The Urgency of Biochar Application on Palm Oil Plantations in Indonesia

The large number of acidic soils in Indonesia that are used for palm oil plantations makes the productivity of palm oil fruit or the resulting FFB (fresh fruit bunch) not optimal. The acid soil covers the largest dryland area in Indonesia. It occupies approximately 55% of the total land area (191.09 million ha) in Indonesia. About 107.36 million ha of all Indonesian acid soils is classified as dryland acid soils and the rest (14.93 million ha) as peat soil. Acid soils in Indonesia are distributed amongst the big islands, such as Kalimantan (39.42%), Sumatera (28.81%), Papua (18.03%), Java (7.77%), and Sulawesi (6.95%). Acidic soils with low pH make nutrient absorption low in plants and so do soil microbial activity, which plays a large role in soil fertility. This condition should not be ignored because besides making the cultivation of palm oil plantations not optimal, there will also be a lot of fertilizer used. This makes the operational costs of  palm oil plantation operation high. Biochar is a biomass pyrolysis product that is effective and efficient in overcoming these problems. With the abundant amount of biomass waste produced by palm oil mills or CPO mills as biochar raw materials, efforts to improve the quality of plantation soil should be easy to do and have even become the operational standard for these plantations. But the fact is not.

 

Why hasn't biochar been used to improve soil quality and thus increase the production of palm oil fruit or FFB? The lack of information and education about the benefits and uses of biochar are the main factor. This of course makes the application of biochar in palm oil plantations not yet done even though palm oil mills have abundant biomass waste such as empty palm fruit bunches (EFB) and fiber which are generally not used and cause environmental problems. The priority for processing EFB compared to other products such as EFB pellets or compost also needs separate considerations. The best choice, of course, is based on a comprehensive study according to the characteristics of the business or business will be built. Consider not only short-term economic benefits, but also environmental and long-term benefits is an important thing. 

 

Quantitatively, an increase in the production of palm oil fruit or FFB, an increase of at least 20% with the application of biochar is something that is normal. And a 20% increase in fruit production will also result in a big profit. Productivity of a number of other agricultural commodities can be increased by 30%, 40% or even more than 100%. The low productivity of palm oil fruit in Indonesia can be increased by the application of biochar, which is particularly effective in improving the soil quality in the palm oil plantations. Moreover, about 80% of the components of the cost of producing crude palm oil (CPO) come from the plantations, and 20% in the processing sector (palm oil mills). The operational costs of palm oil mill plantations, especially fertilizers, can also be reduced by the use of biochar. The priority of liquid biofuel development will also get better if the volume of biofuel raw materials such as CPO increases. This shows the strategic role of biochar. Apart from that from the aspect of climate change, biochar will also absorb CO2 concentrations in the atmosphere or reduce the concentration of greenhouse gases, as a solution to today's world problems.  

 

Meanwhile, from the side of the palm oil mill, another advantage obtained from biochar production is the use of excess energy from the pyrolysis process or the production of biochar as an energy source for the boiler. Boiler feed water (BFW) will also be preheated twice when it is used for cooling in the pyrolysis condenser and then the economizer on the boiler. In this way, the energy needed by the boiler decreases. When the boiler energy source uses the energy source from pyrolysis, this means that the palm kernel shell (PKS) can be taken and used for other things and can even be sold directly for local and export markets. The main obstacle to business development in the palm oil industry is the availability of energy source namely electricity. If the energy source is available, the development of palm oil-based businesses is very open and varied, such as the production of CPO derivatives, palm kernel shell processing, PKO production, PKO derivative production, biomass power plants and so on.  

Benefits of Palm Oil Company When Produce Biochar

There are at least four things that become motivation for biochar production, namely as in the chart above. There are a number of slices that make the impact of biochar application multi-benefits, which is very much in line with today's world problems, namely climate change and global warming. Biochar has also been accepted as an instrument to reduce the concentration of CO2 in the atmosphere which causes the two big problems above, namely in 2018 biochar was included in the Intergovermental Panel on Climate Change (IPCC) as one of the negative emissions technologies (NETs). Biochar application is a carbon negative scenario because biochar can absorb CO2 from the atmosphere. This is slightly different from the use of biomass fuels such as wood pellets, wood briquette and palm kernel shell (PKS) in industrial boilers or power plants, which are carbon neutral scenarios. Indeed, basically there are 3 big scenarios to reduce the concentration of CO2 in the atmosphere, namely increasing the efficiency of equipment that uses fossil fuels, using carbon neutral fuels and carbon negative scenarios such as biochar.

Palm oil trees are known to require a lot of water and fertilizer to maintain the life sustainability and productivity of their fruit, so practical efforts in the form of increasing fertilizer nutrient efficiency and increasing fruit productivity are important. Besides that, palm oil mills produce a lot of biomass waste, especially empty fruit bunches (EFB ) and mesocarp fiber, which are very potential for biochar raw materials. The biochar is then applied in palm oil plantations which can be used with chemical fertilizers or with compost / organic fertilizers.

Pyrolysis and gasification technologies are commonly used for the production of the biochar. Apart from producing biochar by pyrolysis or gasification, energy is also produced which can be used for the business development of the palm oil industry or for electricity production. Production of PKO (Palm kernel oil) from kernel processing at KCP (kernel crushing plant) or production of torrefied PKS from PKS processing with torrefaction can be done by utilizing excess energy from the production of biochar. Most of the palm oil mills or CPO mills do not have kernel processing or KCP to produce PKO. And by making torrefied PKS, the caloric value of PKS will increase, it is easy to downsizing (increased grindability), for example in the use of cofiring and does not absorb water (hydrophobic property). In general, palm oil mills will have many advantages, both economically / financially and environmentally, with this biochar production.

Apart from being used for business development like the diagram above, excess energy from pyrolysis or gasification can also be used as boiler fuel in the palm oil mill. In this way the energy to heat the boiler, which is usually with palm kernel shell and mesocarp fiber, can be replaced by energy from pyrolysis or gasification. After that, all of the palm kernel shells / PKS can be sold or exported, thus providing additional profits for the palm oil company. The need for biomass fuel, especially palm kernel shell / PKS, is predicted to increase, both in the domestic market and in the export market. Japan is currently the largest consumer or user of palm kernel shells and it is predicted that the demand will also increase. Japan will also impose stricter standards on imports of palm kernel shells to ensure environmental sustainability by applying the GGL (Green Gold Label) certification which will be effective starting April 2023. This is like the wood pellets with FSC certification. If anyone is interested in an economic analysis of the use of biochar in palm oil business, please contact us.  

Fertilizer Savings in Palm Oil Plantations with Biochar and Compost from Biogas Waste

Although Indonesia is the largest CPO producer in the world with an area of ​​approximately 13 million hectares of palm oil plantations, but it is estimated that less than 10% have a biogas facility from POME (Palm oil mill effluent). Whereas by utilizing POME for biogas production, besides being able to be converted into electricity or heat, it also produces organic fertilizer in the form of compost and liquid organic fertilizer. The compost can be used as fertilizer in oil palm plantations, where the cost of fertilizer for palm oil operations is the highest cost component. It is estimated that every 10,000 hectares costs approximately Rp. 35.75 billion (around US$ 2.25 million) for fertilizer and for more details, you can read here. The use of compost will certainly reduce the need for fertilizer.

Palm oil utilization scheme for optimizing CPO production

Besides that, solid wastes such as palm oil empty fruit bunch, fiber and palm oil frond are also very potential for the production of energy (electricity and heat) and biochar. Energy production in the form of electricity and heat is by burning pyrolysis byproducts in the form of syngas and biooil into the furnace to heat the boiler. And because the syngas and liquid fuels used in the furnace, so that the combustion process is more perfect and clean emissions. Steam generated from the boiler will then drive the steam turbine and generator so as to produce electricity. Low pressure steam from steam turbine is then used for sterilization or boiling the fresh fruit bunches (FFB). While biochar will be used together with compost and chemical fertilizers to make fertilizer effective in the palm oil plantations so that it becomes a slow release fertilizer. Costs for fertilization are also expected to be significantly reduced, for example by up to 50% by this way. Although biochar is not a fertilizer, it has a function that makes fertilizer use effectively because it holds fertilizer nutrients from leaching, for example from rain water, also maintains moisture and so on.

PKS loading for export in Indonesia

PKS (palm kernel shell) can even be sold or exported. This is because previously or in general the palm kernel shells used to fuel boilers with fiber, have been substituted with products from the pyrolysis process namely syngas and biooil. The need for palm kernel shells for both the domestic / local and export markets continues to increase all the time. Palm kernel shells / PKS are environmentally friendly fuels because they come from biomass so they are carbon neutral fuels. The use of PKS as a fuel is widely used by a number of industries starting as a heat source for the drying process such as spray dryers in detergent and ceramic plants, boilers in food industries such as soy sauce factory, to power plants such as in Japan, can be read in more detail here. In the world of biomass fuel commodity trading, especially in the international market, PKS is the main competitor of wood pellets. Although the specifications are not much different, the price of PKS is also cheaper because it comes from palm oil mill waste and does not need complex processing units such as wood pellets. And basically with the scheme of utilizing palm oil mill wastes as above, it will maximize the profit from the palm oil mill or CPO mill.

Advantages of Municipal Waste Processing by Pyrolysis Compared to Fluidized Bed Combustion, Incenerator, Hydrothermal Carbonization (HTC) and Gasification

Municipal waste is always a problem everywhere, especially in big cities. With proper processing, the municipal waste should be an attractive opportunity that has great potential. Municipal waste that amounts to thousands of tons per day needs fast handling so that it does not cause problems, moreover the waste management should require cheap investment and even benefit the waste management party. The question is what is the waste processed into, in what ways and where can it be used? Let's compare waste processing with a thermal route with various existing technologies, namely fluidized bed combustion, incenerator, hydrothermal carbonization (HTC) and gasification. Why are only thermal routes compared? This is because if the biological route takes a long processing time and requires a large place. In short, the biological route is not effective in overcoming the problem of municipal waste.

Basically all the thermal technologies mentioned above can be used to process municipal waste, only how effective and how economically profitable it is the topic of discussion. It really depends on the condition of each region, for example a number of major cities in Indonesia have oversupply electricity production, so that if added to electricity production it will meaningless and not absorbed. Another factor is the investment needed for waste processing equipment, which is generally still very expensive. Based on this, a solution is needed that can be suitable for a particular region. In fluidized bed combustion technology, incenerator and gasification in general is to produce electricity, even though electricity has also been oversupplied so it is not an option.

With HTC technology will produce the main product in the form of carbon material or charcoal, but HTC equipment investment is still expensive. Well, of all the thermal route technologies, continuous pyrolysis is the best choice because it produces the main product in the form of charcoal. Charcoal with the main content of carbon can be used for fuel, especially boilers in the industry. Boilers that have been using coal even from other fossil energy such as gas and petroleum can switch to using charcoal produced from municipal waste. The use of charcoal from municipal waste will certainly reduce the use of coal in particular and fossil energy in general. And the most important thing is of course to overcome the environmental problems caused by the garbage. The continuous pyrolysis units are also not centralized in one place, but can be spread more to various locations on a medium scale, for example each location to process municipal waste with a capacity of 200 tons / day. If let's say Jakarta produces 5000 tons / day of municipal solid waste every day, 25 continuous pyrolysis units are needed. To save transportation and facilitate storage and use, the charcoal product can be made of charcoal pellets or charcoal briquettes.

With the use of continuous pyrolysis, InsyaAllah the problem of municipal waste in big cities can be overcome while providing economic benefits (read: profits) for the manager companies. While the garbage problem continues to haunt and has never been resolved to this day, so an effective and solution-oriented innovation is needed to overcome it. Jakarta is the largest city in Indonesia surrounded by many industrial estates and boilers are one of the important equipment widely used by these industries. If Jakarta's waste is processed into charcoal, it can replace the fuel for the boilers. Steam power plants can also use charcoal for their fuel, for example with cofiring.