Biorefining of pigeon pea: Residue conversion by pyrolysis

Creator

Mari Rowena C. Tanquilut, Pampanga State Agricultural University
Homer C. Genuino, University of Groningen
Erwin Wilbers, University of Groningen
Rossana Marie C. Amongo, University of the Philippines Los Banos
Delfin C. Suministrado, University of the Philippines Los Banos
Kevin F. Yaptenco, University of the Philippines Los Banos
Marilyn M. Elauria, University of the Philippines Los Banos
Jessie C. Elauria, University of the Philippines Los Banos
Hero J. Heeres, University of Groningen

Issue Date

6-2020

Abstract

Pyrolysis is an important technology to convert lignocellulosic biomass to a renewable liquid energy carrier known as pyrolysis oil or bio-oil. Herein we report the pyrolysis of pigeon pea wood, a widely available biomass in the Philippines, in a semi-continuous reactor at gram scale. The effects of process conditions such as temperature (400-600 ◦C), nitrogen flow rate (7-15 mL min−1) and particle size of the biomass feed (0.5-1.3 mm) on the product yields were determined. A Box-Behnken three-level, three-factor fractional factorial design was carried out to establish process-product yield relations. Of particular interest is the liquid product (bio-oil), of which the yield was shown to depend on all independent variables in a complex manner. The optimal conditions for highest bio-oil yield (54 wt.% on dry feed intake) were a temperature of 466 ◦C, a nitrogen flow rate of 14 mL min−1 and a particle size of 1.3 mm. Validation of the optimized conditions proved that the average (n = 3) experimental bio-oil yield (52 wt.%) is in good agreement with the predicted value from the model. The properties of product oils were determined using various analytical techniques including gas chromatography-mass spectrometry (GC-MS), gel-permeation chromatography (GPC), nuclear magnetic resonance spectroscopy (13C- and HSQC-NMR) and elemental and proximate analyses. The bio-oils were shown to have low ash content (0.2%), high heating value (29 MJ kg−1) and contain high value-added phenolics compounds (41%, GC peak area) as well as low molecular weight aldehydes and carboxylic acids. GPC analysis indicated the presence of a considerable amount of higher molecular weight compounds. NMR measurements showed that a large proportion of bio-oil contains aliphatic carbons (~60%), likely formed from the decomposition of (hemi)cellulose components, which are abundantly present in the starting pigeon pea wood. Subsequent preliminary scale-up pyrolysis experiments in a fluidized bed reactor (~100 gfeed h−1, 475 ◦C and N2 flow rate of 1.5 L min−1) gave a non-optimized bio-oil yield of 44 wt.%. Further fractionation and/or processing are required to upgrade these bio-oils to biofuels and biobased chemicals.

Source or Periodical Title

Energies

Volume

13

Issue

11

Page

2778

Document Type

Article

Physical Description

diagrams; graphs; tables; references

Language

English

Subject

Bio-oil, Lignocellulosic biomass, Phenolics, Pigeon pea, Pyrolysis

Recommended Citation

Tanquilut, M.M.C., Genuino, H., Wilbers, E., Amongo, R.M.C., Suministrado, D., Yaptenco, K.F., Elauria, M., Elauria, J.C., Heeres, H.J. (2020). Biorefining of Pigeon Pea: Residue Conversion by Pyrolysis. Energies, 13(11), 2778. DOI:10.3390/en13112778.

Identifier

DOI:10.3390/en13112778.

Digital Copy

yes

En – AGROVOC descriptors

BIO-OIL; LIGNOCELLULOSIC BIOMASS; PHENOLICS; PIGEON PEA; PYROLYSIS