Assessment of increasing loading rate on two-stage digestion of food waste

M. A. Voelklein; A. Jacob; R. O' Shea; J. D. Murphy

doi:10.1016/j.biortech.2015.12.001

Assessment of increasing loading rate on two-stage digestion of food waste

M. A. Voelklein
, A. Jacob
, R. O' Shea
, J. D. Murphy

Research output: Contribution to journal › Article › peer-review

Abstract

A two-stage food waste digestion system involved a first stage hydrolysis reactor followed by a second stage methanogenic reactor. Organic loading rates (OLR) were increased from 6 to 15 g VSL^-1d^-1 in the hydrolysis reactor and from 2 to 5 g VSL^-1d^-1 in the methanogenic reactor. The retention time was fixed at 4days (hydrolysis reactor) and 12days (methane reactor). A single-stage digester was subjected to similar loading rates as the methanogenic reactor at 16days retention. Increased OLR resulted in higher quantities of liquid fermentation products from the first stage hydrolysis reactor. Solubilisation of chemical oxygen demand peaked at 47% at the maximum loading. However, enhanced hydrolysis yields had no significant impact on the specific methane yields. The two-stage system increased methane yields up to 23% and enriched methane content by an average of 14% to levels of 71%.

Original language	English
Pages (from-to)	172-180
Number of pages	9
Journal	Bioresource Technology
Volume	202
DOIs	https://doi.org/10.1016/j.biortech.2015.12.001
Publication status	Published - 1 Feb 2016

Keywords

Biogas
Food waste
High performance reactors
Hydrolysis
Two-stage digestion

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10.1016/j.biortech.2015.12.001

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title = "Assessment of increasing loading rate on two-stage digestion of food waste",

abstract = "A two-stage food waste digestion system involved a first stage hydrolysis reactor followed by a second stage methanogenic reactor. Organic loading rates (OLR) were increased from 6 to 15 g VSL-1d-1 in the hydrolysis reactor and from 2 to 5 g VSL-1d-1 in the methanogenic reactor. The retention time was fixed at 4days (hydrolysis reactor) and 12days (methane reactor). A single-stage digester was subjected to similar loading rates as the methanogenic reactor at 16days retention. Increased OLR resulted in higher quantities of liquid fermentation products from the first stage hydrolysis reactor. Solubilisation of chemical oxygen demand peaked at 47\% at the maximum loading. However, enhanced hydrolysis yields had no significant impact on the specific methane yields. The two-stage system increased methane yields up to 23\% and enriched methane content by an average of 14\% to levels of 71\%.",

keywords = "Biogas, Food waste, High performance reactors, Hydrolysis, Two-stage digestion",

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AU - Voelklein, M. A.

AU - Jacob, A.

AU - O' Shea, R.

AU - Murphy, J. D.

PY - 2016/2/1

Y1 - 2016/2/1

N2 - A two-stage food waste digestion system involved a first stage hydrolysis reactor followed by a second stage methanogenic reactor. Organic loading rates (OLR) were increased from 6 to 15 g VSL-1d-1 in the hydrolysis reactor and from 2 to 5 g VSL-1d-1 in the methanogenic reactor. The retention time was fixed at 4days (hydrolysis reactor) and 12days (methane reactor). A single-stage digester was subjected to similar loading rates as the methanogenic reactor at 16days retention. Increased OLR resulted in higher quantities of liquid fermentation products from the first stage hydrolysis reactor. Solubilisation of chemical oxygen demand peaked at 47% at the maximum loading. However, enhanced hydrolysis yields had no significant impact on the specific methane yields. The two-stage system increased methane yields up to 23% and enriched methane content by an average of 14% to levels of 71%.

AB - A two-stage food waste digestion system involved a first stage hydrolysis reactor followed by a second stage methanogenic reactor. Organic loading rates (OLR) were increased from 6 to 15 g VSL-1d-1 in the hydrolysis reactor and from 2 to 5 g VSL-1d-1 in the methanogenic reactor. The retention time was fixed at 4days (hydrolysis reactor) and 12days (methane reactor). A single-stage digester was subjected to similar loading rates as the methanogenic reactor at 16days retention. Increased OLR resulted in higher quantities of liquid fermentation products from the first stage hydrolysis reactor. Solubilisation of chemical oxygen demand peaked at 47% at the maximum loading. However, enhanced hydrolysis yields had no significant impact on the specific methane yields. The two-stage system increased methane yields up to 23% and enriched methane content by an average of 14% to levels of 71%.

KW - Biogas

KW - Food waste

KW - High performance reactors

KW - Hydrolysis

KW - Two-stage digestion

UR - https://www.scopus.com/pages/publications/84949935159

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VL - 202

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JO - Bioresource Technology

JF - Bioresource Technology

ER -

Assessment of increasing loading rate on two-stage digestion of food waste

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Keywords

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