Comparative Assessment of Energy Consumption and CO2 Emission

Low-carbon transport system is desired for sustainable cities. The study aims to compare carbon footprint of two transportation modes in campus transit, bus and bike-share systems, using life-cycle assessment (LCA). A case study was conducted for the four-campus (College Ave, Cook/Douglass, Busch, Livingston) transit system at Rutgers University (New Brunswick, NJ). The life-cycle of two systems were disaggregated into four stages, namely, raw material acquisition and manufacture, transportation, operation and maintenance, and end-of-life. Three uncertain factors—fossil fuel type, number of bikes provided, and bus ridership—were set as variables for sensitivity analysis. Normalization method was used in two impact categories to analyze and compare environmental impacts. The results show that the majority of CO2 emission and energy consumption comes from the raw material stage (extraction and upstream production) of the bike-share system and the operation stage of the campus bus system. The CO2 emission and energy consumption of the current campus bus system are 46 and 13 times of that of the proposed bike-share system, respectively. Three uncertain factors can influence the results: (1) biodiesel can significantly reduce CO2 emission and energy consumption of the current campus bus system; (2) the increased number of bikes increases CO2 emission of the bike-share system; (3) the increase of bus ridership may result in similar impact between two systems. Finally, an alternative hybrid transit system is proposed that uses campus buses to connect four campuses and creates a bike-share system to satisfy travel demands within each campus. The hybrid system reaches the most environmentally friendly state when 70% passenger-miles provided by campus bus and 30% by bike-share system. Further research is needed to consider the uncertainty of biking behavior and travel choice in LCA. Applicable recommendations include increasing ridership of campus buses and building a bike-share in campus to support the current campus bus system. Other strategies such as increasing parking fees and improving biking environment can also be implemented to reduce automobile usage and encourage biking behavior.

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Strategies and scenarios to reduce energy consumption and CO2 emission in the urban, rural and sustainable neighbourhoods

Sustainable Cities and Society ◽

10.1016/j.scs.2021.103053 ◽

2021 ◽

pp. 103053

Author(s):

Modeste Kameni Nematchoua ◽

Mahsan Sadeghi ◽

Sigrid Reiter

Keyword(s):

Energy Consumption ◽

Co2 Emission ◽

Urban Rural ◽

Reduce Energy Consumption

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Pulp and Paper Industry: Decarbonisation Technology Assessment to Reach CO2 Neutral Emissions—An Austrian Case Study

Energies ◽

10.3390/en14041161 ◽

2021 ◽

Vol 14 (4) ◽

pp. 1161

Author(s):

Maedeh Rahnama Mobarakeh ◽

Miguel Santos Silva ◽

Thomas Kienberger

Keyword(s):

Energy Consumption ◽

Co2 Emissions ◽

Emission Reduction ◽

Co2 Emission ◽

Manufacturing Industry ◽

Paper Industry ◽

Heat Pumps ◽

Pulp And Paper ◽

Low Carbon ◽

Co2 Emission Reduction

The pulp and paper (P&P) sector is a dynamic manufacturing industry and plays an essential role in the Austrian economy. However, the sector, which consumes about 20 TWh of final energy, is responsible for 7% of Austria’s industrial CO2 emissions. This study, intending to assess the potential for improving energy efficiency and reducing emissions in the Austrian context in the P&P sector, uses a bottom-up approach model. The model is applied to analyze the energy consumption (heat and electricity) and CO2 emissions in the main processes, related to the P&P production from virgin or recycled fibers. Afterward, technological options to reduce energy consumption and fossil CO2 emissions for P&P production are investigated, and various low-carbon technologies are applied to the model. For each of the selected technologies, the potential of emission reduction and energy savings up to 2050 is estimated. Finally, a series of low-carbon technology-based scenarios are developed and evaluated. These scenarios’ content is based on the improvement potential associated with the various processes of different paper grades. The results reveal that the investigated technologies applied in the production process (chemical pulping and paper drying) have a minor impact on CO2 emission reduction (maximum 10% due to applying an impulse dryer). In contrast, steam supply electrification, by replacing fossil fuel boilers with direct heat supply (such as commercial electric boilers or heat pumps), enables reducing emissions by up to 75%. This means that the goal of 100% CO2 emission reduction by 2050 cannot be reached with one method alone. Consequently, a combination of technologies, particularly with the electrification of the steam supply, along with the use of carbon-free electricity generated by renewable energy, appears to be essential.

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Energy-Saving and CO2-Emissions-Reduction Potential of a Fuel Cell Cogeneration System for Condominiums Based on a Field Survey

Energies ◽

10.3390/en14206611 ◽

2021 ◽

Vol 14 (20) ◽

pp. 6611

Author(s):

Kazui Yoshida ◽

Hom B. Rijal ◽

Kazuaki Bohgaki ◽

Ayako Mikami ◽

Hiroto Abe

Keyword(s):

Power Generation ◽

Energy Consumption ◽

Fuel Cell ◽

Energy Saving ◽

Electric Power ◽

Water Use ◽

Co2 Emission ◽

Contribution Rate ◽

Electric Power Generation ◽

Cogeneration System

A residential cogeneration system (CGS) is highlighted because of its efficient energy usage on both the supplier and consumer sides. It generates electricity and heat simultaneously; however, there is insufficient information on the efficiency according to the condition of usage. In this study, we analysed the performance data measured by the home energy management system (HEMS) and the lifestyle data of residents in a condominium of 356 flats where fuel cell CGS was installed in each flat. The electricity generated by CGS contributed to an approximately 12% reduction in primary energy consumption and CO2 emission, and the rate of generation by the CGS in the electric power demand (i.e., contribution rate) was approximately 38%. The electricity generation was mainly affected by the use of electricity up to 4 MWh/household/year. Gas or water use also impacted electric power generation, with water use as the primary factor affecting the contribution rate. Electric power generation changes monthly, mainly based on the water temperature. From these results, we confirmed that a CGS has substantial potential to reduce energy consumption and CO2 emission in condominiums. Thus, it is recommended for installation of fuel cell CGS in existing and new buildings to contribute to the energy-saving target of the Japanese Government in the residential sector.

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Assessing the effects of fuel energy consumption, foreign direct investment and GDP on CO2 emission: New data science evidence from Europe & Central Asia

Fuel ◽

10.1016/j.fuel.2021.123098 ◽

2022 ◽

Vol 314 ◽

pp. 123098

Author(s):

Muhammad Mohsin ◽

Sobia Naseem ◽

Muddassar Sarfraz ◽

Tamoor Azam

Keyword(s):

Foreign Direct Investment ◽

Energy Consumption ◽

Central Asia ◽

Direct Investment ◽

Co2 Emission ◽

Data Science ◽

Science Evidence

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Modeling and Analysis of Coal-Based Lurgi Gasification for LNG and Methanol Coproduction Process

Processes ◽

10.3390/pr7100688 ◽

2019 ◽

Vol 7 (10) ◽

pp. 688 ◽

Cited By ~ 1

Author(s):

Gu ◽

Yang ◽

Kokossis

Keyword(s):

Energy Consumption ◽

Natural Gas ◽

Methanol Synthesis ◽

Co2 Emission ◽

Value Added ◽

Economic Benefits ◽

Liquefied Natural Gas ◽

Utilization Efficiency ◽

Separation Unit ◽

Gas Removal

A coal-based coproduction process of liquefied natural gas (LNG) and methanol (CTLNG-M) is developed and key units are simulated in this paper. The goal is to find improvements of the low-earning coal to synthesis natural gas (CTSNG) process using the same raw material but producing a low-margin, single synthesis natural gas (SNG) product. In the CTLNG-M process, there are two innovative aspects. Firstly, the process can co-generate high value-added products of LNG and methanol, in which CH4 is separated from the syngas to obtain liquefied natural gas (LNG) through a cryogenic separation unit, while the remaining lean-methane syngas is then used for methanol synthesis. Secondly, CO2 separated from the acid gas removal unit is partially reused for methanol synthesis reaction, which consequently increases the carbon element utilization efficiency and reduces the CO2 emission. In this paper, the process is designed with the output products of 642,000 tons/a LNG and 1,367,800 tons/a methanol. The simulation results show that the CTLNG-M process can obtain a carbon utilization efficiency of 39.6%, bringing about a reduction of CO2 emission by 130,000 tons/a compared to the CTSNG process. However, the energy consumption of the new process is increased by 9.3% after detailed analysis of energy consumption. The results indicate that although electricity consumption is higher than that of the conventional CTSNG process, the new CTLNG-M process is still economically feasible. In terms of the economic benefits, the investment is remarkably decreased by 17.8% and an increase in internal rate of return (IRR) by 6% is also achieved, contrasting to the standalone CTSNG process. It is; therefore, considered as a feasible scheme for the efficient utilization of coal by Lurgi gasification technology and production planning for existing CTSNG plants.

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Life cycle energy consumption and CO2 emission of an office building in China

The International Journal of Life Cycle Assessment ◽

10.1007/s11367-011-0342-2 ◽

2011 ◽

Vol 17 (2) ◽

pp. 105-118 ◽

Cited By ~ 90

Author(s):

Huijun J. Wu ◽

Zengwei W. Yuan ◽

Ling Zhang ◽

Jun Bi

Keyword(s):

Life Cycle ◽

Energy Consumption ◽

Co2 Emission ◽

Office Building

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Advanced Energy, Exergy, and Environmental (3E) Analyses and Optimization of a Coal-Fired 400 MW Thermal Power Plant

Journal of Energy Resources Technology ◽

10.1115/1.4048982 ◽

2020 ◽

Vol 143 (8) ◽

Author(s):

Siamak Hoseinzadeh ◽

P. Stephan Heyns

Keyword(s):

Energy Consumption ◽

Power Plant ◽

Environmental Analysis ◽

Thermal Power Plant ◽

Co2 Emission ◽

Environmental Temperature ◽

Thermal Power ◽

Energy Losses ◽

Exergy Destruction ◽

Exergetic Efficiency

Abstract In this article, energy, exergy, and environmental (3E) analysis of a 400 MW thermal power plant is investigated. First, the components of the power plant are examined in terms of energy consumption, and subsequently the energy losses, exergy destruction, and exergetic efficiency are obtained. It is shown that the highest energy losses are in the closed feedwater heaters Nos. 1 and 5 and the boiler with amounts of 7.6 × 10 J/s and 6.5 × 107 J/s, respectively. The highest exergy destruction occurs in the boiler and amounts to 4.13 × 108 J/s. The highest exergetic efficiency is 0.98 and is associated with the closed feedwater heaters Nos. 4 and 8. It is observed that the exergetic efficiency and exergy destruction in the boiler are the primarily affected by changes in the environmental temperature. Furthermore, by increasing the main pressure in the turbine, the load on the power plant is increased, and increasing the condenser pressure reduces the load on the power plant. In an environmental analysis, the production of pollutants such as SO2 production and CO2 emission has been investigated.

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