This study aims to establish a market efficiency baseline for ACs in Indonesia.
This collaborative study explored ways for energy efficiency programs to achieve greater savings in the industrial sector.
This report presents an analysis of the cost and benefit of improving efficiency of air conditioners in India, based on a bottom-up engineering analysis of key AC components such as compressors and heat exchangers.
This report includes updates from the recorded achievements in EESL programs published in 2015.
Rebound effects have been the subject of intense debate in the field of energy efficiency policy for many years. In the past, the focus of this debate has been on the perceived loss of the expected energy savings and related benefits resulting from the rebound effects. However, more recently, there has been a growing recognition that policymakers need to consider the health, economic and other non-energy benefits that often result from the increase in energy services represented by user “rebound effects”. This Policy Brief, prepared by Lawrence Berkeley National Laboratory, presents an overview of the rebound effect phenomenon.
This guide is designed to be read as a “Motors” annex to the CLASP Monitoring, Verification and Enforcement (MVE) Guide (CLASP, 2010), with Figure 1 (overleaf) showing the structured approach to creating a CC&E programme taken from this MVE guide.
This program evaluation aimed to analyze the impacts on Mexican consumers and the national economy from energy efficiency standards on residential refrigerators and window air conditioners that were aligned, or “harmonized” with U.S. standards in the early 2000s.
A new report developed in collaboration with the SEAD Initiative, the International Energy Agency (IEA) Implementing Agreement on Energy Efficient End-Use Equipment (4E) outlines the historic achievements of energy efficiency standards and labeling programs.
This paper uses LBNL (Lawrence Berkeley National Laboratory)’s BUENAS (Bottom-Up Energy Analysis System) model to forecast demand reductions from energy efficiency in a major developing country – Indonesia. The resulting analysis finds that peak load may increase 3 times in Indonesia over the next 20 years in the business-as-usual case, primarily driven by space cooling with an important component from lighting and refrigerators. Applying BUENAS efficiency scenarios of cost-effective potential and best available technology indicates a potential peak load reduction of 13% and 37% in 2030, respectively.