By | | , , ,
1 Comment

Biofuels are renewable and sustainable forms of energy. They can reduce greenhouse emissions by almost 30%, which means that although they do release carbon dioxide into the atmosphere, they do so in a very limited manner.

With the aim of building a green new world, and eliminating the need for fossil fuel and other traditional energy sources, people are now turning towards biofuel to meet their daily needs. Thus, we see biofuel being used for transportation in many countries. It’s also being used to generate electricity. The rural areas in many underdeveloped and developing countries will use biofuel for their cooking purposes as well. All in all, this particular fuel has diverse uses.

Biofuel is produced from biomass, which itself is treated as a clean energy source. We can produce biofuel from biomass through a series of steps. These steps can be performed even in our houses if we have the right materials. A quick overview of the whole biofuel production process is described below.

biofuel-production

1. Filtration

The purpose of the filtration process is to get rid of the unnecessary particles from the biomass. In this step, we take the waste vegetable oil and then heat it to a certain degree. Once the liquid has been heated, the waste particles will automatically separate themselves from the main mixture. Afterward, we just have to filter it with a regular filter paper.

2. Water removal

Next, we need to remove water from the residual gangue. If the water is allowed to stay in the mixture, it’ll end up delaying the overall process. By removing all the water, we can make the reaction move a lot faster. The easiest way to remove water from the mixture is by heating it steady at 212 degrees F for some time.

3. Titration

Titration is conducted on the mixture to determine the amount of chemical catalyst (like lye) that will be needed. The catalyst is a key component in any chemical reaction. It pretty much determines how fast and how much of a product we’re going to receive. Thus, this step is very important in the biofuel manufacturing process.

4. Sodium methoxide preparation

In this step, we take methanol (18-20% of the waste vegetable oil) and mix it with sodium hydroxide. This gives us sodium methoxide, which is also used as a catalyst in the reaction. It helps perform synthesis reactions on the reagents and facilitates the overall reaction process. Sodium methoxide is a key ingredient in this manufacturing process. It’s considered to be a standard substance used to accelerate the reaction, and yield better results.

5. Mixing and heating

Next, we heat the residue between 120-130 degrees F. Afterward, we mix it properly. This process aims to evenly distribute the mixture. This will help the mixture to settle down later on, and cool off, after which we can begin the extraction process. In a way, the mixing and heating stage can be seen as the final preparation before extraction.

biofuel-production

6. Setting

Once the mixing is completed, the liquid is allowed to cool and settle down, after which we can extract the final product, i.e. the biofuel.

7. Separation

After the liquid has cooled, the biofuel can be extracted from the top of the mixture. It’ll be found floating on top, like oil in water. To get the biofuel, we’ll have to remove the glycerin underneath it. This can be done by simply draining it out from the bottom, and keeping the fuel afloat. The biofuel is finally ready.

The whole process described above is for a small-scale operation. However, it can be scaled up as needed, given that you have the right tools, ingredients, and setup.

It should also be noted that chemical catalysts (such as lye) are used in the manufacturing process as well. Recently, however, scientists and researchers are looking into the use of ultrasonics as additional catalysts. According to recent observations, a combination of chemicals and ultrasonics can lead to a higher yield of fuel, and reduce the overall processing time. This also leads to better utilization of biomass.

Companies such as Coltraco (https://coltraco.com/) are now using ultrasonic systems and technology in a wide variety of fields, one of which is the renewable energy industry. And while the technology’s use in other fields has gained more traction in recent times, it shouldn’t be long before it’s used in biofuel manufacturing, as well as in other renewable energy sectors, in full swing.

So You Want To Get Into Crypto? Points To Note For Beginners

  By | | ,
1 Comment

Are you looking forward to making a cryptocurrency investment? Well, 2022 is the right time to get into crypto investment, if you haven’t already. Undoubtedly cryptocurrency investment has picked up the pace, and people are showing interest in cryptocurrencies at https://immediate-edge.pl. This is not just limited to investment. Even big organizations are investing thousands of dollars in acquiring bitcoin. Hence we can say that bitcoin is gaining popularity and is the future of the financing system.

bitcoin-introduction

For a starter in the crypto trading world, the task can be overwhelming. Filtering out the best cryptocurrency from more than 10,000 options available in the market, choosing the right trading platform, and formulating the best trading strategies that can give positive outcomes, everything can be challenging task if You are not aware of how the crypto market operates. Hence this guide is an attempt to take you through some of the key aspects of the crypto domain that will help you in deciding your course of action in crypto investment.

Get The Inside Scoop On The Crypto Market!

  • There are more than 10,000 cryptocurrencies in the market, and the number is only going to increase with all the options that are available in the market; bitcoin continues to reign supreme.
  • Being a pioneer in the crypto world, this cryptocurrency enjoys a special position in the market.
  • It also has the highest capitalization value of $650 billion and hence is one of the most popular choices of investors.
  • Big organizations are investing thousands of dollars in Bitcoin; for example, MicroStrategy Inc. purchased more than $1 billion of Bitcoin in 2020.
  • There are around 15,000 organizations globally accepting bitcoin payments.
  • You can now make payment for your coffee or pizza with bitcoin or even make travel bookings using bitcoin

Bitcoin – What You Need To Know About The Future Of Cryptocurrency

Many financial investors consider Bitcoins that is equal to gold. Despite the downfall in its value, it has not affected the interest of the investors in this cryptocurrency. The concept of bitcoin was introduced after the great recession of 2009.

Although in 2009, bitcoin did not gain much acceptance, there were several apprehensions surrounding the cryptocurrency. By 2013 the scenario completely changed, and today it is considered to be one of the most popular and profitable investment assets.

As per Deloitte, more than 2300 businesses across the US or now accepting bitcoins as the mode of payment. Going figure highlights that bitcoin is a great investment as it is, and you should consider it as a part of your investment profile.

Things To Keep In Mind When Converting Bitcoins To Cash

 

The Future of Bitcoin: How to Invest Now and Profit Later

Now that you know about the crypto market and the development that has taken place in this field over the years, the next big step is to start investing in it. However, as a fresher, you must know about the right steps to invest in it. The following tips are going to help you in the same:

  • Begin with basic research about crypto trading platforms. One of the first and most important steps is to finalize the best trading platform where you can register yourself and explore the different cryptocurrencies. As an investor, you would like to invest in different cryptocurrencies, and hence the trading platform that you are you are choosing should offer you this feature.
  • Since the crypto market is susceptible to volatility, it is always recommended that one should invest in different cryptocurrencies to reduce the impact of price volatility. For example, the value of bitcoin plummeted in 2022; conversely, in 2021, the value of bitcoin had risen to $65,000. Diversifying your portfolio reduces the impact since you’re your investment is not dependent on just one cryptocurrency.
  • If you are a beginner and this is your first move in the crypto world, it is recommended that you should begin with a smaller investment, and once you have an understanding of how the market is operating, you can increase your investment.

Conclusion

This brief information on the crypto world and how crypto trading operates will help you in defining your investment strategies and ensure that your journey as a crypto trader is profitable.

Plastic Wastes and its Management

  By | | , ,
25 Comments

Plastic seems all pervasive and unavoidable. Since the 1960s our use of plastic has increased dramatically, and subsequently, the portion of our garbage that is made up of plastic has also increased from 1% of the total municipal solid waste stream (household garbage) to approximately 13% (US Environmental Protection Agency).

Plastic products range from things like containers and packaging (soft drink bottles, lids, shampoo bottles) to durable goods (think appliances, furniture and cars) and non-durable goods including things from a plastic party tray to medical devices. Sometimes marked with a number and a chasing arrow, there is an illusion that all plastics are recyclable, and therefore recycled. But there are a number of problems with this assumption.

plastic-wastes

While use and consumption of plastic is increasingly high, doubts about viable options for reuse, recycling and disposal are also on the rise. Complications such as the increasing number of additives used alter the strength, texture, flexibility, colour, resistance to microbes, and other characteristics of plastics, make plastics less recyclable. Additionally, there is very little market value in some plastics, leading municipalities to landfill or incinerate plastics as waste. Based on figures from the EPA (2011 data) only 8% of plastic materials are recovered through recycling.

Another major concern about plastics in the waste stream is their longevity and whether or not they are truly biodegrade. It is estimated that most plastics would take 500-1000 years to break down into organic components. Because of this longevity and the low rate of recycling, much of our plastic waste ends up in landfills or as litter. Some of this plastic waste makes its way via rivers and wind to the ocean. Garbage barges, and the trans-continental transport of recyclable materials also lead to an increasing amount of plastics in our oceans and waterways.

Plastic waste directly and indirectly affects living organisms throughout the ecosystem, including an increasingly high impact on marine life at a macro and micro scale. According to United Nations, almost 80% of marine debris is plastic. Policy enforcement remains weak, global manufacture of plastics continues to increase, and the quantity of plastic debris in the oceans, as well as on land, is likely to increase.

With limited sustainable recovery of plastics, there is a growing global movement to reduce the generation of plastic. Certain types of plastic may be ’safer‘ for the environment than others, however, there are troubling issues associated with all of them, leading to the conclusion that action is needed to remove plastic waste, and stricter controls are required to limit new sources of plastic pollution.

biodegradable-plastics

Efforts such as light weighting of packaging and shifts to compostable plastics are options. Many people use eco-friendly bags for the sake of green living. Policies limiting the use of plastics such as bottle bills and bag bans are other ways to decrease the production and consumption of plastics.

Mining the debris fields in our oceans and turning plastic waste into usable materials, from socks made of fishing line to fuel made from a variety of plastic debris, is one way to mitigate the current situation. You can do your part by using renewable cotton bags.

Note: This excerpt is being published with the permission of our collaborative partner Be Waste Wise.

Solid Waste Management – India’s Burning Issue

  By | | , ,
19 Comments

For the first time in the history of India, the year 2012 saw several public protests against improper solid waste management all across India – from the northernmost state Jammu and Kashmir to the southernmost Tamil Nadu. A fight for the right to clean environment and environmental justice led the people to large scale demonstrations, including an indefinite hunger strike and blocking roads leading to local waste handling facilities. Improper waste management has also caused a Dengue Fever outbreak and threatens other epidemics.

In recent years, solid waste management has been the only other unifying factor leading to public demonstrations all across India, after corruption and fuel prices. Public agitation resulted in some judicial action and the government’s remedial response, but the waste management problems are still unsolved and might lead to a crisis if this continues for too long without any long term planning and policy reforms.

Solid-Wastes-India

Hunger Strike in Kerala

The President of Vilappilsala Village Panchayat went on a hunger strike recently, against her counterpart, the Mayor of Thiruvananthapuram. Thiruvananthapuram is the state capital of Kerala, and Vilappilsala is a village 22 km away.

Since July 2000, about 80% of the waste generated in Thiruvananthapuram is being transported to a waste composting plant and a dumpsite in Vilappilsala village. Since the same month, respiratory illnesses reported in Vilappil Primary Health Center increased by 10 times from an average of 450 to 5,000 cases per month. People who used to regularly swim in the village’s aquifer started contracting infections; swarms of flies have ever since been pervasive; and a stigma of filth affected households throughout the community. This was a source of frustration as locals who, as Indians, prize the opportunity to feed and host guests, found them unwilling to even drink a glass of water in their homes. Currently, there is not a single household which has not experienced respiratory illnesses due to the waste processing plant and the adjoining dumpsite.

On the other hand, Thiruvananthapuram’s residents had to sneak out at night with plastic bags full of trash to dispose them behind bushes, on streets or in water bodies, and had to openly burn heaps of trash every morning for months. This was because the waste generated was not being collected by the City as it could not force open the composting plant and dumpsite against large scale protests by Vilappilsala’s residents. This is why in August – 2012, about 2,500 police personnel had to accompany trucks to the waste treatment plant as they were being blocked by local residents lying down on the road, and by some, including the village’s President, by going on an indefinite hunger strike.

Municipal Commissioner Replaced in Karnataka

In response to a similar situation in Bengaluru, the state capital of Karnataka, where the streets were rotting with piles of garbage for months, the municipal commissioner of the city was replaced to specifically address the waste management situation. Against the will of local residents, a landfill which was closed following the orders issued by the state’s pollution control board in response to public agitation had to be reopened soon after its closure as the city could not find a new landfill site.

Mavallipura landfill in Bangalore

Population density and the scale of increasing urban sprawl in India make finding new landfill sites around cities nearly impossible due to the sheer lack of space for Locally Unwanted Land Uses (LULUs) like waste management.

Dengue Outbreak in West Bengal

Even if partially because of improper waste management, Kolkata, state capital of West Bengal and the third biggest city in India experienced a Dengue Fever outbreak with 550 confirmed cases and 60 deaths. This outbreak coincides with a 600% increase in dengue cases in India and 71% increase in malarial cases in Mumbai in the last five years.

Accumulation of rain water in non biodegradable waste littered around a city act as a major breeding environment for mosquitoes, thus increasing the density of mosquito population and making the transmission of mosquito related diseases like dengue, yellow fever and malaria easier.

Rabies in Srinagar

Rabies due to stray dog bites already kills more than 20,000 people in India every year. Improper waste management has caused a 1:13 stray dog to human ratio in Srinagar (compared to 1 per 31 people in Mumbai and 1 per 100 in Chennai), where 54,000 people were bitten by stray dogs in a span of 3.5 years. Municipal waste on streets and at the dumpsite is an important source of food for stray dogs.

The ultimate solution to controlling stray dogs is effective waste management. The public has been protesting about this stray dog menace for months now with no waste management solutions in sight, but only partial short term measures like dog sterilization.

Waste-to-Energy Sector in China: Perspectives

  By | | , ,
5 Comments

China is the world’s largest waste generator, producing as much as 175 million tons of waste every year. With a current population surpassing 1.37 billion and exponential trends in waste output expected to continue, it is estimated that China’s cities will need to develop an additional hundreds of landfills and waste-to-energy plants to tackle the growing waste management crisis.

garbage-china

China’s three primary methods for municipal waste management are landfills, incineration, and composting. Nevertheless, the poor standards and conditions they operate in have made waste management facilities generally inefficient and unsustainable. For example, discharge of leachate into the soil and water bodies is a common feature of landfills in China. Although incineration is considered to be better than landfills and have grown in popularity over the years, high levels of toxic emissions have made MSW incineration plants a cause of concern for public health and environment protection.

Prevalent Issues

Salman Zafar, a renowned waste management, waste-to-energy and bioenergy expert was interviewed to discuss waste opportunities in China. As Mr. Zafar commented on the current problems with these three primary methods of waste management used by most developing countries, he said, “Landfills in developing countries, like China and India, are synonymous with huge waste dumps which are characterized by rotting waste, spontaneous fires, toxic emissions and presence of rag-pickers, birds, animals and insects etc.” Similarly, he commented that as cities are expanding rapidly worldwide, it is becoming increasingly difficult to find land for siting new landfills.

On incineration, Zafar asserted that this type of waste management method has also become a controversial issue due to emission concerns and high technology costs, especially in developing countries. Many developers try to cut down costs by going for less efficient air pollution control systems”. Mr. Zafar’s words are evident in the concerns reflected in much of the data ­that waste management practices in China are often poorly monitored and fraudulent, for which data on emission controls and environmental protection is often elusive.

Similarly, given that management of MSW involves the collection, transportation, treatment and disposal of waste, Zafar explains why composting has also such a small number relative to landfills for countries like China. He says, “Composting is a difficult proposition for developing countries due to absence of source-segregation. Organic fraction of MSW is usually mixed with all sorts of waste including plastics, metals, healthcare wastes and industrial waste which results in poor quality of compost and a real risk of introduction of heavy metals into agricultural soils.”

Given that China’s recycling sector has not yet developed to match market opportunities, even current treatment of MSW calls for the need of professionalization and institutionalization of the secondary materials industry.

While MSW availability is not an issue associated with the potential of the resource given its dispersion throughout the country and its exponential increase throughout, around 50 percent of the studies analyzed stated concerns for the high moisture content and low caloric value of waste in China, making it unattractive for WTE processes.

Talking about how this issue can be dealt with, Mr. Zafar commented that a plausible option to increase the calorific value of MSW is to mix it with agricultural residues or wood wastes. Thus, the biomass resources identified in most of the studies as having the greatest potential are not only valuable individually but can also be processed together for further benefits.

Top Challenges

Among the major challenges on the other hand, were insufficient or elusive data, poor infrastructure, informal waste collection systems and the lack of laws and regulations in China for the industry. Other challenges included market risk, the lack of economic incentives and the high costs associated with biomass technologies. Nevertheless, given that the most recurring challenges cited across the data were related to infrastructure and laws and regulations, it is evident that China’s biomass policy is in extreme need of reform.

China’s unsustainable management of waste and its underutilized potential of MSW feedstock for energy and fuel production need urgent policy reform for the industry to develop. Like Mr. Zafar says, “Sustainable waste management demands an integration of waste reduction, waste reuse, waste recycling, and energy recovery from waste and landfilling. It is essential that China implements an integrated solid waste management strategy to tackle the growing waste crisis”.

Future Perspectives

China’s government will play a key role in this integrated solid waste management strategy. Besides increased cooperation efforts between the national government and local governments to encourage investments in solid waste management from the private sector and foster domestic recycling practices, first, there is a clear need to establish specialized regulatory agencies (beyond the responsibilities of the State Environmental Protection Administration and the Ministry of Commerce) that can provide clearer operating standards for current WTE facilities (like sanitary landfills and incinerators) as well as improve the supervision of them.

It is essential that China implements an integrated solid waste management strategy to tackle the growing waste crisis

It is essential that China implements an integrated solid waste management strategy to tackle the growing waste crisis

Without clear legal responsibility assigned to specialized agencies, pollutant emissions and regulations related to waste volumes and operating conditions may continue to be disregarded. Similarly, better regulation in MSW management for efficient waste collection and separation is needed to incentivize recycling at the individual level by local residents in every city. Recycling after all is complementary to waste-to-energy, and like Salman Zafar explains, countries with the highest recycling rates also have the best MSW to energy systems (like Germany and Sweden).

Nevertheless, without a market for reused materials, recycling will take longer to become a common practice in China. As Chinese authorities will not be able to stop the waste stream from growing but can reduce the rate of growth, the government’s role in promoting waste management for energy production and recovery is of extreme importance.

Palm Kernel Shells as Biomass Resource

  By | | ,
51 Comments

Biomass residue from palm oil industry are attractive renewable energy fuel in Southeast Asia. The abundance of these biomass resources is increasing with the fast development of palm oil industry in Malaysia, Indonesia and Thailand. In the Palm Oil value chain there is an overall surplus of by-products and the utilisation rate of these by-products is low.

Palm kernel shells (or PKS) are the shell fractions left after the nut has been removed after crushing in the palm oil mill. Palm 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, palm kernel shells are 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 kernel 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.

Most palm oil mills in the region are self-sufficient in terms of energy by making use of kernel shells and mesocarp fibers in cogeneration. The demand for palm kernel shells has increased considerably in Malaysia, Indonesia and Thailand resulting in price close to that of coal. Nowadays, cement industries are using palm kernel shells to replace coal mainly because of CDM benefits.

PKS has also emerged as a hot biomass commodity in the Asia-Pacific region, especially in South Korea and Japan, where PKS is being used to power huge biomass power plants. PKS is also getting traction in Europe as an attractive alternative fuel.

The problems associated with the burning of these solid fuels are the emissions of dark smoke and the carry-over of partially carbonized fibrous particulates due to incomplete combustion of the fuels can be tackled by commercially-proven technologies in the form of high-pressure boilers.

Dual-fired boilers capable of burning either diesel oil or natural gas are the most suitable for burning palm Oil waste since they could also facilitate the use of POME-derived biogas as a supplementary fuel. However, there is a great scope for introduction of high-efficiency CHP systems in the industry which will result in substantial supply of excess power to the public grid.

Energy Potential of Coconut Biomass

  By | | , ,
13 Comments

Coconuts are produced in 92 countries worldwide on about more than 10 million hectares. Indonesia, Philippines and India account for almost 75% of world coconut production with Indonesia being the world’s largest coconut producer. A coconut plantation is analogous to energy crop plantations, however coconut plantations are a source of wide variety of products, in addition to energy. The current world production of coconuts has the potential to produce electricity, heat, fiberboards, organic fertilizer, animal feeds, fuel additives for cleaner emissions, eco-friendly cutlery, health drinks, etc.

coconut-shell-biomass

The coconut fruit yields 40 % coconut husks containing 30 % fiber, with dust making up the rest. The chemical composition of coconut husks consists of cellulose, lignin, pyroligneous acid, gas, charcoal, tar, tannin, and potassium. Coconut dust has high lignin and cellulose content. The materials contained in the casing of coco dusts and coconut fibers are resistant to bacteria and fungi.

Coconut biomass is available in the form of coconut husk and coconut shells. Coconut husk and shells are an attractive biomass fuel and are also a good source of charcoal. The major advantage of using coconut biomass as a fuel is that coconut is a permanent crop and available round the year so there is constant whole year supply. Activated carbon manufactured from coconut shell is considered extremely effective for the removal of impurities in wastewater treatment processes.

Coconut Shell

Coconut shell is an agricultural waste and is available in plentiful quantities throughout tropical countries worldwide. In many countries, coconut shell is subjected to open burning which contributes significantly to CO2 and methane emissions.

Coconut shell is widely used for making charcoal. The traditional pit method of production has a charcoal yield of 25–30% of the dry weight of shells used. The charcoal produced by this method is of variable quality, and often contaminated with extraneous matter and soil. The smoke evolved from pit method is not only a nuisance but also a health hazard.

The coconut shell has a high calorific value of 20.8MJ/kg and can be used to produce steam, energy-rich gases, bio-oil, biochar etc. It is to be noted that coconut shell and coconut husk are solid fuels and have the peculiarities and problems inherent in this kind of fuel.

Coconut shell is more suitable for pyrolysis process as it contain lower ash content, high volatile matter content and available at a cheap cost. The higher fixed carbon content leads to the production to a high-quality solid residue which can be used as activated carbon in wastewater treatment. Coconut shell can be easily collected in places where coconut meat is traditionally used in food processing.

Coconut Husk

Coconut husk has high amount of lignin and cellulose, and that is why it has a high calorific value of 18.62MJ/kg. The chemical composition of coconut husks consists of cellulose, lignin, pyroligneous acid, gas, charcoal, tar, tannin, and potassium.

The predominant use of coconut husks is in direct combustion in order to make charcoal, otherwise husks are simply thrown away. Coconut husk can be transformed into a value-added fuel source which can replace wood and other traditional fuel sources. In terms of the availability and costs of coconut husks, they have good potential for use in power plants.