Rabu, 08 Desember 2021

The Urgency of Ex-Coal Mine Reclamation With Biochar

The large number of ex-coal mines that are not reclaimed causes various environmental problems and even life safety. There have been many casualties from the former coal mine pit. The simple logic should be that after the coal deposit is taken or extracted during the mining activity, the land is returned and repaired so that the quality is better than before the mining activity or at least the same, but not worse so that various environmental problems arise. The era of decarbonization is accelerating because of the driving force of climate change and global warming. Fossil fuels, especially coal, are starting to be abandoned, of course, including the coal mining activity itself. Meanwhile, the area of former coal mines which reaches millions of hectares is a lot of environmental problems today.

When the quality of the soil is improved so that it has high fertility then this becomes a very extraordinary potential so that a number of important activities can be carried out, such as agriculture, animal husbandry and forestry. With such conditions, the effort to self-sufficiency or food sovereignty is not impossible. Technically, it can be analyzed which of the agricultural, livestock and forestry sectors can reach the goal faster, namely food independence or sovereignty. But before going far and doing business on the ex-mining land, to be more specific what products will be made, the basic question is how to improve the condition of the damaged soil and the scale is also massive?

The application of biochar to the soil is a surefire solution in an effort to repair damaged soils. Depending on how severe the damage is, the characteristics of the soil type and the final quality level being targeted will determine the application or dosage of the biochar. In addition to improving the soil, the biochar application also absorbs CO2 from the atmosphere, thereby reducing the concentration of CO2 from the atmosphere or is a carbon negative scenario. Biochar buried in the soil becomes a carbon sink, similar to creating a conservation forest to absorb CO2 from the atmosphere. How much biochar is buried so that it can be calculated that the CO2 absorbed into the carbon sink can be sold on the carbon market and get carbon credit. Biochar itself is able to last in the soil for hundreds of years and is not decomposed for a long time. Even when the land has been repaired with biochar and then a conservation forest is made on it, the carbon credit obtained are double, namely from the application of biochar itself and from the conservation forest. But once again, of course, economic factors are another important consideration, so as above, after soil fertility is improved with biochar, there are a number of options for using the land. Of course which one provides the best economic benefits will be the choice.

Millions of hectares of land can be recovered so that its benefits will be maximized. Say, for example, that one million hectares of land can be recovered and then used for activities that support food security or self-sufficiency such as agriculture and animal husbandry, then how much output can be calculated. Even better if there can be a surplus of food production so that it can export. Or even in the longer term, the land is reforested into conservation forest, so how much CO2 can be absorbed by the forest plus the application of biochar. Of course very much. Then why have to build a food estate but have to clear forest land, while there are other better ways? Namely not only restoring but improving the condition of the land even better before the coal mining activity was carried out.  

Selasa, 07 Desember 2021

Biochar and Land Reclamation of Ex-Coal Mines

Reclamation of ex-coal mining land is the obligation of the mining company, but often this is not done properly for various reasons. These are mainly due to weak rule enforcement and light sanctions. With the area of ex-coal mines that has reached millions of hectares and the reclamation efforts are needed, but the realization in the field is still very minimal, making environmental damage even greater. The thing that can encourage efforts to improve the ex-coal mining land is the profit or economic factor that can be obtained. This means that if the reclamation effort also bring economic benefits - in addition to environmental benefits, of course - then the coal companies will also be happy to do so. So what activity is it?

The photo is taken from here
After the coal deposit is taken, the top soil should be returned to the land. The basic thing that needs to be done is to improve the quality of the soil so that it can be used for planting various crops. By improving soil quality, besides soil fertility can be restored and even increased, it also includes isolating (immobilizing) a number of harmful elements from the ex-coal mining land. Creating a profitable and sustainable business activity is the next step. The improved soil can then be planted and legumes are the best choice, this is because legumes are other than pioneer plant types with high survivability, strong and deep roots that prevent erosion, root nodules from azetobacter symbiosis by binding nitrogen from the atmosphere which fertilizes the soil also provides many other benefits. Ruminant husbandry is a profitable and sustainable business activity, because it mainly utilizes the leaves of the legume plant as a source of feed. The livestock manure can also be used to further improve the health and quality of the soil so that soil fertility continues to increase and is maintained. The wood from the legume plantation can also be used for productions namely briquettes, charcoal briquettes and even wood pellets.

As a basic thing and the entry point for the above business is improving the quality of the land or soil of the ex-coal mines. There are a number of ways to do this, but the use of biochar is one of the best options. With biochar not only increases the pH or acidity of the soil so that many nutrients will be absorbed by plants better and soil microbial activity to decompose organic matter is more active, but it is also able to absorb a number of harmful chemical elements in the soil, increasing soil organic carbon that can last hundreds of years and also absorbs the greenhouse gase from atmosphere. The biochar can be made from a number of agricultural, forestry and agro-industrial wastes, such as wood chips from logging or from palm oil mill waste such as empty fruit bunches and fiber. A number of areas in Kalimantan are not only rich in coal deposits and also currently many of these ex-coal mining lands are abandoned, as well as a lot of biomass materials such as forest waste and palm oil mill waste for the production of biochar.

In order to reduce CO2 emissions in the atmosphere, biochar is also able to absorb CO2 from the atmosphere (carbon sequestration) and is a carbon negative scenario. The biochar applied to the soil is a carbon sink, as an option for carbon credit other than carbon offset. In the current era of decarbonization, efforts to reduce CO2 level in the atmosphere are important. In Indonesia, where there is still a lot of forest land, carbon credit can be obtained from the absorption of CO2 by the trees in the forest, so that the forest acts as a carbon sink as well. But in other countries where the use of fossil energy is very large or massive, they must reduce the adverse climate impacts caused by burning fossil energy materials, especially coal. They can buy carbon credits on this biochar application.

 
Coal is the most widely used fossil energy for power generation in the world today and Indonesia is one of the producers of such coal. Although in the near future the use of coal will be reduced and in some countries it will be stopped altogether, but the negative impacts of coal mining are still many, damaging and even endangering the environment. This is an urgency to improve the land or ex-coal mining land which is estimated to reach 8 million hectares in Indonesia. On the one hand, coal power plants can buy carbon credits for biochar applications like the scheme above. Palm oil mills on the other hand also produce a lot of solid waste, especially empty fruit bunches (EFB) that can be used for the production of biochar. These big companies could collaborate to solve climate problems due to the increasing concentration of CO2 in the atmosphere. To this day, it is reported from the Mauna loa observatory, in Hawaii, United States that the concentration of CO2 in the atmosphere has exceeded 400 ppm or there is still an increase of about 2 ppm every year, even though the global target is to decrease the concentration to only 350 ppm.    

Biochar and IoT in Palm Oil Plantations

Monitoring until action needs to be done to get optimal results according to the expected target. Ensuring that the supply of nutrients and water is always sufficient for the needs of plants is an important thing to do. Other variables that affect the process of nutrient absorption and plant growth need to be properly monitored. Biochar is a soil amendment to improve soil properties such as soil structure, soil aeration, water and nutrient availability, suppress the development of certain plant diseases, create good habitats for symbiotic microorganisms and reduce soil acidity. Biochar also  adsorbs greenhouse gases in the form of carbon dioxide from the atmosphere, thereby reducing these gases in the atmosphere. It is important that sensors are used to read the variables above. How many sensors are installed and what type is also very dependent on the objectives being achieved. The use of various sensors in large numbers is also a cost in itself, while a production is always looking for the most efficient way to maximize profit. The use of sensors that are effective and efficient is the key to successfully monitoring the conditions of biochar applications in the field with a specified period of time, even real time all the time.

IoT (Internet of Things) is predicted to become a trend in the near future and it cannot be avoided. A number of plantation areas that are located far away in remote villages, such as in palm oil plantations, are generally still constrained by the internet network, this condition makes IoT unable to be applied or still not optimal. Palm oil plantations are one of the ideal locations for biochar applications for large capacities as well as IoT, for more details read here. While waiting for an internet network in the area provided by a telecommunications company, satellite signals can be used even with small data usage so that the information displayed is also less and simpler. This makes only really important information that needs to be monitored, especially on plantation locations that are difficult to reach. At such a stage manual monitoring is still much needed, so the online information from the satellite only helps for verification. Devices such as drones can also be used to monitor growth or general the plantation conditions.

Basically, IoT and its supporting devices such as artificial intelligence and big data are tools to help make decisions, especially for the plantation manager such as palm oil plantations. Knowing the condition of the plantation so that it can maintain the level of plantation productivity performance is an important part of maintaining the company's performance itself. Even though IoT devices help in such a way, the important thing that is still needed is basic knowledge to the characteristics of plantation management itself. These sciences will be very useful for analyzing the data presented by IoT devices more sharply and accurately or on target. Selection of sensors, the number of sensors to the location of the sensor installation must be carried out effectively and this can only be done with an adequate scientific basis. A number of chemical analyzes in general also cannot be done sensory but using reagents and so on. In addition, IoT is also a new thing so that a number of certain activities or practices in certain agriculture or plantations and more specifically in the biochar application have not been identified for IoT developers. This is so that collaboration between researchers, practitioners and IoT developers is needed so that IoT device products will also be more effective and efficient. 

Sabtu, 04 Desember 2021

Integration of Pyrolysis with Cocopeat and Cocofiber Industries

The high demand for cocofiber and cocopeat in the world which reaches thousands of containers per year should be a golden opportunity and a driving force for the Indonesian coconut industry. There are a number of potential advantages of Indonesia which should be at the forefront of capturing and exploiting these opportunities. These advantages include, from 196 countries in the world, only 8 countries control 90% of the world's coconut demand, Indonesia as the owner of the largest coconut plantation in the world, which is around 3.8 million hectares with a production of more than 15 billion coconuts fruit every year, and strategic geographical position. This is also the reason why the ICC (International Coconut Community) or an international organization concerned that the members of which are coconut producing countries is headquartered in Jakarta, Indonesia. The island of Sumatra is the center of the largest coconut plantation in Indonesia, especially Indragiri Hilir regency in Riau province, followed by the islands of Sulawesi, Java, Maluku and Papua, Nusa Tenggara and Bali, and Kalimantan. The current condition, although with a number of advantages above and the quality of Indonesian coconut coir is high and the price of this coir is cheap, it turns out that Indonesia still supplies less than 5% of the world's cocofiber and cocopeat needs.

To seize these opportunities, of course, one cannot only rely on the potentials, but also on effective and efficient production technology. One of the main obstacles in increasing cocofiber and cocopeat production capacity is the drying aspect. The production of cocofiber and cocopeat can be boosted in such a way if the efficient drying aspect can be carried out. And for drying, heat energy is absolutely necessary. This heat energy can be obtained cheaply from the excess energy of the pyrolysis process. In addition to producing the main product in the form of biochar, excess energy from the pyrolysis process can be relied on as an energy source or heat source for the coconut coir processing industry. A certain type of dryer according to the characteristics of the material being dried must also be used. With modern dryers such as belt dryers, tray dryers and drum dryers, in addition to the high drying capacity, the product quality will also be standard and stable.

Meanwhile, for the pyrolysis process, raw materials are needed in the form of biomass wastes that are widely available in that location, even the biomass waste can vary according to its availability which sometimes depends on the season. In certain cases, it is also possible for pyrolysis to be integrated with an integrated coconut industry, so that coconut shell becomes the raw material. Meanwhile, if the location of the coconut plantation is not far from the palm oil plantation, biomass wastes from the plantation or palm oil mill can be used for the pyrolysis. Even like the palm oil trunk, if it is not used and only left to rot in the plantation, it invites insects that disturb the coconut plantation. For more details, you can read it here. The integration of the pyrolysis industry and coconut coir processing in addition to reducing environmental pollution due to biomass waste is also a solution for the coconut coir industry. The relationship between the two industries must be mutually beneficial, namely the pyrolysis industry can sell its excess energy at a competitive price and the coconut coir industry can increase its production.

Senin, 29 November 2021

Biochar for Coconut Plantation

The productivity of Indonesian coconuts is decreasing so that even though it has the largest coconut plantation area in the world. This of course makes the land less productive and the production from coconut plantations is also low. As a comparison, the productivity of Indian coconut reaches 300 grains per tree or 7.5 times that of Indonesia, which averages only 40 grains per tree per year. In addition, the number of coconut plantations that must be replanted is very large and is not proportional to the speed of replanting. Due to the lack of maintenance, there were also many areas of damaged coconut plantations, which in total reached hundreds of thousands hectares.

Indonesia has experienced the critical condition of coconut and now many coconut producing countries in the Asia Pacific region are experiencing a similar condition. Most of the coconut trees that exist are trees planted in the decade after the first world war or in the 1930s, even though the age of the coconut is around 80 years. This means that the tree is more than 80 years old or has passed its productive period. FAO has even given this warning since 2013. As a consequence, industries are experiencing a severe shortage of raw material supplies amid the increasing demand for coconut-based products, as experienced by the Sambu Group. Sambu group is the largest coconut industry in Indonesia which is located in Riau which has had to buy the coconut raw materials from West Kalimantan province in the last two years. Though Riau province itself is the largest coconut producer in Indonesia, especially Indragiri Hilir regency.

Overcoming the crisis, of course, takes time and is neither fast nor easy. A number of structured, systematic and massive efforts need to be done consistently to get optimal results and according to goals. As a product which is mainly for food and added all its parts that can be utilized, overcoming the crisis of coconut plantations or the upstream sector of the coconut industry is important. In addition, the expansion of the coconut plantation area also needs to be increased to around 6 million hectares so that the supply for industry is sufficient, in comparison Indonesia's palm oil plantations have reached around 14 million hectares. Of course that is the next step after replanting and repairing damaged coconut plantations can be overcomed. 

 To increase coconut productivity, apart from the use of superior seeds, there are also adequate agricultural cultivation techniques. It is very important to improve soil quality so that plants can optimize nutrient uptake. No matter how good the seeds are, if the soil quality is low and farming techniques or cultivation techniques are perfunctory, the results will also not be optimal. For example, on acid soils that make nutrient absorption low and also the soil microbial activity, whatever the plant will not grow optimally. Biochar as a soil amendment is effective and efficient to improve the quality of the coconut plantation soil. Although coconut is a plant that is resistant to salinity, a decrease in salinity will also have a good impact on the coconut tree, and this can also be done with the application of biochar.

Like palm oil, coconut industrialization should also be possible. With this industrialization, the production process becomes efficient and all the coconut fruit harvested from the plantation can be processed all. Population growth that continues to increase and it is estimated that the world's population will reach around 10 billion by 2050 certainly requires sufficient food and various other supporting things such as edible oil and other coconut-derived products. Pyrolysis technology is very good for use in the coconut processing industry. This is in addition to biochar as the main product of pyrolysis with its main use in coconut plantations, excess energy pyrolysis can be used for various needs of the coconut processing industry, both in the form of heat and electricity. Coconut processing products are much more numerous and varied than palm oil. An industry will also need a continuous supply of raw materials with a certain amount and this means that the performance level of its coconut plantations must be maintained in such a way as to meet the needs of the industry and biochar application is the right solution. 

Kamis, 25 November 2021

Biochar as a Solution to Deforestation in Indonesian Palm Oil Plantations

Palm oil trees are not native to Indonesia but come from West Africa and were brought by the Dutch colonialists in the mid 19th century. At first they brought 4 grains and planted them in the Bogor Botanical Garden which is now a palm oil monument. The first palm oil plantation were established in Indonesia in the early 1900's in North Sumatra. The development of the palm oil industry and its subsequent plantations is very rapid, especially in the last 10 years and it is currently estimated that the area of Indonesian palm oil plantations reaches 15 million hectares. As the largest vegetable oil-producing plant in the world and the area of palm oil plantations is also the largest in the world, of course, palm oil has a strategic value in the Indonesian economy. The average rate of growth for Indonesian palm oil plantations is 6.5% per year or the equivalent of about 500 thousands up to 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% in average. In fact, the largest increase occurred in 2017 which increased by 2.8 million hectares. From 2015 to 2019, the total area of palm oil increased by 3.7 million hectares. Extensification or expansion of palm oil plantations turned out to be many "accused" and became the world's spotlight as from the conversion of forest land functions, so that there was a lot of deforestation to be converted into palm oil plantations.

Pressure from the European Union in particular, due to these conditions worsened the image of Indonesian palm oil which in turn affected the selling price of palm oil, both CPO (crude palm oil) and its derivative products. Improving the image is also not easy. One of the effective measures is to stop the extensification effort so that forest land remains as forest land and does not turn into palm oil plantations. Biochar can be an effective solution to this problem. By increasing the productivity of fresh fruit bunches (FFB) from the usage of biochar, new palm oil plantations do not need to be opened again. Assuming an average productivity increase of 20% occurs, CPO production will also increase by 20% or equivalent to 2 million tons. The increase would be equivalent to new land clearing of more than 2 million hectares. Certainly not a small land area. With the 20% increase in production, it is very likely that the national needs for CPO needs have been met and the same goes for the export market.

With the extensification of palm oil land of more than 1 million per hectare every year but the increase in palm oil fruit (FFB/fresh fruit bunch) production is only 11%, it is certainly less attractive and must be avoided, especially when the world's attention on deforestation is getting stronger. This also indicates the low productivity of the palm oil plantations. In fact, by improving soil quality, the productivity of palm oil fruit can be significantly increased and the clearing of new land for palm oil plantations can be avoided. Biomass wastes in palm oil plantations and in palm oil mills can be used for the production of biochar.

In palm oil mills, this biomass waste is easier to process in large quantities, especially empty fruit bunches (EFB). An average palm oil mill can produce 200 tons of waste per day of EFB. Meanwhile, in palm oil plantations, biomass waste, such as palm fronds, leaves and stems, is the raw material for the production of biochar. Palm oil trunks even have a lot of negative impacts when they are not treated adequately or are only left to rot in the plantation, giving rise to horn beetle pests, for more details read here. Optimizing the utilization of biomass waste has multiple benefits, not only preventing environmental pollution by the waste, and can be described as the scheme below.

In terms of technology, biochar production technology is also very varied, from simple technology (low tech, low cost) that is cheap to advanced high technology that is efficient, precise process control but at a higher price. In the palm oil mill, it will be effective to use high technology so that it can be integrated with the operations of the palm oil mill. The excess energy from the pyrolysis process will also replace boiler fuel which has been using fiber and palm kernel shells (PKS). There are indeed many advantages of palm oil mills when doing the production of biochar, for more details, please read here. Production of biochar with empty fruit bunches or EFB biochar is also more profitable than EFB pellets, a more detailed explanation can be read here. Meanwhile, for people who have palm oil plantations as part of society palm oil producers (Plasma) or independent plantations, they can use simple technology (low tech, low cost) for the production of biochar. Biochar production in a simple way can also take advantage of excess energy for various small business activities such as those carried out in Tanzania, Africa. In this way, the community in addition to producing biochar also gets a source of energy including reducing the use of firewood which can be obtained from cutting down trees in protected forests or reducing deforestation pressures.

Fertilizer is the highest cost component in the palm oil plantation operations. Besides being able to increase the productivity of palm oil fruit or FFB, Biochar can also reduce the need for the use of fertilizers. An increase in soil pH makes nutrients easily absorbed by palm oil trees and also increases soil microbial activity which increases fertility is one of the benefits of using biochar. And when the performance of the productivity level of palm oil plantations has been able to be achieved and maintained, a number of other improvements can also be made. From the industry point of view, raw materials are a vital factor in terms of availability, continuity of supply and quality, including palm oil mills. Moreover, the plantation aspect of CPO production holds a portion of 80% while the factory or the mill aspect is only 20%. This confirms that the plantation aspect plays a vital role in the supply of these raw materials, so that efforts to maximize productivity, including maintaining productivity level performance, are very important and a top priority. Meanwhile, the change in palm oil plantations from monoculture to polyculture (mixed plantation) is one of the further improvement that can be made. Extensive monoculture plantations have the potential to be susceptible to disease, so they need to be avoided. Technically, how much monoculture area is still effective, especially for palm oil plantations, there are no convincing findings. 

Rabu, 24 November 2021

Utilization of Excess Energy from Biochar Production with Pyrolysis

Most of the production equipments for biochar are currently obsolete, so that the productivity and quality of the products produced are low, also causing environmental problems, namely air pollution. In equipment with this technology, the production process is also not running efficiently, indicated by the large amount of energy or heat loss so that it is less profitable. Slow pyrolysis technology is the best technology for biochar production because it maximizes the production of a solid fraction (biochar). Meanwhile, other thermal technology group are not so suitable for biochar production, for example fast pyrolysis, the main objective of which is to maximize its liquid product or biooil, gasification is the main objective of maximizing gas or syngas product as well as hydrothermal carbonization (HTC) or wet pyrolysis requiring high pressure operating conditions so that it is difficult to be applied. Modern slow pyrolysis technology will operate autothermal / self sustain fuel, safe, good process control and energy management, so that in this way in addition to energy being used for the pyrolysis process itself, excess energy can also be used for other needs such as electricity or heat production.

 There are three main variables for this pyrolysis process, namely heating rate, duration / residence time and temperature. The quality and quantity of biochar are determined by these process variables. For example, biochar production with a temperature of less than 400 C will produce acidic biochar, while biochar production above this temperature will produce alkaline biochar. Currently, the pH of biochar produced ranges from 4 to 12. There are also those who make a category about the pyrolysis temperature for biochar production, namely, low with less than 250 C, medium (250 - 500 C), high with more than 500 C. According to some researches fixed carbon also increased from 56% to 93% at 300 and 800 C pyrolysis temperatures. The surface area also increased from 120 m2 / gram at 400 C to 460 m2 / gram at 900 C. 

And indeed, basically the quality and quantity of biochar is determined by the raw materials used and the conditions of the production process, especially the pyrolysis. In fact, to ensure the quality of biochar, all aspects need to be considered such as raw materials and production processes such as the pyrolysis operating temperature should not be more than 20%, interruptions when production are allowed as long as the conditions of subsequent production parameters are maintained the same as before the restart. The composition of the raw material should not fluctuate more than 15%. And for modern pyrolysis equipment, the excess energy must be utilized with an estimated 35-60% of the energy from the biomass raw material found in pyrolysis gas. A number of agricultural waste processings can use the pyrolysis optimally, including:

 1. Palm Oil Industry

The use of pyrolysis technology for palm oil companies, especially in Indonesia, is currently ideal. This is because palm oil mills or CPO mills produce a lot of solid waste biomass namely, empty fruit bunches/EFB, fiber and palm kernel shell. And because palm kernel shell / PKS has a lot of demand both from within and outside the country for industrial fuel and power plants, this PKS should not be used as raw material for pyrolysis or biochar production, but can be directly used as a trading commodity.  The EFB and fiber are used as raw material for biochar and then the biochar is used to improve the soil quality of palm oil plantation so that fresh fruit bunch or FFB productivity increases. Excess energy from pyrolysis is then used as boiler fuel so that it can reduce or even replace all PKS as the the boiler fuel. And because the boiler fuel is replaced with the excess energy pyrolysis, so can be  all of the PKS can be sold. 

2. Integrated Coconut Industry

Products from coconut processing such as copra, dessicated coconut, and nata de coco require heat in the production process. Coconut shell charcoal is also a favorite charcoal with a large market demand. The charcoal will usually be further processed into briquettes for energy and activated carbon for various industries. For biochar production, coconut industrial wastes such as coir/fiber, bunch and midrib can be used. Excess energy of pyrolysis can be used for the production of the above products and other advanced products. The low productivity of Indonesian coconut production needs to be improved, one of which is by improving soil quality with biochar. In addition, there are so many coconut plantations in Indonesia that need to be replanted so that improving soil quality to achieve the desired production is increasingly important. 

3. Corn Plantation

Efforts to increase food products need to be taken seriously, this can be done in two ways, first by expanding the land or making new rice paddy fields for production and the second by improving the quality of existing land so that productivity will increase. Biochar is very effective and efficient for the second method above. Besides being used as a human food source, corn is also used for animal feed. With the projection of the human population continuing to increase, the need for food either directly by consuming corn or indirectly from livestock such as meat and eggs. Poultry or chicken feed production ranks first of other animal feed production, or in the world almost half of the animal feed produced is chicken feed. Corn cobs and husks are agricultural waste that can be used for biochar production. Excess energy from the pyrolysis process can be used for drying corn and other advanced processes.

4. Rice Paddy Farming 

Rice or paddy is the staple food of most of the Indonesian population. The area of irrigated rice fields is decreasing throughout the year. This encourages the use of non-irrigated rice fields or dry land for the production of this rice. Biochar is able to improve the quality of dry land soils, such as in corn farming. Rice husks are rice paddy agricultural waste that can be used for biochar production. Excess energy from rice husk pyrolysis can be used for drying the rice paddy itself so that it becomes dry grain ready to be milled, or for other purposes. With the improvement of soil quality, rice productivity can be increased and it is not impossible that food self-sufficiency, especially rice, can be achieved, as has been achieved by Indonesia some time ago.

Biochar For Date Palm Plantations

Biochar is increasingly being used as a soil amendment with the aim of improving the physical, chemical and biological properties of the soil, and reducing the concentration of greenhouse gases from the atmosphere. In date palm plantations which are mostly planted in dry and sandy areas, the use of biochar will especially increase the ability of water and nutrients holding capacity, meaning that the evaporation of groundwater can also be reduced and nutrient loss for date palms can also be reduced. This of course is very beneficial for the date palm tree. Waste from date palm plantations such as midribs, seeds and leaves can be used as raw material for the biochar. The impact or positive results of the use of biochar have been reported from enormous of studies and experiments. These results are improvements in the physical, chemical and biological properties of the soil which ultimately result in the quality and productivity of the fruit yield.

 Every year, it is estimated that each date palm tree produces 33 kg of green waste or 20 kg of dry biomass waste. Currently, it is estimated that date palms around the world reach 120 million trees with a biomass waste potential of 4 billion tonnes of green waste or 2.4 billion dry and can be converted into biochar into 800 million tonnes of biochar. The 10 largest date producing countries are Egypt, Iran, Saudi Arabia, Algeria, Iraq, Pakistan, Sudan, South Sudan, Oman and the United Arab Emirates. The use of modern pyrolysis equipment for processing biomass waste into biochar, also produces excess energy for heat or electricity production which can be used for various purposes. Location of date palm plantations in rural areas can use electricity or store this energy for other purposes such as cooking. The energy storage can be done with large or small tanks for the needs of residents in that location. By utilizing the excess energy from the pyrolysis process, environmental damage such as illegal logging can be minimized. Dry and arid are areas with high evaporation and low rainfall, and such areas as these occupy 41% of the land surface area on earth. Currently nearly 900 million people inhabit this area.

Improved soil quality will result in higher crop productivity. The better the quality of the soil that can be cultivated, the better the productivity will be. Biochar will enrich soil organic carbon which has important roles, including reducing plant nutrient loss, increasing soil aggregation, reducing soil erosion, and increasing water holding capacity. Each plant has its own characteristics regarding the growing medium and environmental condition. Improving the quality of the soil will certainly increase the productivity of dates and even increase the quality of the fruit.   

Minggu, 21 November 2021

Increasing Energy Efficiency in Palm Oil Mill Operations Using Pyrolysis

Energy utilization in the form of steam production which is then used for electricity production through steam turbines and generators, as well as the use of steam for steamming (sterilizing) fresh fruit bunches (FFB) are the main things in palm oil mill operations. This is because the need for electrical energy to power various mechanical equipment in the mill comes entirely from this electricity production. Electricity and steam for industrial processing are grouped under the utilities that support that industry. Meanwhile, in the sterilization process or the boiling of FFB, steam besides stopping the development of FFA (free fatty acid) and facilitating the threshing will also facilitate the CPO extraction process and processing the kernel (palm kernel). To produce steam and electricity, of course, energy is needed, namely heat. Steam is produced by the boiler in the form of superheated steam to drive steam turbines and generators to produce electricity and then steam from electricity production or low pressure steam is used for steamming (sterilization) of FFB.

The water after being treated so that it becomes BFW (boiler feed water) is then used for the production of steam and electricity. Heat energy to produce steam can be reduced in such a way with the use of a pyrolysis process (which means that it is not ordinary combustion), so that the heat requirement for the boiler furnace is getting smaller. The pyrolysis condenser will produce hot water so that it becomes preheating for the boiler. In pyrolysis a condenser is used to separate bioil and syngas (uncondensable gas). Preheating from the condensation process of the pyrolysis unit will then go to stage 2 preheating in the economizer of the boiler unit. Thus the temperature of the water entering the upper drum on the boiler is high enough, and the heat requirement to become superheated steam will be reduced. The palm oil mill uses a water tube type boiler as is commonly used in large industries and not a fire tube which is in the form of a shell and tube type heat exchanger with the tube submerged in water so that it does not overheat. In a water tube type boiler, it consists of an upper and lower drum (mud drum) which is connected to a pipe. The lower drum and water tube are fully filled with water, while the upper drum is only partially filled. With this arrangement, steam will pass through the mechanical separator on the upper drum, flow to the superheater and exit the boiler. Efficiency is the key word in production, including the use of energy in the production process of CPO or palm oil mills. The rule of thumb is an increase of 10 C in BFW is equivalent to increasing 1% boiler efficiency.

Excess energy from the pyrolysis process should be used for fuel or energy sources in the boiler furnace. The use of excess energy from pyrolysis will also produce environmentally friendly flue gas emissions because the combustion of liquid and gaseous fuels will be cleaner than solid fuels. In this way, the palm kernel shell, which has been used for boiler fuel, can no longer be used. All these palm kernel shells or PKS can be sold directly and even exported to Japan and Korea. Of course, be a separate source of additional income. Palm kernel shells or PKS are competitors for wood pellets in the global market because they have many similar properties, but because palm kernel shells come from waste or palm oil mill sideproducts, the price can be cheaper, more information can be read here. The use of slow pyrolysis for biochar production is the best option compared to similar technologies such as fast pyrolysis and gasification, more details can be read here. Palm oil mills or companies will get a lot of benefits from biochar production, for more details can be read here. 

Production of EFB Pellet EFB or EFB Biochar ?

One of the main obstacles for palm oil mills to develop their business is the availability of electricity. With locations that are generally located in remote areas in the middle of palm oil plantations, palm oil mills do not get electricity supply from PLN (Indonesia State Owned Electricity Company). Eventhough electricity is very important in a production process, such as in the production of EFB pellets. Even though empty bunches or EFB in general are an environmental problem for palm oil mills. If every ton / hour of EFB pellet production takes 300 KW, then for production of 10 tonnes / hour (5,000 tonnes / month) 3 MW of electricity is needed, export of biomass fuels such as wood pellets and PKS (palm kernel shell)  with bulk shipments usually requires 10 thousand tons / shipment. So if the production of EFB pellets is planned for 10 thousand tons / month so that every month can export the EFB pellets, the factory capacity or EFB pellet production is 20 tons / hour (10,000 tons / month) 6 MW of electricity is needed. For palm oil mills, utilizing liquid waste or POME to become biogas is a potential source of energy for the production of electricity. However, with a palm oil mill capacity of 30 tonnes of FFB / hour, only about 1 MW of electricity is generated from POME biogas, so to produce 6 MW of palm oil mills with a capacity of 6 x 30 tonnes of FFB / hour are generated equal to 180 tonnes of FFB / hour. In fact, the average palm oil mill has a capacity of 45 - 60 tonnes of FFB / hour, so it is impossible to generate 6 MW of electricity from the palm oil mill's POME biogas.

The use of EFB pellets is the same as wood pellets and PKS is mainly for power generation. All three are biomass fuels. The high chlorine and potassium content in empty palm fruit bunches or EFB makes their use limited to power plants due to corrosion and scale causes. Not all power plants can use EFB pellets at large capacities or quantities. The use of coal-fired power plants with pulverized combustion technology can only be used with a small ratio or an estimate of less than 5%, but can be used more or even 100% in fluidized bed and stoker types of power plants. The capacity of fluidized bed and stoker type PLTU is generally much smaller than pulverized combustion.

When the biomass source is managed properly, the use of biomass fuel is an environmentally friendly and sustainable fuel. Biomass fuels like this are carbon neutral fuels, because they do not increase the concentration of CO2 in the atmosphere. This is because the biomass as a fuel source comes from plants whose growth is from the photosynthesis process, one of which uses CO2 from the atmosphere, so that when the biomass is burned, there is practically no addition of CO2 to the atmosphere. In general, there are 2 ways to overcome the CO2 concentration in the atmosphere which causes climate change and global warming, namely the carbon neutral scenario and the carbon negative scenario. In a carbon negative scenario, CO2 in the atmosphere will be captured and absorbed so that it is no longer released and the concentration of CO2 in the atmosphere can be reduced, as in the biochar application below. 

Whereas in the production of biochar with pyrolysis, besides not requiring a large amount of electrical power for its operation, electricity can also be generated from the use of excess energy from pyrolysis itself. By using the excess energy from pyrolysis, the palm oil mill boiler fuel does not need to use palm kernel shells and fiber. The use of gas or liquid fuels from the excess energy of the pyrolysis process also makes burning emissions cleaner. To achieve more complete combustion, gaseous or liquid fuels are better than solid fuels. Palm kernel shells so that everything can be sold or even exported. The biochar product applied to palm oil plantations will also improve the quality of the soil so that fertilizer use can be reduced and the productivity of palm oil fruit will increase. Biochar also absorbs CO2 from the atmosphere so that the use of biochar in large palm oil plantations means that with massive applications it can also be used for carbon trading. Recent developments indicate that the use of biochar is increasingly widespread, such as biomaterials for construction, transportation, plastics, packaging, furniture and so on. The use of biomaterials for these products means substituting the use of fossil-derived raw materials. 

So based on the above review, the production of biochar with pyrolysis is more profitable and easy to implement for palm oil mills compared to EFB pellet production. The addition of electricity production with a large capacity and the availability of sufficient raw materials is not easy and cheap for the average palm oil mill in Indonesia with a capacity of 45 - 60 tons of FFB / hour. Whereas in the production of biochar with pyrolysis, a certain amount of energy is produced which can be used for various purposes and the use of biochar is also multi-beneficial. Palm oil mills should consider this in particular in the aspects of waste management, plantation productivity, environmental aspects and business development, for more read here. Based on experience, the cost structure of the CPO or palm oil production business consists of about 80% of the cost of production is the cost of crops or plantation aspects, while the other 20% is the cost of processing or mill aspects. And the highest cost aspect of palm oil plantations is the cost of fertilization so that if the need for fertilizer can be reduced and the productivity of palm oil can be increased, of course it is very profitable, biochar is effective and efficient to use for this. 

Sabtu, 20 November 2021

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.  

Modern Ruminant Livestock Paradigm: Reducing Methane Production and Increasing Feed Efficiency

 The gases in the atmosphere that can capture the sun's heat are called greenhouse gases (GHG). Which includes greenhouse gases in the atmosphere, among others, are carbon dioxide (CO2), nitrogen dioxide (N2O), methane (CH4), and freon (SF6, HFC and PFC). Methane gas (CH4) is a dangerous gas for the earth's atmosphere and one of the greenhouse gas groups above because of the destructive power of methane gas 21 times carbon dioxide (CO2). This requires efforts to prevent methane gas and reduce its production. An example is the use of POME waste or palm oil mill effluent for biogas production. In this way, methane occurring in the open air (aerobic) will be avoided (methane avoidance scenario) and will not be released into the atmosphere with the biogas unit. The livestock sector also has the potential to produce, namely the group of ruminant farms or ruminant animals. The methane is produced in the ruminant's rumen as part of the digestion process. It is estimated that the contribution of methane from ruminant livestock is dominant and of course it needs to be reduced. The production of methane gas (CH4) besides being an environmental problem also causes a lot of energy loss in livestock. And it turns out that there is a process of reducing methane production which simultaneously improves health and increases body weight and milk production.

Large ruminant farms should be more aware of this condition and have a greater incentive to reduce methane production. Biochar is a feed supplement that can be used for the above purposes. The use of 1-3% biochar from dry feed ingredients has been shown to significantly increase body weight gain in beef cattle, as well as milk production in dairy cows. Experiments in Australia on beef cattle for 2 months have given a weight gain of 10% compared to those who do not use biochar. As for dairy cows, it has provided a profit of $ 70,000 per year. For more details, read here. Meanwhile, the reduction in methane gas emissions is estimated at 29% from the use of biochar. Once paddle 2-3 islands, so the saying goes.

Another effect of using biochar as a feed additive is that livestock manure becomes denser and less smelly. Biochar can also be used alone to deal with the smell and viscosity of livestock manure, so that the cage becomes cleaner and does not smell strong. In addition, if the manure is used for production, the biogas production will also increase, for more details, please read here. The composted digestate will also produce better organic fertilizer (compost) because of the additional biochar. 

The quality of biochar is also very important, especially for animal feed supplements. Meat and milk are livestock production to meet human food needs, so that it will also affect humans in the end. The quality of biochar is determined by the raw materials used and the production process carried out. This indicates that not all biochar has the same quality, for example biochar from agricultural wastes with high ash content with traditional processes, with wood biomass raw materials with a small ash content and modern processes, of course the results are different, for example using the same modern technology will have different results. The differences mainly lie in their physical chemistry properties. 

Biochar production should also be designed according to its objectives, for example the biochar feed supplement above must use selected biomass raw materials and modern processes so that the quality is stable and maintained. Meanwhile, the reference for biochar quality can be OMRI, USDA or IBI. World feed livestock associations or organizations such as FEFAC, IFIF and AFIA are currently very concerned about safety and sustainability, so this can be in line with biochar as a feed additive. Biochar as a feed additive, especially dairy cattle, has been accepted by almost all European Union countries. Meanwhile, for purposes such as reducing odors and the dilution of impurities, biochar is produced from any biomass and even by using simple technology (low tech).