Your search keyword '"Valencia-Vázquez R"' showing total 8 results

1. Biochemical methane potential of residual biomass for energy generation

Author

Galván-Arzola, U., primary, Moreno-Medina, C. U., additional, Lucho-Chigo, R., additional, Rodríguez-Rosales, M. D. J., additional, and Valencia-Vázquez, R., additional

Published

2019

2. Biochemical methane potential of residual biomass for energy generation.

Author

Galván-Arzola, U., Moreno-Medina, C. U., Lucho-Chigo, R., Rodríguez-Rosales, M. D. J., and Valencia-Vázquez, R.

Subjects

BIOMASS energy, SWINE manure, METHANE, HEAT of combustion, ANAEROBIC digestion, METHANE as fuel

Abstract

World's energy consumption has doubled in the last four decades, this demand has been covered by the usage of fossil fuels; which are an important source of greenhouse gases emissions, entailing climate change. An efficient less polluting management alternative is the anaerobic digestion (AD) process which generates biogas derived from organic matter. The methane contained at the biogas is considered a biofuel that can generate electricity and heat through its combustion. Biochemical Methane Potential (BMP) essays are standardized methodologies carried out to estimate the energy potential of an organic residue. After performing a BMP test for 13 residual biomass samples, it can be concluded that fresh livestock rumen and manure were the best substrates to generate higher biogas yields; ranging from 1119–1669 ml/g VSadded, with high methane content (65%4<77%) doubling the results reported at literature (≈550 ml biogas/g VSadded). Results indicate that energy potential of these residual biomasses can be increased 23–25% by improving management (freshness) and environmental (higher temperature) conditions and, by reducing the nutrimental deficiencies (mineral medium) of microorganisms. Fresh swine manure also produced large volumes of biogas (1150 ml biogas/g VSadded); however, average methane content ranged 50–65% CH4 v/v. The rest of the residual biomasses produced biogas and methane yields within the normal ranges (≈550 ml biogas/g VSadded); meaning that also can be used as substrate for bioenergy generation. Residues from aquaculture and fish based-industry produced low quantities of biogas (<250 ml biogas/g VSadded; CH4 < 20%); therefore, these cannot be recommended as substrates for bioenergy purposes. [ABSTRACT FROM AUTHOR]

Published

2021

3. Enhanced stabilisation of municipal solid waste in bioreactor landfills

Author

Valencia Vázquez, R., Wageningen University, H.J. Gijzen, and H.J. Lubberding

Subjects

bioreactoren, vaste afvalstoffen, huisvuilverwijdering, solid wastes, Environmental Technology, bioreactors, landfills, municipal refuse disposal, Milieutechnologie, septic tank effluent, stortterreinen, septic tankafvalwater

Abstract

The increasing development and urbanization of the society has led to an increase per-capita production of municipal solid waste (MSW) materials. These MSW materials are of organic and inorganic nature that can be of rapidly, moderately and slowly biodegradable or inert characteristics. With regard to these waste streams a wide variety of treatments exist: reuse and recycling, composting, anaerobic digestion, incineration, and land disposal are the most common ones, pyrolysis and gasification are in use to a lesser extent or on a smaller scale. Regardless of the method chosen for treatment all these methods produce residues, which will be eventually disposed at open dumps or sanitary landfills. Sanitary landfills are engineered facilities that make use of barriers to isolate the waste from the biosphere in order to protect human health and the environment. However, these barriers will fail in the long-term allowing the intrusion of moisture into the waste mass, which will trigger restrained physical, chemical and biological processes causing pollution in the form of leachate and landfill gas. In order to minimise the negative impacts of landfilling of waste, researchers conducted experiments, which resulted today in the so-called bioreactor landfill approach. The bioreactor landfill is a system that is operationally influenced to promote synergy between the inherent microbial consortia, and is controlled to accelerate the sequential phases of waste stabilisation through the addition of liquids and/or air. These past investigations have allowed the determination of optimal ranges for the key process parameters and the implementation of alternative operational conditions, the so-called enhancement techniques. Two main perspectives can be identified: 1) the American perspective, which attempts to apply enhancement techniques in order to maximise landfill gas production; 2) the European perspective that focus on the achievement of the Final Storage Quality (FSQ) status of residues within a generation timeframe (30 years). The term FSQ suggests that the potential of a waste material to produce pollution is reduced to nearly zero in the long-term perspective, similar to the characteristics for inert waste laid in the Waste Acceptance Criteria (WAC) of the European Landfill Directive. Until now, the main technical problem faced by landfill operators is homogenous liquid addition and distribution (key enhancement technique) within the waste mass. The main objective of this thesis was to achieve a FSQ status of waste, through laboratory and pilot-scale experiments, that complies with the WAC of the Landfill Directive for Inert waste, which had been considered as the worstcase scenario due to the stringent criteria established. Therefore, this thesis focused on the interaction and modification of the factors controlling the waste stabilisation process in order to have a better understanding of the physical, chemical and biological processes occurring in a bioreactor landfill.Bench (1 L), laboratory (50 L) and pilot-scale (800 L) simulators were used to apply different combinations of enhancement techniques (shredding. buffer addition, septage addition, and forced air intrusion) in order to achieve FSQ of residues. In addition, coarse materials (as layers or homogenous mixtures) were used in order to improve the hydraulic conditions of the simulators. The results of these experiments revealed that it was possible to achieve biological stabilisation within 1 year, but not FSQ status. Achievement of FSQ status depends strongly on the initial solid waste composition. Nevertheless, the residues were close to comply with the WAC of the Landfill Directive for inert waste. Buffer and septage addition proved to have a positive impact on the waste stabilisation process, reducing the biogas production lag-phase. Additionally, the risks associated with septage disposal were practically eliminated as no faecal coliforms were detected after 1 year of operation. Also the use of coarse materials had a positive impact on the waste stabilisation process, especially as homogenous mixtures and layers to a lesser extent since they were prone to clogging. Nitrogen compounds, especially ammonium, have been identified as a main parameter that will jeopardise the achievement of FSQ status, hence the safe closure of landfill sites. Therefore, evolution and fate of nitrogen compounds were also investigated in this thesis. The experiments showed that about 40% of the total ammonium was released by physical processes within 24 hours; the other 60% was produced by biological degradation of proteins contained in the MSW. Anammox bacteria were found for the first time in bioreactor landfills and it was suspected to have an important contribution to the total removal of nitrogen from the system, beside other nitrogen removal processes. Nevertheless, it was not clear how or where the intermediate products (i.e. nitrite) necessary for Anammox metabolism were produced.The Landfill Degradation and Transport (LDAT) model was used to simulate the evolution of carbon and nitrogen compounds. The LDAT model was not suitable to represent accurately the processes occurring in the simulators mainly because the model operated at a fixed (20ºC) process temperature and the waste chemistry equations need to be improved. Other models found in literature could be more appropriate to describe these processes; however, it was noticed that these models lack a complete ionic balance which has great influence on the pH of the system. The experimental research emphasised the importance of increasing pH values to neutral pH values, which “triggered” most of the processes in the simulators. This thesis highlighted the need to focus future modelling efforts on the integration of this complete ionic balance and its influence on the development of neutral (even alkaline) pH levels.In conclusion, this research reduced our current gaps-in-knowledge and offered feasible technical alternatives to control and steer the processes occurring in a bioreactor landfill aiming to achieve FSQ status of residues

Published

2008

4. Enhanced stabilisation of municipal solid waste in bioreactor landfills

Author

Gijzen, H.J., Lubberding, H.J., Valencia Vázquez, R., Gijzen, H.J., Lubberding, H.J., and Valencia Vázquez, R.

Abstract

The increasing development and urbanization of the society has led to an increase per-capita production of municipal solid waste (MSW) materials. These MSW materials are of organic and inorganic nature that can be of rapidly, moderately and slowly biodegradable or inert characteristics. With regard to these waste streams a wide variety of treatments exist: reuse and recycling, composting, anaerobic digestion, incineration, and land disposal are the most common ones, pyrolysis and gasification are in use to a lesser extent or on a smaller scale. Regardless of the method chosen for treatment all these methods produce residues, which will be eventually disposed at open dumps or sanitary landfills. Sanitary landfills are engineered facilities that make use of barriers to isolate the waste from the biosphere in order to protect human health and the environment. However, these barriers will fail in the long-term allowing the intrusion of moisture into the waste mass, which will trigger restrained physical, chemical and biological processes causing pollution in the form of leachate and landfill gas. In order to minimise the negative impacts of landfilling of waste, researchers conducted experiments, which resulted today in the so-called bioreactor landfill approach. The bioreactor landfill is a system that is operationally influenced to promote synergy between the inherent microbial consortia, and is controlled to accelerate the sequential phases of waste stabilisation through the addition of liquids and/or air. These past investigations have allowed the determination of optimal ranges for the key process parameters and the implementation of alternative operational conditions, the so-called enhancement techniques. Two main perspectives can be identified: 1) the American perspective, which attempts to apply enhancement techniques in order to maximise landfill gas production; 2) the European perspective that focus on the achievement of the Final Storage Quality (FSQ) status

Published

2008

5. Low-performance diagnosis of covered anaerobic lagoons as a waste management strategy in the intensive dairy industry.

Author

Galván-Arzola U, Valencia-Vázquez R, Gómez-González R, Alcalá-Rodríguez MM, Loredo-Medrano JÁ, García-Balandrán EE, and Rivas-García P

Abstract

Covered anaerobic lagoons (CALs) are Latin America's main livestock waste treatment systems. Mexico has 680 CALs that present low biogas yields (0.05 m 3 m -3 digester d -1 ) and low COD removal rates (< 60%). This work focused on diagnosing CAL´s low performance in dairy farms by determining and analyzing operational parameters. Seven CALs located in the main dairy basin of Mexico were analyzed. The sampling areas for each CAL were the supernatant, the active zone, settled sludge, and digester inlet and outlet. The variation of the process parameter values corroborated that CALs appeared stratified and not working as expected. The sludge zone, comprising 50-58% of total solids content and 1-15% of total CALs volume, showed an elemental compounds content suitable for organic fertilizer (340, 48, and 5 kg t -1 of C, N, and S, respectively). However, this zone contained, at least, 85% of the slowly hydrolysable material; the methanogenic potential was less than 87 mL CH 4 g VS -1 , and the C/N ratio ranged from 4.9 to 17, outside of the optimal range. The biogas produced did not exceed 60% of methane content and more than 3000 ppm of H 2 S. The sludge zone significantly influences the lagoon's dynamics since it is a nutrient sink. Furthermore, the lack of agitation is the leading cause for the low energy yield and the low removal of organic matter rate. This work provides valuable information to address the operational problems within the CALs improving our understanding that shall allow proposing reactivation alternatives.

Published

2024

6. Anaerobic co-digestion of fruit and vegetable waste: Synergy and process stability analysis.

Author

Miramontes-Martínez LR, Rivas-García P, Albalate-Ramírez A, Botello-Álvarez JE, Escamilla-Alvarado C, Gomez-Gonzalez R, Alcalá-Rodríguez MM, Valencia-Vázquez R, and Santos-López IA

Subjects

Anaerobiosis, Animals, Bioreactors, Cattle, Digestion, Fruit, Vegetables

Abstract

Anaerobic mono- and co-digestion of fruits and vegetable waste (FVW), slaughterhouse waste (SHW), and cattle manure (CM) under mesophilic conditions (35°C) were conducted through biochemical methane potential tests to investigate how the FVW in a co-substrate formulation improves the methane yield, the degradative synergy between substrates, and especially the stability of the process. The co-digestion of FVW:SHW and FVW:CM were evaluated with volatile solids (VS) ratios of 1:2, 1:1, and 2:1. The results indicated that the highest synergistic effect was found in the co-digestion FVW:CM at 1:1 VS ratio. However, the co-digestion FWV:SHW at 1:2 VS ratio increased the methane yield by 74.2% compared to the mono-digestion of FVW (776.3 mL CH 4 g VS added -1 ). As a critical condition in these processes, the stability was evaluated using the early warning indicator VFA/TA (volatile fatty acids/total alkalinity). The co-substrate SHW promotes greater stability in methane production as the soluble carbohydrate content in FVW increases. It was proposed that the high protein (49.04 ± 0.96% VS) and ammonia content (693 ± 3 mg L -1 ) of SHW leads to the formation of a dampening system known as a carbonate-acetic buffer. It was concluded that balanced distribution between carbohydrates, proteins, and lipids is crucial to increase methane yields, and the low methane productions were associated with low N-NH 4 + concentrations (FVW:CM co-digestions). The results obtained in this study can serve as a basis to design full-scale digesters under similar operating conditions and with the same substrate:co-substrate relationships. Implications : The production of methane from the anaerobic digestion process of food, and lose waste presents a viable alternative of valorization and could help to mitigate environmental impacts. However, anaerobic digestion from these substrates carries high instabilities and low methane yields. The need to increase these yields and contribute to process stability must be considered in the selection of a co-substrate. In this context, this work aims to evaluate the best fruits and vegetable waste: co-substrateformulation, that promotes higher methane yield, a synergy between substrates, and to improve the AD process stability in the presence of perturbations in the substrate composition. We believe that our results could be helpful for the design processes for methane production from fruit and vegetable waste, to contribute to competitiveness with conventional energies and promote the sustainability of these processes.

Published

2021

7. Utilization of Agave durangensis leaves by Bacillus cereus 4N for polyhydroxybutyrate (PHB) biosynthesis.

Author

Martínez-Herrera RE, Alemán-Huerta ME, Flores-Rodríguez P, Almaguer-Cantú V, Valencia-Vázquez R, Rosas-Flores W, Medrano-Roldán H, Ochoa-Martínez LA, and Rutiaga-Quiñones OM

Subjects

Agave microbiology, Bacillus cereus growth & development, Biotechnology, Calorimetry methods, Carbon metabolism, Fermentation, Hydrogen metabolism, Nitrogen metabolism, Plant Leaves metabolism, Spectroscopy, Fourier Transform Infrared methods, Waste Products economics, Agave metabolism, Bacillus cereus metabolism, Hydroxybutyrates chemistry

Abstract

Lignocellulosic wastes may provide a means to economize polyhydroxybutyrate (PHB) production. This study has proposed the use of Agave durangensis leaves obtained from the artisanal mezcal industry as a novel substrate for this aim. Results revealed an increase in PHB biosynthesis (0.32 g/L) and improvement in %PHB (16.79-19.51%) by Bacillus cereus 4N when A. durangensis leaves used as carbon source were physically pre-treated by ultrasound for 30 min (ADL + US30') and thermally pre-treated (ADL + Q). Chemical analyses and SEM studies revealed compositional and morphological changes when A. durangensis leaves were physically pre-treated. Also, elemental analysis of growth media showed that carbon/nitrogen ratios of 14-21, and low nitrogen, hydrogen, and protein content were well-suited for PHB biosynthesis. Confocal microscopy revealed morphological changes in the bacterial cell and carbonosome structure under the influence of different substrates. Finally, Fourier transform infrared spectroscopy (FTIR) and differential scanning calorimetry (DSC) analyses showed that homopolymeric PHB with a high thermal-resistance (271.94-272.89 °C) was produced. Therefore, the present study demonstrates the potential use of physically pre-treated A. durangensis leaves to produce PHB. These results promote the development of a circular economy in Mexico, where lignocellulosic wastes can be employed to produce value-added biotechnological products., Competing Interests: Declaration of competing interest None., (Copyright © 2021 Elsevier B.V. All rights reserved.)

Published

2021

8. Knowledge and technology transfer to improve the municipal solid waste management system of Durango City, Mexico.

Author

Valencia-Vázquez R, Pérez-López ME, Vicencio-de-la-Rosa MG, Martínez-Prado MA, and Rubio-Hernández R

Subjects

Conservation of Natural Resources, Humans, Methane analysis, Mexico, Private Sector, Recycling, Solid Waste analysis, Technology Transfer, Waste Disposal Facilities, Cities, Refuse Disposal methods

Abstract

As society evolves its welfare level increases, and as a consequence the amount of municipal solid waste increases, imposing great challenges to municipal authorities. In developed countries, municipalities have established integrated management schemes to handle, treat, and dispose of municipal solid waste in an economical and environmentally sound manner. Municipalities of developing and transition countries are not exempted from the challenges involving municipal solid waste handling, but their task is not easy to accomplish since they face budget deficits, lack of knowledge, and deficiencies in infrastructure and equipment. In the northern territory of Mexico, the municipality of Durango is facing the challenge of increased volumes of waste with a lack of adequate facilities and infrastructure. This article analyses the evolution of the municipal solid waste management of Durango city, which includes actions such as proper facilities construction, equipment acquisition, and the implementation of social programmes. The World Bank, offering courses to municipal managers on landfill operation and waste management, promoted the process of knowledge and technology transfer. Thereafter, municipal authorities attended regional and some international workshops on waste management. In addition they followed suggestions of international contractors and equipment dealers with the intention to improve the situation of the waste management of the city. After a 15-year period, transfer of knowledge and technology resulted in a modern municipal solid waste management system in Durango municipality. The actual system did not reach the standard levels of an integrated waste management system, nevertheless, a functional evaluation shows clear indications that municipality actions have put them on the right pathway., (© The Author(s) 2014.)

Published

2014