Study of the use of substandard flour as a co-substrate to increase biogas yield-Reference-Cited by-同舟云学术

Study of the use of substandard flour as a co-substrate to increase biogas yield

Published:2021 Issue:13(112) Volume: Page:196-203
ISSN:2707-0751
Container-title:Mehanization and electrification of agricultural
language:uk
Short-container-title:M&EAgri

Author:

Polishchuk V. M.^ORCID,Rogovskii I. L.^ORCID,Shvorov S. A.^ORCID,Derevianko D. A.^ORCID,Dvornik Ye. O.^ORCID,Davidenko T. S.^ORCID

Abstract

Annotation Purpose. Increasing the biogas yield due to the rational mode of manure fermentation with the addition of substandard flour as a co-substrate. Methods. Experiment planning, methods of mathematical statistics. Analytical processing of experimental data. was carried out using the methods of mathematical statistics and probability theory on a computer in Excel and MathCad. Optimization problems were solved using the dichotomy method. Results. In methane fermentation of cattle manure with the addition of wheat flour as a co-substrate, the maximum yield of biogas was observed when adding 2.3% flour to the substrate. If the mass of flour increases to 10.6%  methane fermentation quickly stops. Conclusions. Based on the research, the following results were obtained: • for quasi-continuous loading of the methane tank, the optimal flour content in the substrate is determined, which is 3%; • substantiated recommendations on the rational content of flour in the substrate in the range of 2.3–4%, which provides an increase in biogas yield during fermentation of a mixture of cow manure and flour in 1.5–2 times. Keywords: biogas, cosubstrate, methane tank, gasholder, cattle manure, flour, grain waste, bread waste, experimental researches.

Publisher

National Scientific Center - Institute of Agricultural Engineering and Electrification

Subject

General Medicine

Reference15 articles.

1. 1. (2012). Biogas manual. From receipt to use. Germany, Gülzow-Prützen [in Russian].

2. 2. Eder, B., & Schulz, H. (2006). Biogas plants : practical guide. Moscow : Kolos [in Russian].

3. 3. Lee, H. J., Lee, S. C., Kim, J. D., Oh, Y. G., Kim, B. K., Kim, C. W., & Kim, K. J. (2003). Methane production potential of feed ingredients as measured by in vitro gas test. Asian-Australasian Journal of Animal Sciences, vol. 16, issue 8, 11431150 [in English]. doi: 10.5713/ajas.2003.1143.

4. 4. Alagcan, D. G., Pratap, S. K., Alagcan, M. M., Ginasha, D. R., Tuivavalagi, N. S., & Garg, S. K. (2012). Use of compact biogas plant for biogas production utilizing Waste foodmaterials, fruits, and vegetable peelings of high calorific contents. International Journal of Engineering, Science and Metallurgy, vol. 2, issue 1, 371381 [in English].

5. 5. Acharya, R. C., & Mukundan, U. (2015). Effect of substrate variation on biomethane production at pilot scale. European Journal of Biotechnology and Bioscience, vol. 3, issue 4, 2427 [in English].