Day 3 :
Keynote Forum
Rintu Banerjee
Indian Institute of Technology, India
Keynote: Pilot scale production of 2G ethanol utilizing rice straw: an integrated bio-refinery approach
Biography:
Rintu Banerjee, Ex-MNRE- Chair-Professor, Indian Institute of Technology, Kharagpur has created a niche of her own in the area of Biomass Deconstruction/Biofuel Production/Enzyme Technology. In the process of her innovative development, she was granted 8 Indian, 3 International (US, Japanese and Chinese) patents. She has published more than 150 papers in peer-reviewed national/international journals, guided 27 (17 continuing) Ph.Ds, 3 MS, 71 (3 continuing) M.Techs, 50 (2 continuing) B.Techs. She is the Editorial member of many Journals. She has written 24 book chapters and authored a book on “Environmental Biotechnology” published by Oxford University Press. She is recipient of various awards/honours given by both government/non-government organizations.
Abstract:
The global energy demand has been continuously increased from past decades that caused a scarcity in the supply of crude oil. Globally, research has been shifted from conventional sources to alternative clean and sustainable energy sources. In general, the atmospheric carbon-dioxide was fixed by plants to carbohydrates via photosynthesis and considered as a most abundant lignocellulosic biomass on earth that has significant potential for biofuels generation. The exploitation of lignocellulosic biomass for biofuels production is one of the viable options compared to conventional energy sources such as fossil fuels that ultimately help to reduce the burden on fossil fuels utilization and greenhouse gas emission. Current situation demands the production of cellulosic biofuels to control the energy crisis for betterment of societal needs. The production status of rice straw indicated that approximately 731 million tons of rice straw produced per year globally. The distribution data in Asia is 667.6 million tons, 20.9 million tons in Africa, and 3.9 million tons in Europe. The total carbohydrate content of rice straw was reported to be 49 % and lignin content of 14 %. It is one of the largest lignocellulosic biomass feedstock’s having the capacity to produce 730 billion liters of bioethanol from 731 million tons of rice straw. Major proportion of the rice straw is burnt in the field itself. In practice, rice straw was burned in the open fields that led to air pollution and release of the particulate matter into the atmosphere. In India, surplus amount (23 %) of rice straw is produced every year that constitute 0.05% greenhouse gas emissions through open burning in the field. Thus, rice straw represents one of the viable feedstock candidates for biofuels generation owing to its carbohydrate content that can be converted to fermentable sugar and in turn ethanol. Biomass is the only foreseeable renewable feedstock for sustainable production of biofuels. The main technological barrier to more widespread utilization of this resource is the lack of low-cost technologies to overcome the recalcitrance of the cellulosic structure. Three major biological events occur during conversion of lignocellulose to ethanol via processes featuring biomass pretreatment, enzymatic hydrolysis and fermentation of hexose and pentose sugars. Consolidated biomass processing (CBP) is gaining increasing recognition as a potential breakthrough for low-cost biomass processing. A fourfold reduction in the cost of biological processing and a twofold reduction in the cost of overall processing are projected when a mature CBP process is substituted other fermentation processes. To increase product yields and to ensure consistent product quality, key issues of industrial fermentations, process optimization and scale up are aimed at maintaining optimum and homogenous reaction conditions minimizing microbial stress exposure and enhancing metabolic accuracy. For each individual product, suitable strategies have to be elaborated by a comprehensive and detailed process characterization and identification of the most relevant scale-up parameters influencing the product yield. In the present work, consolidated processing of rice straw of 25Kg batch was carried out for ethanol production. Maximum ethanol 3.01 % (v/v) in liquid broth was obtained whereas, 1.77 % (w/w) was recorded in fermented solid biomass. SEM analysis indicated changes in the surface characteristics. Biomass crystallinity and energy density studies further support the outcome of the process. Techno-economic analysis of the process suggests that if the residual biomass from rice straw is utilized for biomethane and biomanure generation then the process will result a net profit upon per ton of biomass processing.
- Biogas
Location: Berlin
Session Introduction
Jianrong Li
Van Swinden Laboratory (VSL), Netherlands
Title: Progress in developing measurement standards and standardised test methods for biogas and biomethane assessment
Biography:
Jianrong Li is working at the Van Swinden Laboratory (VSL), the Dutch Metrology Institute, as Scientist in the R&D Department. Her work focuses on metrology and gas analysis in the fields of Energy and Environment. Currently Jianrong is coordinating the European joint research project “EMPIR 16ENG05 - Metrology for biomethane” and is leading a Task in “EMPIR 16ENG09 – Metrological support for LNG and LBG as transport fuel” project. In the past, she has led Work Packages and Tasks in several other research projects under the European Metrology Research Programme (EMRP), such as ENG54 Biogas, ENG60 LNG II and ENV56 KEY-VOCs.
Abstract:
Under the Renewable Energy Directive 2009/28/EC, mandate M/475, CEN/PC 408 developed specifications for biomethane (i.e., EN16723). Currently, the test methods cited in EN16723 are neither harmonised nor validated, lack aspects of metrological traceability, and are usually not dedicated to biomethane. Thus, they are hampering the energy transition from natural gas to biomethane and are causing the realisation of the EC’s H2020 goals to be too slow. Regulators, grids and refuelling stations, and testing laboratories urgently require harmonised and validated test methods to enable the transportation of biomethane using existing infrastructure as well as clear financial transactions without disputes. Recently an ISO Working Group for Biomethane has been established, i.e. ISO/TC193/SC1/WG25 Biomethane.
In order to assess conformity with the EN16723 specifications and to provide valuable input to ISO/TC193/SC1/WG25, as the successor project of EMRP ENG54 – Metrology for biogas [1], the European joint research project EMPIR 16ENG05 – Metrology for biomethane [2] aims to develop standardised test methods for the parameters (mainly impurities) to be monitored when injecting biomethane into the natural gas grids and when using it as a transport fuel, for example the content of total silicon and siloxanes, halogenated volatile organic compounds, hydrogen chloride, hydrogen fluoride, ammonia, terpenes, compressor oil and amines in biomethane. A further objective of this work is to develop or improve the measurement standards for these parameters, in order to enable SI traceable calibration and measurement results. For legal purposes, a standardised test method is also needed for determining the fraction of biogenic methane in blends of biomethane and natural gas.
This work will closely liaise with the biogas producing and upgrading industry, regulators and biomethane testing laboratories and other end-users to ensure that the developed test methods are robust and efficient and can readily be implemented.
Latest progress of this work, with focus on results obtained at VSL, will be reported and discussed.
Samudrala Prashant Jeevan Kumar
Indian Institute of Technology, India
Title: Biodiesel production from enzymatically delignified lignocellulosic substrates using oleaginous yeast Trichosporon sp
Biography:
S.P. Jeevan Kumar is pursuing his Ph.D at Indian Institute of Technology, India . His research interests are biodiesel production from oleaginous microbes.
Abstract:
The dramatic increase in demand for transportation fuels coupled with depletion of finite resources and the increased environmental concerns have kindled to search for renewable fuels. Among several renewable fuels, biodiesel is a promising fuel, which is synthesized by transesterification reaction of vegetable oils/animal fats using methanol. On the other hand, exorbitant cost of vegetable oils and succinct supply of animal fats have crippled the development of biodiesel. Oleaginous yeast has the potential to synthesize lipid in significant amounts using lignocellulosic substrates. In the present study, Trichosporon sp. an oleaginous yeast was isolated, identified and evaluated its efficiency to utilize various lignocellulosic substrates that are delignified with laccase. It was observed that 21.45 %(w/w), 20.23 %, 18.82 %, 15.75 %, and 14.80 % of lipid contents were resulted with delignified Ricinus communis, cotton stalk, Lantana camara, Saccharum spontaneum and pineapple leaf waste, respectively. Further, the lipids were subjected to enzymatic transesterification using immobilized lipase and obtained yield of 85.00 % fatty acid methyl esters with oil:methanol ratio 1:15, 10 U of immobilized lipase/g of oil in 36 h at 30 °C of 150 rpm. The fatty acid methyl esters were tested for suitability of fuel properties and found that the iodine value, cetane index, saponification value, acid value and calorific value were within the limits of international standards. These studies signify that the delignified substrates could be used for biodiesel production by oleaginous yeast.