Production of Electricity and Biochar from Pineapple Plantation Waste

Besides being able to be processed into briquettes or in more detail, read here, pineapple plantation waste can also be used for electricity and biochar production. The use of biochar on pineapple plantation land will increase fertility and improve soil quality so that it will also increase the productivity of the pineapple fruit. The use of biochar on dry land such as pineapple plantations will be more effective so that the benefits will be even more real. Biochar that can last up to hundreds of years in the soil will provide long-term benefits for pineapple plantation owners. The era in the future that tends towards efficient agriculture or precision agriculture will also produce less waste or even zero waste. Agricultural wastes that have been a lot of environmental problems will be reduced and processed into added value, environmentally friendly and sustainable materials such as biochar production.

In large pineapple plantations, the amount of pineapple waste produced is also large. Besides producing biochar, pyrolysis of pineapple waste will also generate electricity. Electricity as a form of energy that is easily converted to various other forms of energy is certainly very useful, especially the pineapple industry. Pineapple processing can use the electricity generated, thereby reducing or even eliminating the need for external electricity. But it is possible that if the pineapple industry needs heat more than electricity, the excess energy from pyrolysis does not need to be converted into electricity but only heat is enough and this is easier and simpler. Of course, these things also further reduce the production costs of these pineapple-based products, thus providing even greater profit.

 There are many products from the pineapple industry, including candied pineapple, pineapple jam, pineapple paste, pineapple chips, pineapple juice, pineapple juice probiotics, pineapple jelly, canned pineapple, and dried fruit. As one fruit that is quite popular throughout the world, the demand for pineapple is also increasing. With the prediction of the world's population reaching nearly 10 billion by 2050, the need for food, especially fruit, will also increase. Pineapple peels are also commonly used as animal feed, especially cattle, and cow dung is used for biogas production. The addition of biochar to cow dung for biogas will increase biogas production, more details can be read here and the sideproduct in the form of digestate which is then composted will be of better quality in the presence of biochar. Biochar makes the nutrients in compost not easy washed but is released slowly (slow release fertilizer).  

Continuous Pyrolysis Unit for Activated Carbon Production

Production of activated carbon requires charcoal as raw material. Charcoal production will be more effective and efficient by continuous pyrolysis (carbonization). In addition to the high quality charcoal produced can also produce electricity and steam production for the activation process. Of course this makes high efficiency of the production process. Whereas in terms of environmental aspects, it is also very environmentally friendly because of smoke pollution during the process of pyrolysis (carbonisation) can be minimized below the threshold. Methane emissions that are very damaging to the ozone layer also did not occur.

The process of pyrolysis (carbonization) with a temperature of around 400 C with a product in the form of charcoal can immediately proceed with activation. Activation with 700-1000 C operating conditions can be done directly by raising the temperature. If the excess syngas is used for electricity production, then biooil from pyrolysis can be used to fuel in steam production. Excess electricity can also be sold to industries or to electricity companies. Whereas if all sources of energy are used for the production of activated charcoal (activated carbon), the consumption of heating oil can be minimized and even eliminated. Activated carbon production with all the energy can be supplied by itself is certainly very interesting and economical.

The problem with traditional charcoal production is the problem of smoke pollution and the amount of energy lost. Smoke pollution can be directly identified and can be easily felt, but the problem of energy loss is usually not noticed and generally do not know. Of course this is very unfortunate, let alone energy is one component of high costs in a production process. Is there really an energy loss? And how much energy is lost? Of course we need to look in detail at the carbonization process (pyrolysis) to answer these questions.

 Conversion from raw materials to charcoal is only 20-25% in the process of traditional carbonization / pyrolysis. For example, we take a conversion of 25%, with a raw material of 10 tons of coconut shell, 2.5 tons of charcoal are produced. Coconut shell with a heating value of around 4,500 kcal / kg, meaning that 10 tons of raw material is 45,000,000 kcal. While coconut shell charcoal with a heating value of around 8,000 kcal / kg, then 2.5 tons of charcoal will have a heating value of 20,000,000 kcal / kg. Based on these calculations more than 50% of energy is lost or is only wasted, ie 25,000,000 kcal. If the conversion to charcoal is lower or 20%, the energy loss is even greater, namely 29,000,000 kcal or more than 60%. Of course it is very inefficient and should be avoided. This can also happen for carbonization of various other raw materials for activated carbon, such as palm kernel shells, wood, and so on.

Continuous pyrolysis is the best solution for charcoal production and also the production of energy that can be used for the activated carbon production process itself. The activated carbon factories that have been established can upgrade the technology especially on the side of charcoal production and energy fulfillment. The more efficient of a production will be the more economical the business. While the pyrolysis or carbonization process is also still produced by-products namely biomass vinegar (pyroligneous acid / liquid smoke) which can be used as plant fertilizer, biopesticides to raw materials for chemicals, especially biophenol and wood adhesive.

Production of Biophenol, Bioformaldehyde and Wood Adhesive from Pyrolysis Liquid Products

The byproducts of biomass (slow) pyrolysis are liquid and gas products. The liquid products consist of biooil and biomass vinegar (pyroligneous acid). Biooils can be directly used as fuel with a particular burner, or can also be upgraded to the vehicle fuel. Meanwhile, if used for non-energy products, can be used for the production of green chemical or renewable chemicals such as BioFormaldehyde and wood adhesive. While the aqueous phase of pyrolysis liquid product that is biomass vinegar (pyroligneous acid) can be used for feedstock biophenol production. Previously biomass vinegar has been known for various uses such as latex coagulant, anti-termite and fertilizer. While the biophenol production process scheme of biomass vinegar as follows.

Global consumption for phenol currently reaches 20 million tons or worth 20 billion US dollars (280 trillion rupiah). Renewable phenol or biophenol can substitute phenol which has been produced based on petroleum. Excess heat and excess syngas from the pyrolysis process can be used for the production process of the biophenol as energy sources. An integrated and efficient production unit will produce highly competitive products, such as the pyrolysis process which is primarily charcoal, and from its by-products made derivative products that are desperately needed today.