EFB Pellets: Indonesia and Malaysia's Huge Potential Ready to be Monetized

Empty oil palm fruit bunches (EFB) are the most abundant solid waste from palm oil mills. Efforts to utilize them have also attracted considerable attention. With hundreds of tons of waste produced daily, it certainly presents a challenge, but also an attractive opportunity. Considerations of investment size and potential profits are key. EFB pellet production is an attractive option given the need for biomass fuel for decarbonization, renewable fuels, and carbon-neutral fuels to achieve Indonesia's Net Zero Emissions (NZE) by 2060.

The global population of palm oil plantations, with Indonesia and Malaysia leading the way, makes processing this material highly attractive. Many machinery companies have focused on empty fruit bunch processing, particularly through size reduction and pressing, but few have focused on producing EFB pellets. This is because empty fruit bunches, with their high fiber content, are more difficult to process than wood materials like sawdust or other agricultural waste biomass. 

Selecting the right, reliable, and experienced production machinery supplier is key to success. Performance guarantees, such as agreed quality and quantity targets, as well as timely machine manufacturing, installation, commissioning, and production, are indicators of the supplier's reliability. A track record is also an important consideration. Furthermore, the high potassium content of empty fruit bunches (EFB) poses a challenge in producing boiler-friendly fuel, particularly for pulverized combustion, commonly used in power plants.

And with the increasing number of companies producing EFB pellets, there will be competition for the supply of empty fruit bunches raw materials, such as PLN EPI (Energi Primer Indonesia) which signed a Memorandum of Understanding (MoU) with PT Biomassa Energi Group (BEG) and G7 Group SP.Z.O.O from Poland which was developed jointly will start operating in February 2026, with an initial production target of 120 thousand tons per year, and will be followed by five additional factories with similar or larger capacities, more details read here. 

Processing of Empty Palm Fruit Bunches (EFB) for Ash Production as Potassium Fertilizer and Energy

Palm oil mills produce a large amount of biomass waste, and one of the largest in their daily operations is empty fruit bunches (EFB). Comprising approximately 22% of the fresh fruit bunches (FFB) processed by the mill, the volume becomes enormous and piles up daily if not managed properly. For example, a palm oil mill with a capacity of processing 60 tons of FFB per hour for 20 hours per day produces 264 tons of empty fruit bunch waste per day (approximately 6,600 tons per month and 79,200 tons per year). This enormous amount would resemble a hill if piled up in one place.

Incinerators have recently become popular, particularly in Indonesia, for processing empty fruit bunches due to their speed and practicality. Furthermore, the ash produced by burning them can be used as fertilizer due to their high potassium content. However, these incinerators produce exhaust emissions that pollute the environment, including black smoke and particulate matter. These emissions, which pollute the environment and exceed the threshold permitted by the Ministry of Environment (KLH), have led to the prohibition of incinerators. This ban has led to an increasing number of unmanaged empty fruit bunches. Using empty fruit bunches for mulch is also less effective, and composting, a biological process, takes a long time.

Video link for conventional EFB incinerator here

This problem demands an immediate and effective solution. The quickest practical solution is to upgrade the incinerator to make it environmentally friendly or to reduce emissions below the required threshold. This can be achieved by using adequate emission control devices to meet these environmental requirements. While many emission control devices are available, cost and target output are crucial considerations when selecting them. This approach not only addresses the problem of empty fruit bunches, but the resulting ash can also be used as a potassium fertilizer.

Furthermore, by upgrading the incinerator with emission controls (basic type), the equipment can be developed into several types, as follows: the second type is a cogeneration boiler for palm oil mills, allowing 100% palm kernel shell (PKS) to be sold, even for export. The third type is by adding a new boiler and steam turbine for electricity production, which is then sold to PLN (Indonesia State Owned Electricity Company) under a power purchase agreement (PPA). The fourth type is equipped with waste heat recovery equipment, allowing for more general use. This also means the combustion process in the upgraded incinerator can also be upgraded so that the combustion process can run optimally. Several combustion technologies, such as chain grates, step grates, or reciprocating grates, can be considered to achieve maximum performance, including the removal and handling of ash product.

Empty fruit bunches (EFB) processing can vary, although the primary focus is addressing environmental pollution caused by them. However, their large volumes certainly represent a potential raw material for processing units. Therefore, in addition to addressing this waste, the technology used must also provide financial benefits. Of the numerous EFB processing technology options, the cost-to-benefit ratio of a technology application will be a crucial consideration for EFB processing.

In addition to combustion using conventional or this upgraded incinerator, thermal processing routes also include pyrolysis, with slow pyrolysis specifically for biochar production and fast pyrolysis for bio-oil production. Another pyrolysis variant is mild pyrolysis or torrefaction for the production of torrified biomass. Then there's gasification to maximize gas (syngas) production from biomass. Furthermore, empty fruit bunches of palm oil can be used as fuel or an energy source. To facilitate handling, storage, and reduce transportation costs, empty fruit bunches need to undergo biomass densification technology, with the final product being pellets or briquettes. 

Biochar for Sustainable Palm Oil Productivity

The Indonesian government emphasized the importance of sustainable palm oil productivity for food and energy security, as conveyed by Deputy Minister of Agriculture Sudaryono, at the opening of ICOPE (International Conference on Palm Oil and Environment) in Sanur, Bali, mid-February 2025. The conference, attended by delegates from various countries, namely Indonesia, Malaysia, India, the Netherlands, France, Finland, Colombia, and Spain, aims to formulate a sustainable transformation for the palm oil industry. Sustainable palm oil productivity can be increased by land intensification and the use of superior seeds. Even if land expansion is necessary, it must be done without causing deforestation. Meanwhile, for replanting in dry land, it can also be combined with upland rice or corn through intercropping methods.

Biochar is a powerful solution
Palm oil productivity can be increased by improving fertilizer efficiency, or Nutrient Use Efficiency (NUE), as part of land intensification. Using the same fertilizer dose with the addition of biochar will increase palm oil productivity by around 20% or more. Fertilizer savings of around 30% with the addition of biochar will keep palm oil productivity relatively stable or at the same level as before. For efforts to increase palm oil productivity while avoiding deforestation, the first option is more appropriate: maintaining the same fertilizer dose as usual, but adding biochar to increase fertilizer efficiency.  

Indonesia's current CPO production reaches approximately 50 million tons/year across 16.4 million hectares, with an average CPO production of 3.55 tons/ha per hectare, or 3.55 million tons per million hectares. If biochar is used and productivity increases by 20%, this means an increase of 10 million tons of CPO per year (a total of 60 million tons of CPO per year), saving approximately 2.8 million hectares of land. The use of biochar will also slow down forest clearing (deforestation) for palm oil plantations.

Besides using biochar to increase palm oil productivity, other benefits from biochar production include the potential for carbon credits (BCR = biochar carbon removal) and the utilization of pyrolysis byproducts for palm oil plantations and palm oil mill operations in CPO production. This method offers several advantages for palm oil companies, such as savings in liquid organic fertilizer and pesticides, and the sale or export of 100% of the palm kernel shells (PKS). In addition to palm oil companies producing their own biochar through pyrolysis, it is also possible to establish separate companies or companies that collaborate with palm oil companies for biochar production under specific agreements.

Global pressure and scrutiny on the palm oil industry to adopt sustainable practices are increasing. Amidst soaring demand for palm oil in both global and domestic markets, increasing palm oil productivity is inevitable. Utilizing biomass waste from palm oil mills and plantations, such as empty fruit bunches (EFB) and trunks (OPT), for biochar production, and using biochar to increase palm oil productivity, is a powerful solution to address these challenges. Even for replanting dryland with upland rice or corn using intercropping methods, the use of biochar will also have a positive and significant impact on these intercrops. 

Optimization of Palm Oil Mill Operations to Maximize Profits by Utilizing EFB Waste

As a profit-oriented company, palm oil companies will also do various things necessary to maximize their profits, both in the operations of their palm oil mills and on their plantations. The more efficient the operations of the palm oil mill, as well as on its plantations, the higher the profits obtained. Minimizing the environmental impact of waste produced, even zero waste, and becoming part of responsible and sustainable environmental management practices, including part of climate solutions, are important parts of this industry that cannot be abandoned. That is why palm oil mills must innovate to achieve optimal conditions. To achieve these conditions, it can be done by evaluating current practices and finding better solutions.

CPO (crude palm oil production) requires steam for the sterilization process. This is why palm oil mills definitely need boilers for their production process, for more details read here. Steam from the boiler is also used for power generation with steam turbines to drive generators. The operation of the boiler is generally carried out by burning fiber (mesocarp fiber) and some palm kernel shells / PKS, so that some palm kernel shells /PKS can still be sold or even exported. This common practice in palm oil mills has also been running for decades, but it turns out that there is still a lot of biomass waste from palm oil mills that has not been utilized, especially empty fruit bunches or EFB (empty fruit bunches) which account for around 23% of the fresh fruit bunches (FFB) processed. These EFBs are usually only piled up behind the palm oil mill and tend to pollute the environment.

The EFB can be processed into biochar. Biochar production with thermal processes, either pyrolysis or gasification, will produce energy as cogeneration in palm oil mills. Cogeneration is the right solution for biochar production while supplying energy needs for boiler operations. In this way, 100% of palm kernel shells / PKS can be sold or even exported, meaning that palm oil companies' profits are greater. But to maximize biochar production, pyrolysis is the right choice. This is because gasification technology is to maximize gas products while pyrolysis is to maximize solid products (biochar). By-products from pyrolysis are also beneficial for the palm oil industry.

Empty fruit bunches (EFB) are solid waste from palm oil or CPO production which is the largest in number. This is what makes many machine manufacturers make these EFB processing machines. Most of the machines made are equipments for cutting and pressing the EFB so that the water content decreases and the material size becomes smaller. However, both the water content and the size of the EFB as the output of the machine or equipment still do not meet the requirements to be further processed into biochar. The typical output is more than 4 inches and the water content is more than 45%. EFB must have a low water content of 10% and can be less than 1 inch for biochar production or as fuel in the boiler.

  

To obtain the EFB with a dryness level or water content of 10%, waste heat recovery from palm oil mills can be utilized for the drying process. Other biomass waste from the palm oil industry can be utilized as fuel or a source of heat energy for drying the EFB. By utilizing these biomass wastes, mill operations can be more efficient so that profits are maximized and environmentally friendly with zero waste. 

Empty Fruit Bunch of Palm Oil Processing: for Pellets, Briquettes or Biochar ?

Empty fruit bunches (EFB) are solid waste from palm oil mills or CPO production which is the largest in number. This is what makes many machine manufacturers make these EFB processing machines. Most of the machines made are equipments for cutting and pressing the EFB so that the water content decreases and the size becomes smaller. However, both the water content and the size of the EFB as the output of the machine or equipment still do not meet the requirements to be further processed into pellets, briquettes or even biochar. The typical output is more than 4 inches and the water content is more than 45%. EFB must have a low water content of 10% and a size of 5-6 mm to be able to make pellets or briquettes, and less than 1 inch for biochar production.

To obtain suitable raw materials for pellet, briquette and biochar production, the EFB that has been cut and pressed still needs to be reduced in size (size reduction) and its water content reduced to about 1/3 so that it is dry enough. Equipments such as a hammer mill or crusher is needed to reduce the size and a drying tool such as a rotary dryer is needed to reduce the water content. The smaller the size of the material (particle size) and the lower the water content or the drier it is, the more energy is needed. Equipment such as hammer mills and rotary dryers have not become an integral part of EFB processing at this time. However, usually EFB palm oil processing producers also produce press equipments for kernels for the production of kernel oil or PKO in kernel processing plants or KCP (kernel crushing plants) with by-products in the form of palm kernel meal or PKE (palm kernel expeller). 

Considerations for selecting pellet, briquette or biochar production from EFB palm oil depend heavily on the readiness of the business. It is estimated that there are 30 million tons per year of dry EFB palm oil in Indonesia and 10 million tons per year of dry EFB palm oil in Malaysia for raw materials for these products. The use of EFB palm oil waste, in addition to being a solution to waste problems in palm oil mills, will also provide additional benefits for the palm oil mill or company. How much profit is usually also proportional to the investment and production capacity made. With the abundance of potential raw materials and the driving force of sustainability and zero waste, EFB palm oil waste will become an attractive new business. 

Optimizing Pyrolysis and Biochar in the Palm Oil Industry

Indonesia's CPO production currently reaches around 50 million tons per year with a land area of ​​around 17.3 million hectares. This means that the average CPO production per hectare is only 2.9 tons or per million hectares produces 2.9 million tons. If biochar is used and there is a 20% increase, it means there is an increase of 10 million tons of CPO per year and this is equivalent to saving around 3.5 million hectares of land, or the use of biochar will slow down forest clearing (deforestation) for palm oil plantations.

The average speed of Indonesian palm oil plantation area is 6.5% per year or equivalent to about 1 million hectares per year for the last 5 years, while the increase in palm oil fruit production or FFB (fresh fruit bunches) is only 11% on average. Even the largest expansion of palm oil land occurred in 2017, which increased by 2.8 million hectares. By opening 1 million hectares of forest, national CPO production only increased by 11%, while without the need to open forests, namely with the application of biochar, there could be a 20% increase in productivity. And the 20% increase in FFB yield (fresh fruit bunches) using biochar is a low estimate.

With the number of palm oil mills in Indonesia reaching more than 1000 units and tens of millions of tons of biomass waste, especially empty palm fruit bunches (EFB), the volume of biochar production produced is certainly very large. In addition, pyrolysis technology can replace combustion technology which is generally used in palm oil mills to produce steam for electricity production and sterilization of fresh fruit bunches (FFB) in CPO production. With pyrolysis raw materials using palm oil tankos and being able to replace palm kernel shells, 100% of palm kernel shells (PKS) can be sold or exported. The sale of palm kernel shells or PKS (palm kernel shells) will certainly provide additional attractive benefits for the palm oil company. Palm kernel shells or PKS are the main competitors of wood pellets in the global biomass market.

In addition, the use of biochar also saves fertilizer use and the highest operational cost on oil palm plantations is fertilizer so this is very relevant. Tens of billions of costs spent on fertilizer can be reduced by using biochar, especially since the biochar comes from its own waste so that it will automatically become a solution for biomass waste management. Including biopesticides and liquid organic fertilizers can also be produced from the pyrolysis process. Carbon credit is the next business potential. This is because the application of biochar to the soil for agriculture or plantations is an effort for carbon sequestration / carbon sink.

The benefits that can be obtained from this biochar carbon credit are also large, even globally biochar carbon credit ranks first or more than 90% in Carbon Dioxide Removal (CDR) recorded in cdr.fyi. However, there are indeed many large biochar producers who do not sell their carbon credits because of the methodological requirements of standard carbon companies such as Puro Earth and Verra, and these biochar producers are comfortable with their biochar sales business, especially since these producers have existed (established) since before carbon credits were available for biochar. 

The Urgency of IOT and Biochar Applications in Palm Oil Plantations

The sustainability trend in palm oil plantations is increasingly important and urgent, which is of course part of the global solution to environmental and climate problems. The vastness of palm oil plantations and the large production of palm oil are in the spotlight in the industry. Waste management and environmental pollution are important concerns. The large volume of biomass waste has the potential to be a source of environmental pollution and so is the excessive use of chemical fertilizers in palm oil plantations which will also cause environmental pollution. Inappropriate land use, for example deforestation and land conversion, are also other concerns.

Two important issues in the palm oil industry are increasing FFB productivity (yield improvement) and climate change resilience. And thank God, both of these things can be handled at once, namely by applying biochar. Palm oil mill biomass waste (especially palm oil empty fruit bunch) will be converted into biochar and then applied to plantation soil (sustainable soil amendment) with fertilizer so that it becomes a slow release fertilizer that will increase NUE (nutrient use efficiency) and minimize environmental pollution. With the increase in NUE, there will be yield improvement or an increase in FFB productivity. And the application of biochar which will remain in the soil or not decompose for thousands of years will become carbon sequestration / carbon sink which is in line with climate change resilience. A precise solution with one action, of course this should be very interesting and awaited by these palm oil companies.

To ensure that the biochar can work properly, an instrument is needed to measure performance and monitor it. That is why IoT (Internet of things) in this sector is needed. How slow can it goes fertilizer nutrients can be measured and monitored accurately, quickly and precisely. In this way, palm oil productivity can also be predicted. The area of ​​land on palm oil plantations that reaches thousands or tens of thousands of hectares is also not an obstacle. The area of ​​palm oil plantations in Indonesia is currently estimated to reach 17 million hectares and in Malaysia it reaches 5 million hectares, of course these palm oil companies are also trying to achieve their best level of sustainability according to the demands of the times. This is so that the application of biochar on palm oil plantations will become a trend and even its operational standards. The entry point by ensuring biochar performance with IoT is an important consideration.

This biochar application also follows the 4Rs rule, namely the right source (appropriate biochar raw material), right place (appropriate application area), right rate (appropriate dosage) and right timing. The physical and chemical properties of biochar differ depending on the raw material and production process. By following the 4R rule, biochar performance can be maximized. On the other hand, modernization in the palm oil industry also continues to be improved. The public perception of work in oil palm plantations, abbreviated as 3D (dangerous, difficult, dirty), will be gradually changed with mechanization, automation and digitalization. The ratio of workers to plantation land currently around 1: 8 ha will be increased to more than double to 1: 17.5 ha with the above modernization so that workers' wages can also be increased. This modernization is expected to help overcome the two important issues above with the biochar application.   

Utility Business for Palm Oil Mills

When the priority is to obtain the maximum profit, good environmental management and ease, efficiency and stability of production as an option, then utility matters at the palm oil mill may be collaborated with other parties. This specialization becomes important because of the priority choices above. The utility problems in question are electricity and steam. Electricity is produced from a steam turbine and steam is produced from a boiler. High pressure steam enters the steam turbine to drive a generator and produce electricity and low pressure steam output from the steam turbine is used for the fresh fruth bunch (FFB) sterilization process. Water treatment for boiler feed is also part of the utility problem, as well as for boiler operations to produce output in the form of electricity and steam.

Regarding cooperation or business models, palm oil mills can pay for the electricity and steam they receive. But because the fuel or energy to produce electricity and steam comes from palm oil mills, of course the price is cheaper. If currently almost all palm oil mills use their boiler fuel from mesocarp fiber and palm kernel shell (PKS), then with this specialization it is possible for palm fiber (mesocarp fiber) and empty palm fruit bunches (EFB) to be used as fuel or energy sources while palm kernel shells (PKS) can 100% sold and even exported. Palm kernel shells (PKS) as biomass fuel can be sold directly and are in great demand, and are also the main competitor for wood pellets in the global biomass fuel market.

Under these conditions, there are efforts to increase the efficiency of utility production such as steam and electricity as optimally as possible, not only combustion technology with static grates, moving grates, reciprocating grates to fluidized beds, but it is even possible to use pyrolysis. EFB or empty palm fruit bunches, which were previously unprocessed and were an environmental problem, can become a potential energy source so that 100% of the palm kernel shells / PKS from palm oil mills can be commercialized/sold. And even if the utility provider uses pyrolysis, biochar will also be obtained. Biochar provides many benefits related to soil fertility and climate.

Size Reduction: Shredder or Chipper ?

There are many biomass processings that require size reduction. With this size reduction, the biomass raw material has a smaller and more uniform size and shape, making the follow-up process easier. After reducing the size, the surface area or contact area becomes larger so that the drying process will be more efficient, especially in continuous drying. The small and uniform size also makes handling easier. Size reduction is usually used in the initial / pretreatment process before the main / core process of processing a biomass.

Biomass, especially from plants, also has various shapes and sizes. This greatly influences the size reduction equipment used. Fibrous biomass such as coconut fiber or empty oil palm fruit bunches will be more effectively and efficiently reduced in size with a shredder rather than a chipper. This is because the fiber dominant and tenacious structure is easier to tear or shred and crush than to cut into pieces like using a knife.

Meanwhile, woody biomass has hard, brittle characteristics and an elongated shape, so the use of a chipper is more effective and efficient compared to a shredder. The character of the wood is easier to cut with equipment such as a knife for size reduction. The output or product from the shredder and chipper is also different in terms of size and shape. The wood produced from the chipper machine is usually called wood chips and looks like chopped wood, while the output from the shredder is in the form of shreds.

Biomass processing products into energy, namely by compaction (densification) into pellets or briquettes, as well as thermochemical routes such as pyrolysis, gasification and combustion are widely used today. If the size and shape of the biomass from the size reduction equipment is suitable, it can be used immediately. However, if the shape and size are not suitable then it is necessary to continue with the next size reduction stage, namely using a hammer mill so that a biomass product is obtained that can be the size of sawdust. In the production of pellets and briquettes, the biomass particle size needs to be made as small as the sawdust, so that compaction (densification) is optimal. Meanwhile, in the thermochemical process, the size of the biomass becomes small particles such as sawdust, usually for equipment that carries out fluidization, for example fluidized bed combustion.

EFB Pellets with Low Potassium (K) and Chlorine (Cl) for Power Plants

Palm oil mills that have excess energy, especially electrical energy, will have more freedom to develop their business. The excess electrical energy could have come from the production of electricity from the use of biogas. Liquid waste (pome) from palm oil mills is the raw material for biogas production. A palm oil mill with a production capacity of 30 tons of FFB/hour will be able to generate 1 MW of electricity and so on. One of the products that can be processed from the utilization of palm oil solid waste as well as the development of this business by utilizing excess energy is EFB pellets production. With the high price of palm kernel shells or PKS and wood pellets, the driving force or need for EFB pellets is increasing. Global awareness regarding decarbonization or CO2 removal (CDR) or CO2 reduction is the main driving force.

Apart from that, the production of EFB pellets can also be carried out by a separate company by purchasing the raw materials for EFB from palm oil mills. With conditions in Indonesia where there are still very few palm oil mills that have biogas units so that they have electricity supply and can process EFB into EFB pellets, there is still a lot of EFB that has not been utilized and becomes waste that pollutes the environment. This makes EFB pellet producing companies not have to worry about the supply of EFB raw materials. In fact, because the amount or volume of EFB is very large, the EFB pellet plant will be overwhelmed by the abundance of this raw material.

However, due to the high content of EFB in potassium and chlorine (ash chemistry), the use of EFB pellets is limited or can only be used in certain types of power plants, especially stokers and fluidized beds. In fact, most power plants currently use pulverized combustion technology. This is so that the chemical content of ash in EFB must be made as friendly as possible to boilers, especially those with pulverized combustion technology. This can be done so that the chemical content of the ash in the form of potassium (K) and chlorine (Cl) is only less than 2000 ppm. Potassium (K) with a low melting point causes deposits or scale to form in the heat exchanger pipes in the boiler so that the efficiency of heat exchange decreases while chlorine (Cl) is corrosive which shortens the life of the equipment. The treatment was even successful in reducing K and Cl by up to 80% so that the problem of fouling thickness and corrosivity was also reduced by 80%. With the number of palm oil mills in Indonesia reaching around 1000 units, of course the amount of EFB that can be processed into EFB pellets is also very large.