Energy Efficiency in Arkansas, Louisiana, Oklahoma, and Texas' Industrial Pump Systems
Energy Efficiency in Arkansas, Louisiana, Oklahoma, and Texas' Industrial Pump Systems
This report analyzes energy efficiency potentials and their cost-effectiveness in industrial pump systems in Arkansas, Louisiana, Oklahoma, and Texas, separately.
Pages: 68 | Figures: 26 | Tables: 20
File format: PDF
Publication date: October 2017
Research Director: Ali Hasanbeigi, Ph.D.
Global Efficiency Intelligence, LLC.
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Industrial electric motors account for over 70% of electricity consumption in manufacturing in the U.S. Motors are used to drive pumps, fans, compressed air systems, material handling, processing systems and more. Industrial motor systems represent a largely untapped cost-effective source for energy savings that could be realized with existing commercialized technologies. Pump systems are widely used throughout manufacturing industries. In many industrial facilities, pumps are among the highest electricity consuming equipment. Inefficiencies in pump systems are common.
One of the major barriers to effective policy making and increased action by states and utilities to improve energy efficiency in industrial pump systems is the lack of information and data on the magnitude and cost-effectiveness of the energy savings potential in industrial pump systems in each state. This lack of information creates an obstacle to developing a comprehensive and effective strategy, roadmap, and programs for improving pump systems efficiency cost-effectively. It is far easier to quantify the incremental energy savings of substituting an energy-efficient motor for a standard motor than it is to quantify the energy conservation of applying other energy efficiency and system optimization practices to an existing pump system.
Global Efficiency Intelligence, LLC. conducted a large initiative to study industrial motor systems in 30 states from different U.S. regions. This includes the top 20 U.S. states in terms of industrial energy consumption. We focused on industrial pumps, pumps, and compressed-air systems which together account for over 70% of electricity use in U.S. industrial motor systems.
This report by Global Efficiency Intelligence, LLC. focuses on analyzing energy use, energy efficiency, and CO2 emissions-reduction potential in industrial pump systems in selected West South Central U.S. States of Arkansas, Louisiana, Oklahoma, and Texas. We have also published similar reports for industrial fan systems and compressed air systems for these states.
Now that states have different programs to set targets, including passing legislation to enact formal energy efficiency resource standards, setting long-term energy savings targets through utility commissions tailored to each utility, or incorporating energy efficiency as an eligible resource in renewable portfolio standards (RPS), investment in energy efficiency in industrial pump systems to tap into the huge saving potentials quantified in this report can help utilities to meet their targets, reduce their greenhouse gas emissions, and thereby help with climate change mitigation.
In addition, energy efficiency in industrial motor systems stimulates economic growth and creates jobs in a variety of ways (direct, indirect, and induced jobs creation). Investment in energy efficiency creates more jobs per dollar invested than traditional energy supply investments. Energy efficiency in industrial motor systems also creates more jobs in the local economy, whereas energy supply jobs and investment dollars often flow outside the state.
Key analyses and results included:
- Electricity use by manufacturing subsector (NAICS code 31-33) in each state studied
- Electricity use for motor systems and pump systems by manufacturing subsector (NAICS code 31-33) in each state studied
- Electricity use by industrial pump systems by size in each state studied
- Market barriers to energy efficiency in industrial motor and pump systems
- Energy Efficiency Cost Curves for industrial pump systems for each state using eight major energy efficiency measures
- Energy saving potential and cost of conserved energy (US$/MWh-saved) for each efficiency measures in each state studied
- The cost-effective and total technical energy efficiency potential in industrial pump systems in each state studied
- Energy saving potential for each energy efficiency measure by system size
- GHG emissions reduction potential for each efficiency measure in each state
- Sensitivity of the results with respect to changes in electricity prices and discount rates
- Implications for markets, utilities, and policy makers
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Who should read this report?
- Utilities
- Government energy and environmental agencies
- State regulators and policy makers
- Energy Service Companies (ESCOs)
- Demand Response (DR) service and technology providers
- Energy management service and technology providers
- Motor, pumps, and pump systems service and technology providers
- Energy efficiency equipment vendors
- Climate and environmental NGOs and think tanks
- Investor community
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Table of Contents
Executive Summary
1. Introduction
2. Market Barriers to Energy Efficiency in Motor and Pump Systems
3. Energy Use in Industrial Motor and Pump Systems in each State, by Manufacturing Subsector
3.1. Industrial Electricity Use in each State by Manufacturing Subsector
3.2. Industrial Motor Systems Electricity Use in each State by Manufacturing Subsectors
3.3. Electricity Use in Industrial Pump Systems in each State by Manufacturing Subsectors
3.4. Electricity Use in Pump Systems in each State by System Size
4. Energy Efficiency Potential and Cost in Industrial Pump Systems in each State
4.1. Energy-Efficiency Cost Curve for Industrial Pump Systems in Arkansas
4.2. Energy-Efficiency Cost Curve for Industrial Pump Systems in Louisiana
4.3. Energy-Efficiency Cost Curve for Industrial Pump Systems in Oklahoma
4.4. Energy-Efficiency Cost Curve for Industrial Pump Systems in Texas
4.5. Sensitivity Analyses
5. Summary and Implications for Markets, Utilities, and Policy Makers
5.1. Summary
5.2. Implications for Markets, Utilities, and Policy Makers
Appendices
Appendix 1. List of acronyms
Appendix 2. List of Figures and Tables
Appendix 3. Methodology and Scope of the Study
Appendix 4. Bibliography and References
Appendix 5. Related Reports from Global Efficiency Intelligence, LLC.
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List of Figures
Figure 1. Global total final electricity use by end use in 2014
Figure 2. Electric motor systems energy use profile
Figure 3. Final electricity consumption in motor-driven systems in the IEA’s New Policies and 450 Scenarios
Figure 4. Illustration of two industrial electric motor-driven systems: (a) normal and (b) efficient
Figure 5. A typical pump system
Figure 6. Industrial electricity use by manufacturing subsector (NAICS code 31-33) in Arkansas in 2015
Figure 7. Industrial electricity use by manufacturing subsector (NAICS code 31-33) in Louisiana in 2015
Figure 8. Industrial electricity use by manufacturing subsectors (NAICS code 31-33) in Oklahoma in 2015
Figure 9. Industrial electricity use by manufacturing subsector (NAICS code 31-33) in Texas in 2015
Figure 10. Share of motor systems from total electricity use in manufacturing in Arkansas, Louisiana, Oklahoma, and Texas in 2015
Figure 11. Estimated industrial pump systems electricity use by manufacturing subsectors (NAICS code 31-33) In Arkansas in 2015
Figure 12. Estimated industrial pump systems electricity use by manufacturing subsectors (NAICS code 31-33) In Louisiana in 2015
Figure 13. Estimated industrial pump systems electricity use by manufacturing subsectors (NAICS code 31-33) In Oklahoma in 2015
Figure 14. Estimated industrial pump systems electricity use by manufacturing subsectors (NAICS code 31-33) In Texas in 2015
Figure 15. Estimated industrial pump systems electricity use by system size in Arkansas in 2015
Figure 16. Estimated industrial pump systems electricity use by system size in Louisiana in 2015
Figure 17. Estimated industrial pump systems electricity use by system size in Oklahoma in 2015
Figure 18. Estimated industrial pump systems electricity use by system size in Texas in 2015
Figure 19. Energy Efficiency Cost Curve for industrial pump systems in Arkansas
Figure 20. Comparison of energy saving potential (GWh/yr) for each efficiency measure in Arkansas when each measure is implemented in isolation or is implemented along with other measures
Figure 21. Energy Efficiency Cost Curve for industrial pump systems in Louisiana
Figure 22. Comparison of energy saving potential (GWh/yr) for each efficiency measure in Louisiana when each measure is implemented in isolation or is implemented along with other measures
Figure 23. Energy Efficiency Cost Curve for industrial pump systems in Oklahoma
Figure 24. Comparison of energy saving potential (GWh/yr) for each efficiency measure in Oklahoma when each measure is implemented in isolation or is implemented along with other measures
Figure 25. Energy Efficiency Cost Curve for industrial pump systems in Texas
Figure 26. Comparison of energy saving potential (GWh/yr) for each efficiency measure in Texas when each measure is implemented in isolation or is implemented along with other measures
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List of Tables
Table 1. Industrial pump system electricity-savings potential in five West South Central U.S. states in 2015
Table 2. Share of motor systems and pump systems electricity use in each U.S. manufacturing subsector
Table 3. Industrial motor systems electricity use by manufacturing subsectors (NAICS code 31-33) for each state studied in 2015
Table 4. Share of pump systems from total electricity use in manufacturing and from industrial motor systems electricity use in each state in 2015
Table 5. Cumulative annual electricity saving and CO2 emission reduction potential for efficiency measures in industrial pump systems in Arkansas ranked by final CCE
Table 6. Total annual cost-effective and technical energy saving and CO2 emissions reduction potential in industrial pump systems in Arkansas
Table 7. Cumulative annual electricity saving potential for efficiency measures in industrial pump systems in Arkansas by system size (GWh/yr)
Table 8. Cumulative annual electricity saving and CO2 emission reduction potential for efficiency measures in industrial pump systems in Louisiana ranked by final CCE 31
Table 9. Total annual cost-effective and technical energy saving and CO2 emissions reduction potential in industrial pump systems in Louisiana
Table 10. Cumulative annual electricity saving potential for efficiency measures in industrial pump systems in Louisiana by system size (GWh/yr)
Table 11. Cumulative annual electricity saving and CO2 emission reduction potential for efficiency measures in industrial pump systems in Oklahoma ranked by their final CCE
Table 12. Total annual cost-effective and technical energy saving and CO2 emissions reduction potential in industrial pump systems in Oklahoma
Table 13. Cumulative annual electricity saving potential for efficiency measures in industrial pump systems in Oklahoma by system size (GWh/yr)
Table 14. Cumulative annual electricity saving and CO2 emission reduction potential for efficiency measures in industrial pump systems in Texas ranked by their final CCE
Table 15. Total annual cost-effective and technical energy saving and CO2 emissions reduction potential in industrial pump systems in Texas
Table 16. Cumulative annual electricity saving potential for efficiency measures in industrial pump systems in Texas by system size (GWh/yr)
Table 17. Sensitivity analyses for the cost-effective electricity saving potentials in the industrial pump systems with different discount rates
Table 18. Sensitivity analyses for the cost-effective electricity saving potentials in the industrial pump system with different electricity price
Table 19. Total annual technical energy saving and CO2 emissions reduction potential in industrial pump systems in the studied states
Table 20. Policies driving customer-funded energy-efficiency programs