Conversion of lignocellulose from palm (Elaeis guineensis) fruit fibre and physic (Jatropha curcas) nut shell into bio-oil

Onifade, T. B.; Wandiga, Shem O.; Bello, Idioleidys Álvarez; Jekanyinfa, S. O.; Harvey, Patricia J.

doi:10.5897/ajb2017.16004

Cited by 7 publications

(3 citation statements)

References 31 publications

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“…Garba et al [275] and Akanni et al [276] also carried out torrefaction studies on rice straw and woody biomass (Melina and Teak wood), respectively, varying both temperatures and residence times. Farrow et al [277] investigated the characteristics of char produced from cassava peelings whilst Onifade et al [278] characterized bio-oil produced from palm fruit fiber and physic nut shell. Okekunle et al [279] assessed the pyrolysis products from different wood sources (Gmelina arborea, Anogeissus leiocarpa, Parkia biglobosa, and Adansonia kilima).…”

Section: Thermochemical Conversionmentioning

confidence: 99%

An Assessment of Potential Resources for Biomass Energy in Nigeria

2020

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Nigeria is a developing country with an insufficient supply of energy to meet the continuously growing demand. However, there are several biomass resources available within the country. This paper presents a desk review, which investigates the potential resources for biomass energy generation within the country. Energy policies to aid biomass use as an energy source within the country were also reviewed. Biomass resources identified within Nigeria include forest residues, agricultural residues, human and animal wastes, aquatic biomass, and energy crops. However, several of the resources, particularly agricultural residues, have competing uses, such as livestock feed and soil rejuvenation. An estimation of the technical energy potential of the biomass resources revealed that about 2.33 EJ could be generated from the available resources in Nigeria. Agricultural residues have an energy potential of about 1.09 EJ, with cassava, maize, oil palm, plantain, rice, and sorghum being the major contributors. Animal wastes, municipal solid waste, and forest residues have energy potentials of 0.65, 0.11, and 0.05 EJ, respectively. The potentials of wood fuel and charcoal are 0.38 and 0.05 EJ, respectively. The study found that despite the available potential and existing policies, not much has been done in the implementation of large-scale bioenergy within the country. However, there has been laboratory and research-scale investigations. The review suggests that more policies and stronger enforcement will aid bioenergy development within the country. From the review, it has been suggested that the agricultural sector needs to be developed to generate more biomass resources. More research, development, and implementation have to be carried out on biomass resources and bioenergy generation processes. The production of non-edible energy crops in marginal lands should also be considered prime to the development of bioenergy within the country.

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Section: Thermochemical Conversionmentioning

confidence: 99%

An Assessment of Potential Resources for Biomass Energy in Nigeria

2020

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“…The pyrolysis method has been used for commercial production of a wide range of fuels, solvents, chemicals and other products from biomass feedstocks [5]. For instance, materials such as tropical woody biomass [6], palm fruit fibre [7]; others like, rice husk [8], groundnut shell [9] and many more are also used as energy sources via pyrolysis.…”

Section: Introductionmentioning

confidence: 99%

Bio-Fuel Properties and Elemental Analysis of Bio-Oil Produced from Pyrolysis of Gmelina Arborea

Adegoke¹,

Ogunsanwo

Rapheal

2021

Acta Chemica Malaysia

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Nigeria demand for sustainable, affordable and accessible energy is on the rise. Hence, this led to rigorous research to determine affordable processes of using waste materials for production of sustainable energy. In this research pyrolysis was carried out in a fabricated fixed bed pilot-scale reactor using Gmelina arborea (sawdust) biomass for the production of bio-oil. The physical, chemical properties and the ultimate analysis of the bio oil produced were determined following standard methods. The physicochemical properties and ultimate analysis obtained were favourable. The highest moisture content of 21 % at 600 oC and least moisture content of 12 % at 900 oC were obtained from Gmelina arborea. The elemental results of the products show low sulphur quantity which is of good prospects that Gmelina arborea are good materials for bioenergy production without posing danger to the environment. Utilisation of Gmelina arborea for bio-oil production as an alternative fuel would shun unfavourable environmental abasement related to the use of conventional fuels.

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“…Palm fruit fibres and sawdust are used as building materials (Sosu et al 2011). Palm fibres are also used in water filtration filters (Idris et al 2017), for the production of bio-oil (Onifade et al 2017), frictional material (Achebe et al 2019), and in biomedicine (Namvar et al 2014). Up to now are no reports regarding the mechanical properties of Trapa natans nuts.…”

Section: Discussionmentioning

confidence: 99%

Changes in physico-mechanical properties of water caltrop fruit (Trapa natans L.) during the drying process

Toma

Kukliński

Dajdok

2021

Sci Nat

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The cosmopolitan water caltrop plant (Trapa natans L.) produces nuts, which in the maturing process develop very hard pericarps. This hardness, together with structure and shape (external spikes) of pericarp and seed, and the water contained in the fruit are responsible for their mechanical properties. This study determined the force needed to break Trapa natans nuts at various drying stages, with tests having been carried out at weekly intervals until the fruit dried completely. The amount of force necessary for cracking nuts at each of the 6 drying stages was determined, as well as the work of crushing calculated until the greatest compressive force (crushing force) was reached. The force needed to rupture the hydrated fruit in the horizontal plane was higher than that necessary for the rupture of dried fruit. The experiment showed that the maximum force needed to crush the fruit was 828.7 N and occurred when crushing the fruit after 2 weeks of drying, while the largest calculated crushing work was 2185.5 mJ for the same fruit. Other strength parameters were introduced to characterize mechanical properties of water caltrop in a more extensive scope. These are hardness defined as a ratio of compressive force increment to strain increment, specific crushing energy defined as a ratio of crushing work to water caltrop’s mass, and unit crashing force defined as a ratio of crushing force to caltrop’s thickness. All these parameters reached their highest mean values for pericarps after 2 weeks of desiccation. Mass measurements were also applied in modelling the desiccation process by the exponential function. The very dense pericarp material, after reaching maturity, slightly changes during drying. It can be used industrially as an extremely durable and biodegradable biological material. Results also suggest that the great evolutionary success of the species may result from the ability of the pericarp to protect its seeds, leading to the spread of this species in aquatic environments.

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Conversion of lignocellulose from palm (Elaeis guineensis) fruit fibre and physic (Jatropha curcas) nut shell into bio-oil

Cited by 7 publications

References 31 publications

An Assessment of Potential Resources for Biomass Energy in Nigeria

An Assessment of Potential Resources for Biomass Energy in Nigeria

Bio-Fuel Properties and Elemental Analysis of Bio-Oil Produced from Pyrolysis of Gmelina Arborea

Changes in physico-mechanical properties of water caltrop fruit (Trapa natans L.) during the drying process

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