Energy Use and Efficiency of Rice-Drying SystemsI. On-Farm Cross-Flow Dryer Measurements

Agricultural direct energy use is responsible for about 1–2% of global emissions and is the major emitting sector for methane (2.9 GtCO2eq y−1) and nitrous oxide (2.3 GtCO2eq y−1). In the last century, farm mechanisation has brought higher productivity levels and lower land demands at the expense of an increase in fossil energy and agrochemicals use. The expected increase in certain food and bioenergy crops and the uncertain mitigation options available for non-CO2 emissions make of vital importance the assessment of the use of energy and the related emissions attributable to this sector. The aim of this paper is to present a simulation framework able to forecast energy demand, technological diffusion, required investment and land use change of specific agricultural crops. MUSE-Ag & LU, a novel energy systems-oriented agricultural and land use model, has been used for this purpose. As case study, four main crops (maize, soybean, wheat and rice) have been modelled in mainland China. Besides conventional direct energy use, the model considers inputs such as fertiliser and labour demand. Outputs suggest that the modernisation of agricultural processes in China could have the capacity to reduce by 2050 on-farm emissions intensity from 0.024 to 0.016 GtCO2eq PJcrop−1 (−35.6%), requiring a necessary total investment of approximately 319.4 billion 2017$US.

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Energy use efficiency of on-farm- and post-pineapples production in Nigeria

International Journal of Energy Technology and Policy ◽

10.1504/ijetp.2013.058148 ◽

2013 ◽

Vol 9 (2) ◽

pp. 175

Author(s):

S.O. Jekayinfa ◽

S.O. Afolayan ◽

A. Taiwo ◽

J.O. Popoola

Keyword(s):

Energy Use ◽

Energy Use Efficiency ◽

Use Efficiency ◽

On Farm

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Experimental Investigation of a Lab-Scale, Cross-Flow Grain Dryer for Testing of Drying Efficiency and Characteristic Profiles of a Packed Bed

Volume 2: Photovoltaics; Renewable-Non-Renewable Hybrid Power System; Smart Grid, Micro-Grid Concepts; Energy Storage; Solar Chemistry; Solar Heating and Cooling; Sustainable Cities and Communities, Transportation; Symposium on Integrated/Sustainable Building Equipment and Systems; Thermofluid Analysis of Energy Systems Including Exergy and Thermoeconomics; Wind Energy Systems and Technologies ◽

10.1115/es2015-49057 ◽

2015 ◽

Author(s):

Taylor N. Suess ◽

Michael P. Twedt ◽

Stephen P. Gent

Keyword(s):

Energy Use ◽

Cross Flow ◽

Electric Heating ◽

Packed Bed ◽

Operating Conditions ◽

Heating Process ◽

Air Temperatures ◽

Two Factors ◽

Forced Air ◽

Drying Efficiency

This study investigates the drying mechanisms of corn when it is exposed to air at elevated temperature and velocity within a cross-flow packed bed dryer. A highly-instrumented laboratory-scale experimental test dryer was constructed to batch-dry samples of 0.03 m3 (1 ft3) of high moisture corn. This is achieved using a perforated wall drying chamber with forced air at temperatures ranging from 180–240°F. The high temperature, high velocity air entering the column is supplied by a variable speed fan and a variable Wattage electric heating coil through a 0.09 m2 (1 ft2) square air duct. This device is able to precisely control the drying air temperate and flow rate, while also measuring the temperature and humidity of the air exiting the dryer. In creating and instrumenting this apparatus, tests were performed to analyze both energy use and drying rate to determine the operating conditions that find a balance between energy and time requirements for moisture removal. This study used a variety of supply air temperatures and air flow rates in drying samples of corn at two initial moisture contents (19%MC and 24%MC) to 15%MC. This is done to determine if there are notable differences in energy requirements (Btu/pound water removed) between different operating conditions. This study determined that corn undergoes a significant pre-heating process before peak drying efficiency is achieved. Current grain dryer designs should focus the most energy just after that pre-heating process for highest overall efficiencies. Additionally, this study found an inverse relationship between dry time and energy efficiency, which showed that an optimum balance between those two factors should be identified.

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Two-dimensional simulation model for dynamic cross-flow rice drying

Chemical Engineering and Processing - Process Intensification ◽

10.1016/s0255-2701(01)00117-9 ◽

2001 ◽

Vol 40 (4) ◽

pp. 355-362 ◽

Cited By ~ 10

Author(s):

T.R. Rumsey ◽

C.O. Rovedo

Keyword(s):

Simulation Model ◽

Cross Flow ◽

Two Dimensional ◽

Dimensional Simulation ◽

Rice Drying

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143 Impacts of soil carbon sequestration on life cycle greenhouse gas emissions in midwestern USA beef finishing systems

Journal of Animal Science ◽

10.1093/jas/skz258.302 ◽

2019 ◽

Vol 97 (Supplement_3) ◽

pp. 147-148

Author(s):

Jason Rowntree ◽

Paige Stanley ◽

David Beede ◽

Marcia DeLonge ◽

Michael Hamm

Keyword(s):

Life Cycle ◽

Soil Carbon ◽

Energy Use ◽

Ghg Emissions ◽

C Sequestration ◽

Grazing Impact ◽

Mineral Supplement ◽

Soil C ◽

Continuous Grazing ◽

On Farm

Abstract Using life cycle analysis (LCA), several studies have concluded that grass-finished beef systems have greater GHG intensities than feedlot-finished (FL) beef systems. These studies evaluated only one grazing management system– continuous grazing – and assumed steady-state soil carbon (C), to model the grass-finishing environmental impact. However, by managing for more optimal forage growth and recovery, adaptive multi-paddock (AMP) grazing can improve animal and forage productivity, potentially sequestering more soil organic carbon (SOC) than continuous grazing. To examine impacts of AMP grazing and related SOC sequestration on net GHG emissions, a comparative LCA was performed of two different beef finishing systems in the Upper Midwest, USA: AMP grazing and FL. We used on-farm data collected from the Michigan State University Lake City AgBioResearch Center for AMP grazing. Impact scope included GHG emissions from enteric methane, feed production and mineral supplement manufacture, manure, and on-farm energy use and transportation, as well as the potential C sink arising from SOC sequestration. Across-farm SOC data showed a 4-year C sequestration rate of 3.59 Mg C ha−1 yr−1 in AMP grazed pastures. After including SOC in the GHG footprint estimates, finishing emissions from the AMP system were reduced from 9.62 to −6.65 kg CO2-e kg carcass weight (CW)−1, whereas FL emissions increased slightly from 6.09 to 6.12 kg CO2-e kg CW−1 due to soil erosion. This indicates that AMP grazing has the potential to offset GHG emissions through soil C sequestration, and therefore the finishing phase could be a net C sink. However, FL production required only half as much land as AMP grazing. This research suggests that AMP grazing can contribute to climate change mitigation through SOC sequestration and challenges existing conclusions that only feedlot-intensification reduces the overall beef GHG footprint through greater productivity.

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