Data on energy and economic evaluation and microbial assessment of anaerobic co-digestion of fruit rind of Telfairia occidentalis (Fluted pumpkin) and poultry manure.

The data described in this article was obtained in an experiment designed for the generation of biogas from the anaerobic co-digestion of Telfairia occidentalis (Fluted pumpkin) fruit rind and poultry manure both of which currently constitute an environmental nuisance in the localities where they are found. The data presented in this article is on the use of combined heat and power (CHP) system to assess the energy and economic feasibility of applying thermo-alkali pretreatment procedures to one of the substrates (Fluted pumpkin) prior to anaerobic digestion. Also, the microbial characterization and succession pattern of important microbes during the anaerobic digestion process was evaluated and the data reported in this paper.

Specifications table

Values of the data

The data presented in this article reveals the energy and economic evaluation of the anaerobic co-digestion of fruit rind of Telfairia occidentalis (Fluted Pumpkin) and Poultry manure for biogas generation

The data will serve as a precursor for further research on the economic assessment of biomass pretreatment prior to anaerobic digestion processes

The data give further exposure on the necessity and feasibility of pretreatment of biomass prior to anaerobic digestion.

More robust heat and power systems can be used to further explore the generated data from this study in order to apply the processes in industrial scale experiments.

Data

The combined heat and power (CHP) system was used to assess the energy balance and the economic feasibility of applying thermal and alkaline pre-treatment to T. occidentalis fruit rind using a 50 and 30% thermal and electrical efficiencies respectively (Table 1). Therefore, to determine the thermal energy requirement (TER) for thermal and alkaline pre-treatments of T. occidentalis fruit rind, the energy needed to raise the temperature of 35 g TS L−1 T. occidentalis fruit rind mixture from 25 to 55 °C was determined using the specific heat of water i.e. 4.18 kJ kg−1 °C−1 in order to evaluate the specific heat of the mixture while neglecting heat loss [1], [2], [3].

Table 1

Energy and economic evaluation for the anaerobic co-digestion of Telfairia occidentalis fruit rind and poultry manure.

Energy parameters	Experiment A	Experiment B	Experiment C
Produced electrical and thermal energy from combined heat and power (CHP)	1785 ± 0.01	1699 ± 0.02	1155 ± 0.02
Produced thermal energy (kWh t−1 TS)	1645 ± 0.02	1547 ± 0.01	498 ± 0.01
Produced electrical energy (kWh t−1 TS)	770 ± 0.01	563 ± 0.02	340 ± 0.02
Thermal balance
*Thermal energy gain (kWh t−1 TS)	1147 ± 0.01	1049 ± 0.03	–
Thermal energy requirement (kWh t−1 TS)	1088 ± 0.02	1109 ± 0.03	–
Thermal energy requirement with 80% of heat recovery (kWh t−1 TS)	218 ± 0.02	210 ± 0.01	–
#Net thermal energy (kWh t−1 TS)	59 ± 0.02	−60 ± 0.02	–
Net thermal energy with 80% of heat recovery (kWh t−1 TS)	−929 ± 0.02	−839 ± 0.03	–
Electrical balance
$Electrical energy gain	430 ± 0.01	223 ± 0.02	–
Energy for mixing during pretreatment	–	–	–
Net electrical energy	430 ± 0.01	223 ± 0.01
Economic evaluation
Cost of NaOH (є t−1 TS)

Remark:*=difference of thermal energies produced by the pretreated experiment minus the untreated; #=difference between the thermal energy gain and the thermal energy requirement for the thermo-alkaline pretreatment; a $=difference of electricity energies produced by pretreated experiment minus the untreated.

To assess the electrical energy, only the electric energy used for the substrate mixing was considered neglecting the energy used during mechanical treatment since this was also done for the experiment without thermal and alkaline pre-treatment [4]. Table 2 shows the heat balance of different biomass previously anaerobically digested with thermal and alkaline pre-treatments procedures [5], [6], [7], [8], [9].

Table 2

Energy balances of thermal and thermo-chemical pretreatment procedures as applied to different substrates.

Substrate	Condition of pretreatment	Increase in methane yield (m3 t−1TS)/operation mode	Biogas conversion	Surplus thermal energy (kWh t−1TS)	Thermal pretreatment requirements (kWh t−1TS)	Net heat energy (kWh t−1TS)	References
Telfairia occidentalis fruit rind	Thermo-alkaline (55 °C; 4% NaOH (w/w); 24 h) Solid load: 35 g TS L−1	40/Batch mode	CHP: 35% electricity; 50% heat	1147	1088	59	Current study
	Thermo-alkaline (55 °C; 4% KOH (w/w); 24 h) Solid load: 35 g TS L−1	35/Batch mode	CHP: 35% electricity; 50% heat	1049	1109	−60	Current study
Tithonia diversifolia shoot	Thermo-alkaline (55 °C; 4% NaOH (w/w); 24 h) Solid load: 35 g TS L−1	53/Batch mode	CHP: 35% electricity; 50% heat	1176	1068	108	[10]
	Thermo-alkaline (55 °C; 4% KOH (w/w); 24 h) Solid load: 35 g TS L−1	30/Batch mode	CHP: 35% electricity; 50% heat	862	1150	−288	[10]
Peanut hull	Thermo-alkaline (55 °C; 4% NaOH (w/w); 24 h) Solid load: 35 g TS L−1	70/Batch mode	CHP: 35% electricity; 50% heat	761	1173	−412	[11]
Sunflower stalks	Thermo-alkaline (55 °C; 4% NaOH (w/w); 24 h) Solid load: 35 g TS L−1	36/Continuous mode	CHP: 35% electricity; 50% heat	185	1034	−849	[12]
	Thermo-alkaline (55 °C; 4% NaOH (w/w); 24 h) Solid load: 50 g TS L−1	36/Continuous mode	CHP: 35% electricity; 50% heat	185	733	−548	[12]
	hermo-alkaline (55 °C; 4% NaOH (w/w TS); 24 h) Solid load: 200 g TS L−1	36/Continuous mode	CHP: 35% electricity; 50% heat	185	210	−25	[12]
	Thermo-alkaline (55 °C; 4% NaOH (w/w); 24 h) Solid load: 50 g TS L−1 80% of heat recovery from pretreatment	36/Continuous mode	CHP: 35% electricity; 50% heat	185	147	38	[12]
Sunflower Oil Cake	Thermal (170 °C; 1 h)	32/Batch mode	CHP: 35% electricity; 50% heat	161	3535	−3375	[6]
	Solid load: 50 g TS L−1
	Thermal (170 °C; 1 h)	32/Batch mode	CHP: 35% electricity; 50% heat	161	1010	−849	[6]
	Solid load: 200 g TS L−1
	Thermal (170 °C; 1 h) Solid load: 200 g TS L−1 80% of heat recovery from pretreatment	32/Batch mode	CHP: 35% electricity; 50% heat	161	152	9	[6]
Ensiled Sorghum Forage	Thermo-alkaline (100 °C; 30 min, 10% NaOH w/w) Solid load: 160 g TS L−1	92/Batch mode	CHP: 40% electricity; 41% heat	378	547	−169	[13]
	Thermo-alkaline (100 °C; 30 min, 10% NaOH w/w) Solid load: 160 g	92/Batch mode	CHP: 40% electricity; 41% heat	378	109	269	[13]
	TS L−1 80% of heat recovery from Pretreatment
Wheat straw	Thermo-alkaline (100 °C; 30 min, 10% NaOH w/w) Solid load: 160 g TS L−1	137/Batch mode	CHP: 40% electricity; 41% heat	577	547	30	[13]
	Thermo-alkaline (100 °C; 30 min, 10% NaOH w/w) Solid load: 160 g TS L−1 80% of heat recovery from Pretreatment	137/Batch mode	CHP: 40% electricity; 41% heat	577	109	468	[13]
Microalgae	Thermal (75 °C; 15 min) Solid load: 11.7 g TS L−1 85% of heat recovery from Pretreatment	32/Batch mode	100% heat conversion	316	458	−142	[7]
	Thermal (75 °C; 15 min) Solid load: 20 g TS L−1 85% of heat recovery from Pretreatment	32/Batch mode	100% heat conversion	316	268	48	[7]
	Thermal (75 °C; 15 min) Solid load: 30 g TS L−1 85% of heat recovery from Pretreatment	32/Batch mode	100% heat conversion	316	173	143	[7]

In the co-digestion of Telfairia occidentalis fruit rind and poultry manure, various aerobic and anaerobes bacteria, fungi and methanogens were isolated and characterized (Table 3).

Table 3

Microbial evaluation and succession in the anaerobic co-digestion of Telfairia occidentalis fruit rind+poultry manure.

Day	Aerobes (Cfu/ml)		Fungi (Cfu/ml)		Anaerobes (Cfu/ml)		Methanogens (Cfu/ml)
	Organism	TAPC	Organism	TFC	Organism	TPC	Organism	TPC
0	Bacillus sp.	2.3 × 1010	Aspergillus niger	1.0 × 108	Fusobacterium sp.	1.2 × 1010	Methanosarcinales sp.	1.2 × 1010
	Serratia sp.		Aspergillus flavus		Bacteroides sp.		Methanobacteriales sp.
	Pseudomonas aeruginosa		Rhizopus sp.		Clostridium sp.		Methanomicrobiales sp.
	Proteus sp.		Mucor sp.		Porphyromonas sp.		Aminobacteria sp.
			Penicillum sp.
6 6	Bacillus sp.	1.4 × 108	Aspergillus niger	1.2 × 108	Fusobacterium sp.	1.0 × 106	Methanosarcinales sp.	1.0 × 108
	Serratia sp.		Aspergillus flavus		Bacteroides sp.		Methanobacteriales sp.
	Pseudomonas aeruginosa		Rhizopus sp.		Clostridium sp.		Methanomicrobiales sp.
	Proteus sp.		Mucor sp.		Porphyromonas sp.		Aminobacteria sp.
			Penicillum sp.
12 12	Nil	Nil	Aspergillus niger	1.0 × 103	Fusobacterium sp.	1.0 × 104	Methanosarcinales sp.	1.0 × 105
			Aspergillus flavus		Bacteroides sp.		Methanobacteriales sp.
			Rhizopus sp.		Clostridium sp.		Methanomicrobiales sp.
			Mucor sp.		Porphyromonas sp.		Aminobacteria sp.
			Penicillum sp.
18 18	Bacillus sp.	1.0 × 102	Aspergillus niger	1.0 × 102	Fusobacterium sp.	1.3 × 1010	Methanosarcinales sp.	1.0 × 1010
					Clostridium sp.		Methanobacteriales sp.
					Porphyromonas sp.		Methanomicrobiales sp.
							Aminobacteria sp.
24 24	Bacillus sp.	1.0 × 102	Aspergillus niger	1.0 × 102	Fusobacterium sp.	1.2 × 103	Methanosarcinales sp.	1.7 × 1010
					Clostridium sp.		Methanobacteriales sp.
					Porphyromonas sp.		Methanomicrobiales sp.
							Aminobacteria sp.
30 30	Bacillus sp.	1.0 × 102	Aspergillus niger	1.0 × 102	Fusobacterium sp.	1.2 × 102	Methanosarcinales sp.	2.7 × 1012
					Clostridium sp.		Methanobacteriales sp.
							Methanomicrobiales sp.
							Aminobacteria sp.

Remark: TAPC=Total aerobic plate count; TFC=Total fungal count; TPC=Mean Plate Count.

Experimental design, materials and methods

Materials and method

Data was obtained from the evaluation of pretreatment application to fruit rind of Telfairia occidentalis and the possibility of gaining back the investment (obtaining of chemicals and heat) into the pretreatment procedure through the sale of additional energy gained.

Experimental design

A simple computational equation was used to first determine the thermal energy required (TER) in kWh t-1 TS for raising the temperature of one ton TS of T. occidentalis fruit rind from 25 to 55 °C during pre-treatment [14], [15], [16].

Microbial enumeration

The aerobic organisms (Bacteria and fungi) associated with the fermenting substrates were isolated and enumerated weekly using standard methods [17], [18], [19]. Facultative anaerobes were serially isolated using specialized media in an anoxic condition at 37 °C for 5 to 7 days as earlier reported [20], [21]. Confirmation of the presumptive isolates was done with corresponding rapid Analytical Profile Index (API) kits [22] while a basal medium was used for identifying methanogens [23], [24].

Statistical data analysis

The paired sample t-tests were conducted to determine the significant difference in the means of three replicates.

Subject area	Microbiology and Biotechnology
More specific subject area	Environmental Biotechnology
Type of data	Tables
How data was acquired	Combined Heat and Power (CHP) System, Analytical Profile Index (API) kits (BioMerieux, Leon, France)
Data format	Analysed
Experimental factors	Produced thermal energy, produced electrical energy, thermal energy gain, thermal energy requirement, net thermal energy, electrical energy gain, electrical energy requirement, net electrical energy
Experimental features	Energy and Economic evaluation of anaerobic co-digestion of pretreated and non-pretreated fruit rind of Telfairia occidentalis (Fluted Pumpkin) and Poultry Manure
Data source location	Omu-Aran, Kwara State
Data accessibility	The data is available within the article body