Cross-Comparison of the Impact of Grass Silage Pulsed Electric Field and Microwave-Induced Disintegration on Biogas Production Efficiency

Szwarc, Dawid; Nowicka, Anna; Głowacka, Katarzyna

doi:10.3390/en15145122

Cited by 4 publications

(5 citation statements)

References 33 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…Methane productivity from pulsed electric field (PEF) pre-treated silage increased by 20.1% compared to the untreated control. The highest biogas output from PEF pre-treated samples was 535.57 L•kgVS -1 , while the highest biogas output from microwave pre-treatment substrates was 487.18 L•kgVS -1 [6]. During the 9 days of a fed-batch cycle, biohythane (biomethane and biohydrogen) production of 0.667 ± 0.054 L•Lreactor −1 (based on three fed-batch cycles) in alkali-pre-treated sludge fed MECs was obtained, compared to 0.451 ± 0.030 L•Lreactor −1 in raw sludge fed MEC and 0.383 ± 0.027 L•Lreactor −1 in raw sludge fed open circuit MEC [7].…”

Section: Introductionmentioning

confidence: 95%

“…The use of electricity in promoting the potential of biogas has taken place in different directionsstarting with the use of a pulsed electric field in the pre-treatment of the input material [6] and ending with the placement of microbial electrolysis cells (MEC) in the bioreactor itself [7; 8]. Methane productivity from pulsed electric field (PEF) pre-treated silage increased by 20.1% compared to the untreated control.…”

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Biogas potential from co-fermentation of food leftovers and lignocellulosic biomass at mesophilic temperatures

Straume,

Plume,

Dubrovskis

et al. 2023

22nd International Scientific Conference Engineering for Rural Development Proceedings

View full text Add to dashboard Cite

Every year, large amounts of food leftovers are thrown away in catering establishments and households. Industry and agriculture produce lignocellulosic residues, including paper dust and willow biomass, which cause environmental problems if not properly disposed of. The aim of this study is to investigate the biogas and biomethane yields of these biomasses during anaerobic co-fermentation under mesophilic conditions. Biogas yields were determined by co-fermentation of food (hospital canteen, cafeteria, and household) residues and lignocellulosic (paper dust and shredded willow) biomass in a number of 0.72 L bioreactors. All bioreactors were divided into groups having the same content in reactors within each group to ensure the reliability of the results. Groups of bioreactors used for anaerobic fermentation were inoculums (0.5 L) only, inoculums with individual biomass, and inoculums with mixture of two or more biomass. Bioreactors were placed in three different thermostats with 16 bioreactors in each thermostat. Single fill batch anaerobic fermentation (AF) process was provided at 28, 33 and 38 °C. Individual reactor groups were equipped with graphite electrodes connected to DC voltage of 0.7 V. The biogas released in the bioreactor was collected into a gas bag outside the reactor. AF was maintained until gas emission ceased. The highest biogas yield in the AF process was obtained from the bioreactors at a temperature of 38 °C and the lowest at a temperature of 28 °C. Co-fermentation of biomass increased biogas and methane yields compared to AF treatment of individual biomasses. Exposure to the electric field decreased the methane yield. The energy balance on the AF process with the application of the electric field should be calculated by considering also the energy of hydrogen released from substrates with electrodes installed.

show abstract

Section: Introductionmentioning

confidence: 95%

Section: Introductionmentioning

confidence: 99%

Biogas potential from co-fermentation of food leftovers and lignocellulosic biomass at mesophilic temperatures

Straume,

Plume,

Dubrovskis

et al. 2023

22nd International Scientific Conference Engineering for Rural Development Proceedings

View full text Add to dashboard Cite

show abstract

“…A similar study was conducted by Deng et al [29], in which the COD content increased by approximately 29% following the application of the PEF treatment of sewage sludge. The effects of ultrasonic radiation treatment of lignocellulosic substrate on TOC and COD solubilisation were also investigated by Kisielewska et al [25]. The ultrasonic disintegration of Sida hermaphrodita increased the TOC and COD contents in the liquid fraction of the substrate by 24.7 and 21.9%, respectively.…”

Section: The Effect Of Up and Pef On Organic Matter Solubilisationmentioning

confidence: 99%

“…A voltage of 40 kV amplitude was applied to the electrodes. Based on the preliminary studies, the process parameters were selected [23][24][25]. The generated electrical pulses were characterised by a width of 50 µs and a frequency of 5 kHz.…”

Section: Pretreatmentmentioning

confidence: 99%

Comparison of the Effects of Pulsed Electric Field Disintegration and Ultrasound Treatment on the Efficiency of Biogas Production from Chicken Manure

2023

Self Cite

View full text Add to dashboard Cite

This study used chicken manure classified as lignocellulosic biomass due to its high straw content. This paper compares the possibility of using pulsed electric field (PEF) pretreatment of lignocellulosic substrates with ultrasonic disintegration (UP) to increase methane production. As for ultrasonic treatment, the BMP increased from 210.42 ± 7.92 mL/g VS to 250.06 ± 8.68 mL/g VS, whereas with PEF disintegration, the BMP ratio increased from 210.42 ± 7.92 mL/g VS to 248.90 ± 9.29 mL/g VS. The use of PEF and UP pretreatment increased methane production from 307.29 ± 13.65 mL/g VS to 366.99 ± 14.18 mL/g VS and from 307.29 ± 13.65 mL/g VS to 365.07 ± 11.71 mL/g VS, respectively. This study showed that both ultrasonic treatment and PEF contribute to the biochemical potential of methane (BMP) from chicken manure.

show abstract

“…Studies carried out in France and Denmark showed that the total nitrogen amount in catch crops' biomass harvested on 1 hectare ranged from 10 to 171 kg N ha −1 for legumes, and from 9 to 89 kg N ha −1 for non-legumes, while the C:N ratio ranged widely, from 9 to 40, thus sometimes going beyond the range considered optimal for microorganisms' growth, which is estimated to be between 20 and 35 [113,114]. According to the study of Szwarc et al [99], the C:N ratio of grass silage was ca. 23.…”

Section: Features Of CCC Biomass Important Because Of Biochemical Con...mentioning

confidence: 99%

Catch and Cover Crops’ Use in the Energy Sector via Conversion into Biogas—Potential Benefits and Disadvantages

Słomka,

Pawłowska

2024

Energies

View full text Add to dashboard Cite

The development of civilization is related to an increase in energy demand, while its production is still based mainly on fossil fuels. The release of carbon into the environment, which disturbs the balance of the global system, is the consequence of using these fuels. One possible way to reduce the carbon footprint of the energy sector is the widespread use of cover crops’ biomass for energy production. The aim of this paper is to critically review the knowledge on the dissemination of catch and cover crops’ cultivation in different regions of the world, and the yield, chemical composition and biomethane potential of their biomass. Additionally, the environmental benefits, as well as the challenges and opportunities associated with this biomass use in the energy sector, are considered. The review showed that the aboveground biomass of cover and catch crops is a valuable source for the production of bioenergy in biogas plants. However, the key role of these crops is to prevent soil degradation. Therefore, changes in biomass target use must be preceded by a multi-aspect analysis that allows their impact on the environment to be assessed.

show abstract

Cross-Comparison of the Impact of Grass Silage Pulsed Electric Field and Microwave-Induced Disintegration on Biogas Production Efficiency

Cited by 4 publications

References 33 publications

Biogas potential from co-fermentation of food leftovers and lignocellulosic biomass at mesophilic temperatures

Biogas potential from co-fermentation of food leftovers and lignocellulosic biomass at mesophilic temperatures

Comparison of the Effects of Pulsed Electric Field Disintegration and Ultrasound Treatment on the Efficiency of Biogas Production from Chicken Manure

Catch and Cover Crops’ Use in the Energy Sector via Conversion into Biogas—Potential Benefits and Disadvantages

Contact Info

Product

Resources

About