Biochar Based Slow Release Fertilizer And Soil Quality Improvement In Indonesian Palm Oil Plantation

Photo taken from here

Expansion (extensification) of palm oil plantation in Indonesia increasingly encouraged to pursue non-oil commodities. The allocation or designation of land for oil palm plantations should be done with careful consideration and comprehensive, so it does not upset the balance of the environment. This factor which highlighted a lot of environmentalists, and the user market oil products from Indonesia. Another factor that I think needs to be considered is the productivity of the oil palm plantation itself. With good farming techniques or start intensification then I am sure Indonesia will increase the productivity of palm oil.

Compared to Malaysia with palm plantation productivity 3.5 tons of CPO per ha, while Indonesia only 2.5 tons of CPO ha per year. Due to differences in the productivity of Malaysia's vast palm plantation only 61.5% of the area of ​​Indonesia but is capable of producing up to 17 million tons of CPO or 85.3% of Indonesia's CPO production. In this case, Indonesia needs to learn from Malaysia. Currently, the land has been planted with oil palm in Indonesia has 7.8 million ha, about 16.5% of the farms and plantations or 8.3% of the total forest area. There are still 7 million ha of arable land palm, a great opportunity to increase the production of CPO and its derivatives. Trade policy of developed countries that want to kill off Indonesia palm oil industry as edible oil industry afraid to compete with palm oil needs attention is important for the government for the betterment of the palm oil industry in Indonesia. All of the government, NGOs and industry have one vote for this.

Increased productivity is one of them with a good fertilization and using quality fertilizer. If you see activity on the production of CPO will be a lot of waste biomass produced can be used to meet energy needs and CPO mill byproduct of biochar. As a porous material that has the ability as adsorbent, biochar able to hold nutrients and water for longer, so that it can act as a slow release fertilizer. When all the oil mill biomass waste can be converted into energy and fertilizer byproducts biocharnya to the oil mill has reduced global warming (carbon neutral fuel with biomass and carbon negative with biochar application) and absolutely zero waste. This obviously also be a solution to the negative campaigning of oil palm plantations in Indonesia. Reliable continuous pyrolysis technology appropriate to the scale of the pool is a necessity. JF BioCarbon will able to answer it.

Judging from the condition of the global climate, carbon balance balance between the expansion of palm oil plantations, the carbon released when the process of biochar production by pyrolysis and carbon sequestration from the atmosphere by biochar. Optimization of the three will give the best results for the environment, human welfare and ecosystem.

7 Reasons Why Future of World Economy Depends on Renewable Energy

There are various reasons as to why the global economic future depends on alternative renewable energy sources. Here are seven of these reasons.

1. Reducing the effects of global warming. Alternative renewable energy sources will provide a solution to the ecological crisis that is caused in part by global warming. If the switch to alternative renewable energy sources is not made soon, this may have a very serious impact on the world economy and the world’s communities.
2. Fossil fuels are running out. Oil and natural gas are not infinite and will run out eventually. Even before they run out, they will become increasingly expensive because of scarcity. The resulting energy crisis will have a devastating impact on the global economy.
3. Reducing pollution. Alternative renewable energy sources are a wonderful way for reducing the global levels of pollution. For example, waste to energy is a great method of turning discarded trash into desperately needed energy to power and heat our homes.
   
   
4. Supporting developing countries. The need for energy goes up every year, especially as more developing countries advance. When they have access to domestically produced energy, it will make their development process easier, as local economies benefit from the abundance of businesses and jobs. The countries of the future will be the countires that are embracing green energy sources right now. Look at China – they got into the act this last few years as they understand that there future depends on it. More and more countries are taking action. Anything to do with the green economy is going to be huge in the next few decades.

5. Moving away from foreign oil dependency. It is possible to produce alternative renewable energy sources domestically in every country. This means that no nation will depend on another to provide it with the means to produce energy, as well as a cleaner domestic environment overall.
6.  Investing in alternative energy. It is a smart choice to invest in alternative energy. This means that it is not only a great opportunity to help our planet, but also one to receive a good financial return in the end. 
7. Creating green jobs. Many new jobs would be created once the switch to alternative renewable energy sources is made. Factory jobs would be needed, since the manufacturing of energy source components is needed. Technicians would be needed to install, service, and repair those energy source components, like wind turbines, solar panels, or municipal waste pyrolyzer.

While for the specific reasons on the biomass for energy with thermal energy conversion route, please click here.

For the original article, click here

For more information, go to:
en.wikipedia.org/wiki/Renewable_energy

Go Green With Sustainable Energy For All

UN Secretary-General BanKi-moon has called on governments, the private sector and society to commit to his Sustainable Energy for All Initiative at the World Future Energy Summit (WFES) in Abu Dhabi, UAE.

In his keynote at WFES, Ban Ki-moon said he has designated sustainable development as his top priority for his next five-year term, and he has set out three objectives to be achieved by 2030:

1. Universal access to modern energy services;
2. Double the rate of improvement of energy efficiency; and
3. Double the share of renewable energy in the global energy mix.

Work on an Action Agenda has already started.Energy transforms lives, businesses and economies. And it transforms our planet — its climate, natural resources and ecosystems. There can be no development without energy.

Biomass is the fourth largest energy source in the world. In contrast to water, wind and solar thermal, biomass is the only energy source that does not depend on the weather in order to ensure stable energy production. Most of the biomass has been used optimally in developed countries, but otherwise there are still many untapped in developing countries. Yet millions of tons of biomass produced annually as a result of agricultural and agro-industrial residue.

Pyrolysis is a technology to process biomass into high-grade fuel. Application of pyrolysis products that biochar can also improve soil fertility. Problem is the lack of electricity supply is a common problem especially in developing countries. According to Ban Ki-moon one in five residents of this planet do not have access to electricity services. Syngas produced from continuous pyrolysis can be used to power plants in remote areas that are rich in potential biomass. 

Three Motivations For Biomass Thermal Conversion

At least, three motivating factors on biomass thermal conversion, like is mentioned below :

A.    Renewability Benefit
Fossil fuel like coal, oil and gas are good and convenient source of energy, and they meet the energy demands of society very effectively. However, there is one major problem: Fossil fuel resources are finite and not renewable.Biomass on the other hand, grows and is renewable. A crop cut this year will grow again next year; a tree cut today may grow up within a decade. Unlike fossil fuel, then, biomass is not likely to be depleted with consumption. For this reason, its use, especially for energy production, is rising fast.

We may argue against cutting trees for energy because they serve as a CO2 sink. This is true, but a tree stops absorbing CO2 after it dies. On the other hand, if left alone in the forest it can release CO2 in a forest fire or release more harmful CH4 when it decomposes in water. The use of a tree as fuel after its life provides carbon-neutral energy as well as avoids greenhouse gas release from deadwood. The best option is new planting following cutting, as is done by some pulp industries. Fast-growing plants like switch grass and Miscanthus are being considered as fuel for new energy projects. These plants have very short growing periods that can be counted in months.

B.    Enviromental Benefit
With growing evidence of global warming, the need to reduce human-made greenhouse gas emissions is being recognized. Emission of other air pollutants, such as NO2, SO2, and Hg, is no longer acceptable, as it was in the  past. In elementary schools and in corporate boardrooms, the environment is a major issue, and it has been major driver for biomass thermal conversion such as pyrolysis for energy production. Biomass has a special appeal in this regard, as it makes no net contribution to carbondioxide emission to the atmosphere.

Regulations for making biomass economically viable are in the place in many countries. For example, if biomass replace fossil fuel in a plant, that plant earns credit for CO2 reduction equivalent to what the fossil fuel was emitting. This credits can be sold on the market for additional revenue in countries where such trades are in practice.

Carbon Dioxide Emissions
When burned, biomass release the CO2 it absorbed from the atmosphere in the recent past, not millions of years ago, as with fossil fuel. The net addition of CO2 to the atmosphere through biomass combustion is thus considered to be zero.

Sulfur Removal
Most virgin or fresh biomass contains little to no sulfur. Biomass-derived feedstock such as municipal solid waste (MSW) or sewage sludge does contain sulfur, which requires limestone for capture of it. Interestingly, such derived feedstock also contains small amounts of calcium, which intrinsically aids sulfur capture.

Nitrogen Removal
A combustion system firing fossil fuel can oxidize the nitrogen in fuel and in air into NO, the acid rain precursor, or into N2O, a greenhouse gas. Both are difficult to remove. In a pyrolysis system, nitrogen appears as either N2 or NH3, which is removed relatively easily in the syngas-cleaning stage.
Nitrous oxide emission results from the oxidation of fuel nitrogen alone. Measurement in a biomass combustion system showed a very low level of N2O emission (Van Loo and Koppejan, 2008, p.295)

Dust and Other Hazardous Gases
 Highly toxic pollutants like dioxin and furan, which can be released in a combustion system, are not likely to form in an oxygen-absenced pyrolyzer. Particulate in the syngas is also reduced significantly by multiple gas clean up systems.

C.    Sociopolitical Benefit

The sociopolitical benefits of biomass are substantial. For one, biomass is locally grown resource. For one, biomass is a locally grown resource. For a biomass-based power plant to be economically viable, the biomass needs to come from within a certain distance from it.  This means that every biomass plant can prompt the development of associated industries for biomass growing, collecting, and transporting.
Some believe that a biomass fuel plant could create up to 20 times more employment than that created by a coal-or oil-based plant (Van Loo and Koppejan, 2008, p.1).  The biomass industry thus has a positive impact on the local economy.

Another very important aspect of biomass-based energy, fuel, or chemicals is that they reduce reliance on imported fossil fuels. The volatile global political landscape has shown that supply and price can change dramatically within a short time, with a sharp rise in the price of feedstock. Locally grown biomass is relatively free from such uncertainties.

Effective Torrefaction Technology from JF BioCarbon

Basically there are two torrefaction technology in use today, namely the direct heating and indirect heating. Direct heating is torrefaction technology with direct heating by using the unit operation (process equipment), among others, with non-oxygen gas loop with exchanger using a moving bed, drum, vibrating belt, multiple heart furnace or using a low-oxygen gas loop linked to the burner using a tunnel or moving bed.  While the indirect heating included using advanced drying technology and retort heating as did JF BioCarbon.  A number of technology providers are competing to design an effective and efficient process so that meet benefit greatly. The use of indirect heating such as JF BioCarbon uses a vacuum process and operating conditions are easier to control.

Huge market potential, because the excellence of the biomass torrefaction products (torrified wood pellet and briquette), also made ​​a number of technology providers to increase their production capacity. Currently the average manufacturer produces less than 5 tons / hour torrefied wood products. Production capacity to 5 tons / hour is one of the parameters of success of this technology. Torrefied wood products is predicted to replace the wood pellets, because of its superiority, among others, as follows:

-Hydrophobic characteristically, good to be stored for a long time without experiencing degradation of its physical properties
-Moisture content below 3%
-Easy to be crushed or pulverized to coal plant process
-The properties of torrified wood are very homogeneous
-Burned without causing smoke and smell because of all volatile material had been removed during manufacture.
-Ideal for gasification and Fisher-Tropsch process for conversion to chemicals.

-Can be made ​​from many biomass, while wood pellet can be made only from narrow feedstocks.

In addition to wood pellet market is already global oversupply, also encourages the use of better fuel economy in both the torrefied wood briquettes or pellets.

Among a number of technology providers, JF BioCarbon using the process easier, simpler and faster. If the average of the production process torrefied pellets through 10 stages as follows:

a. Pre-Torrefaction

1.Prepare feedstock particle size 

2. Pre-dry feedstock

b. Torrefaction

3. Evaporate Residual Moisture

4. Heat Feedstock to 250-280 C

5. De-polimerize hemicellulose

c. Post-Torrefaction

6. Cool & re-polymerize product

7. Crush to Size

8. Condition

9. Densify (pelletizing)

10. Cool & Screen

 (Adapted from Wood Pellet Association of Canada)

 

So JF BioCarbon production process is shorter, ie :

1-      Prepare feedstock size

2 &3 Pre-dry feedstock & evaporate moisture.. This is all done in one process.

4 & 5- are one combined process

6-       Torrefied is cooled while being moved from reactor to char bin via a cold water cooled jacketed auger system (40 ft. long)

7.  Fine particles ready for pelletizing if necessary.

8.  Pelletizing

9. Cool and Screen

For more details please click here.

'Renewable Energy' new part of our life

Not only are fossil fuels the problem, but according to the IEA's World Energy Outlook 2008, we are likely to see an increase in world primary energy demand of 45 percent between 2006 and 2030. As set out in the Energy Equality chapter, developing countries and emerging economies are in the great need of energy. Both need to fuel their growth, and the latter are beginning to converge with formerly dominant world powers, who are now seeing their economies contract.

The only logical and safe option is to channel all possible resources into a new world energy system, based on renewable energies which can provide millions of jobs, new industries and exports, energy security, and protection of the climate and environment. Any policymaker still voting for fossil fuels, and against renewable energy, on the basis of such pros and cons must be asked to give way to someone wiser and more caring. New nuclear programme is not the answer because problem on technology detail. The more one researches the subject, the firmer these conclusion become:renewable energy is the only reasonable and logical choice, with huge variety of benefits; and the switch must be prioritized immediately.

But this is a highly complex matter-renewable energy and its applications are varied, and provide a unique energy endowment for each country. There is no one-size-fits-all approach on technology and policy which can be advocated/ Ultimately, it will be up to each nation to determine how best to harness and protect investment in its renewable resources, and to decide how to share them.By offering a preferential tariff for producers of renewable energy, as well as investment security, they have led to the most rapid deployment at the lowest costs of any policy.

Investment in renewable energy has been surging, and 2008 was another good year with $120 billion invested worldwide. Approximate figures suggest wind (42 percent), solar PV (32 percent) dan biofuels (13 percent) attracted most of these funds, with biomass and geothermal power and heat, solar hot water and small hydro taking up around 6, 6 and 5 percent respectively. Manufacturing capacity has also benefited strongly from capital investment. The US ($24 billion), Germany, China and Spain ($15-19 billion range) and Brazil ($5 billion) were the biggest investors. Energy security and meeting carbon reduction targets, it will be very interesting to see how deployment develops over the next few years. And around US$500 million in development assistance grants is targeted at developing countries annually for renewable energy projects and for training and market support.

This funds policy analysis work, economic assessment, market and business development, project feasibility studies, financing mechanisms, technology improvements and capacity building, and sometimes covers partial incremental costs of renewable energy projects.

Several foundations and NGOs such as the UN Foundation and the Energy Foundation provide funds and manage programmes promoting renewable energy. Bilateral development banks and agencies also contribute, such as the European Union and the European Investment Bank, and national development institutions such as the Australian Agency for International Development (AusAID) and the Deutsche Gesellschaft fur Technische Zusammerarbeit GmbH, better known as GTZ.

As an example of where some of these agencies put their money, the UK’s Department for International Development (DFID) is one of the many funders of Renewable Energy and Energy Efficiency Partnership (REEEP) a global initiative concerned with reducing policy, regulatory and financial barriers to renewable energy and energy efficiency technologies and projects. The partnership has funded more than eighty ‘high quality’ projects in forty developing countries. These projects are beginning to deliver new business models, policy recommendations, risk mitigation instruments and regulatory measures. REEEP also engages in international, national and regional policy dialogues.

Several United Nations organizations actively promote renewable energy. The United Nations Development Programme (UNDP) has an ‘Energy and Environment Practice” which promote acess to sustainable energy services as an essential development strategy. UNER’s (United Nations Environment Programme) renewable energy activities focus on the needs of developing and transition economies in various areas of renewable energy technology research, development and commercialization.

UNEP’s Sustainable Energy Finance Initiative (SEFI) is a platform providing financiers with the tools, support and global network needed to conceive and manage investments in the “complex and rapidly changing marketplace” for clean energy technologies. UNIDO (the United Nations Industrial Development Organization) focuses on rural energy for productive use. Other UN bodies work to spread renewable energy technology information, and to engage stakeholders in accelerating RE development.

The GEF was established in 1991 under the United Nations Framework Convention on Climate Change (UNFCCC), as a mechanism to help developing countries fund projects and programmes that protect the global environment while still supporting national sustainable development initiatives. Nearly a billion dollars has gone to around 150 renewable energy projects in developing countries.

Indonesia and Malaysia is the biggest CPO (crude palm oil) producers in the world. Indonesia has reported with an annual production approximately 22 million tones, a plantation area of approximately 7 million hectares and more than 400 palm oil mills (POM). An additional 18 million hectares has been identified for palm plantation expansion. The solid waste components from POM production are empty fruit bunch (EFB), fiber and shell. These have been identified as the potential raw materials for pyrolysis technology to yield charcoal / biochar or torrified wood, bio-oil and syngas.

JFE have mission to make industry of POMs solid waste processing to produce renewable energy and agricultural products in Indonesia and South-East Asia, by making joint venture company with investor and/or biomass owner. The wide of market access, proven technology (JF BioCarbon System Ltd, Canada as technological support), abundant raw material, good operating business system and research capability for development is the key success of this business.

For further contact please send email eko.sb.setyawan@gmail.com or call Eko +6281328841805, John Flottvik 250-315-2226