<?xml version='1.0' encoding='UTF-8'?><rss version='2.0'><channel><title>Volume 13 Number 6 (June )</title>
		<link>http://ijaers.com/</link>
		<description>Open Access international Journal to publish research paper</description>
		<language>en-us</language>
		<date>June </date><item>
		<title>Culture Adaptation and Transformation of Traditional Kashi Kari with Modular Concept</title>
		<description>This
study explores the transformation of Kashi Kari, a traditional architectural
tile art, into contemporary modular fashion. Known for its complex geometric
patterns, structured symmetry, and vibrant color schemes, Kashi Kari has
historically been used in monumental architecture such as tombs, mosques, and
civic buildings. The craft embodies local identity, cultural memory, and
artisanal knowledge, making it a key source of inspiration in modern design
fields. The research examines the integration of Kashi Kari&#039;s traditional
motifs, patterns, and color schemes into modular fashion, characterized by
detachable, reconfigurable, and sustainable clothing components. Drawing
structural and visual inspiration from four architectural landmarks—Shah Mosque
(Iran), Blue Mosque (Turkey), Hassan II Mosque (Morocco), and Blue Mosque of
Mazar-e-Sharif (Afghanistan)—this study analyzes their tile patterns and
signature colors of cobalt blue, turquoise, mustard yellow, and white. The
study demonstrates how modular fashion can preserve cultural heritage while
providing modern functionality and global relevance. By combining traditional
craftsmanship with innovative design, the research aims to bridge the gap
between cultural storytelling and contemporary fashion systems, emphasizing
sustainable design principles.</description>
		<link>http://ijaers.com/detail/culture-adaptation-and-transformation-of-traditional-kashi-kari-with-modular-concept/</link>
		<author>Mahnoor Munir, Dr. Xinhua Li, Simran Khan</author>
		<pdflink>http://ijaers.com/uploads/issue_files/1IJAERS-0520264-Culture.pdf</pdflink>
                
		</item><item>
		<title>A Review of the Manifestations and Coping Strategies of Energy Degradation in Daily Life Based on the Second Law of Thermodynamics</title>
		<description>This study takes the second law of thermodynamics as its theoretical
foundation to deeply analyze the specific manifestations of energy degradation
in daily life and systematically explore coping strategies. By combining
literature review with theoretical analysis, we investigate the mechanisms of
energy degradation in fields such as household appliances, transportation,
energy conversion, and ecosystems. The research reveals that energy degradation
is ubiquitous in all aspects of daily life; its essence is the irreversible
transformation process of energy revealed by the second law of thermodynamics.
This phenomenon not only leads to reduced energy utilization efficiency but is
also closely related to energy waste and environmental thermal pollution. To
delay energy degradation, comprehensive strategies are proposed at three
levels: technological, behavioral, and systemic. These strategies aim to
improve energy utilization efficiency and contribute to achieving the goals of
carbon peaking and carbon neutrality. This study holds significant importance
for deepening public understanding of the laws of energy degradation and
promoting the popularization of scientific energy-saving concepts.</description>
		<link>http://ijaers.com/detail/a-review-of-the-manifestations-and-coping-strategies-of-energy-degradation-in-daily-life-based-on-the-second-law-of-thermodynamics/</link>
		<author>Ber-Lin Zhou, Yan-Zuo Chang , Zi-Feng Dai, Tian-Lin Zhang, Ming-Shen Huang, Hai-yu Liu, Jia-xu Lin</author>
		<pdflink>http://ijaers.com/uploads/issue_files/2IJAERS-0620263-AReview.pdf</pdflink>
                
		</item><item>
		<title>Industrial Waste Heat Recovery and Heat Pump System Integration: A Critical Review</title>
		<description>Amid global energy restructuring toward
low-carbon development and the steady advancement of China’s dual-carbon
strategic layout, industrial energy consumption consistently occupies a high
proportion in total social energy usage. Mass quantities of low-grade residual
heat generated during industrial production are directly discharged without
effective recycling, which not only creates massive energy wastage but also
aggravates regional greenhouse gas pollution and environmental load. By
upgrading heat pump thermal utilization technologies, low-temperature
low-quality residual heat can be captured and upgraded into high-grade heat
medium suitable for factory production, which has become a core technical route
to realize industrial energy conservation, carbon emission reduction and graded
exploitation of residual heat resources. This paper comprehensively sorts out
domestic and overseas existing research findings plus practical engineering
examples, and conducts systematic reviews on full-chain core technologies
linking industrial residual heat recycling and heat pump matching integration.
Relevant research progress is classified from five dimensions including
residual heat inherent properties, heat pump working principles, system
matching schemes, core component technologies and multi-industry practical
applications. The paper objectively summarizes existing technical bottlenecks,
divergent academic viewpoints and blank research fields of current
technologies. Combined with relevant industrial policy orientation, the paper
further forecasts the development trend of high-temperature heat pump
equipment, digital intelligent linkage and multi-energy complementary
integrated technologies. Relevant research conclusions can provide theoretical
reference and practical guidance for efficient recycling of industrial residual
heat and low-carbon upgrading of manufacturing industries.</description>
		<link>http://ijaers.com/detail/industrial-waste-heat-recovery-and-heat-pump-system-integration-a-critical-review/</link>
		<author>Ze-Yang Chen, Yan-Zuo Chang, Shun-Tian Huang, Zi-Shuo Liu, Hong-Yi Chen, Geng-Wen Cai, Hong-Fei Wu, Lin-Tao He, Zheng-Bo Hou</author>
		<pdflink>http://ijaers.com/uploads/issue_files/3IJAERS-0620265-Industrial.pdf</pdflink>
                
		</item><item>
		<title>Cavitation Flow Mechanisms and Fluid Dynamics Optimization Trends in Small Water Pumps</title>
		<description>Small centrifugal pumps are core basic equipment for fluid transport, waste heat circulation, and cooling systems in energy and power engineering. Consequently, internal cavitation flow represents the most prominent fluid dynamics problem restricting their efficiency, stability, and service life. More precisely, cavitation is a typical gas liquid two phase unsteady flow phenomenon involving complex physical mechanisms such as liquid vaporization, bubble growth, shedding, collapse, and the evolution of multiscale vortex structures. It is evident from industrial statistical data that approximately 30% of small pump failures are directly or indirectly related to cavitation, efficiency reductions caused by cavitation can reach 20% to 40%, and severe cavitation erosion can shorten impeller life by more than 50%. This paper therefore provides a systematic and rigorous review of the current application status of fluid dynamics theory and numerical simulation methods in cavitation mechanism analysis, flow loss identification, and structural optimization. From this review, several important conclusions can be drawn naturally and appropriately hybrid RANS LES models can improve flow resolution accuracy in cavitation regions by 30% to 50% compared with conventional URANS models in strongly curved flow passages deep learning based vibration acoustic signal recognition methods have already achieved diagnostic accuracy above 95% for incipient cavitation and a lightweight Vision Transformer model achieves 100% recognition accuracy for eight cavitation states under multi noise environments with a single inference time of only 15.4 milliseconds. However, it is undeniable that clear and prominent research bottlenecks still remain in this field turbulence cavitation coupling models have insufficient capability in capturing cross scale vortex structures, multi field coupled simulation systems are not yet mature, the cavitation evolution law under variable operating conditions lacks quantitative description, and the intelligence level of optimization design needs to be improved. Accordingly, the future development trends are very clear cross scale refined CFD simulation, construction of multi field coupling systems, precise optimization for energy saving and loss reduction based on entropy production theory, and intelligent simulation optimization with deep integration of fluid dynamics and artificial intelligence. This paper provides excellent theoretical reference value for hydraulic performance optimization, cavitation suppression design, and high efficiency energy saving renovation of small fluid power equipment.</description>
		<link>http://ijaers.com/detail/cavitation-flow-mechanisms-and-fluid-dynamics-optimization-trends-in-small-water-pumps/</link>
		<author>Shi-da Zhang, Yan-Zuo Chang, Zi-An Wang, Yu-Xuan Chen, Zhen-Ming Chen, Xiao-Feng Zhu, Shu-Wei Huang, Gao-Xiong Xie, Jun-Cai Xie</author>
		<pdflink>http://ijaers.com/uploads/issue_files/4IJAERS-0620264-Cavitation.pdf</pdflink>
                
		</item><item>
		<title>A Review on Key Technologies of Central Air Conditioning: Compressors, Heat Recovery, and AI-Driven Control</title>
		<description>In recent years, the central air conditioning
industry has seen extensive technological advances, covering compressor
technology, system energy efficiency optimization, intelligent control and
other fields. Breakthroughs have been achieved in energy-saving technologies
including magnetic levitation compressors, variable and wide-frequency operation
modes, integrated heat pump and heat recovery systems, as well as independent
temperature and humidity control. In terms of intelligent control, AI-enabled
load forecasting, online optimization and digital twin technology have also
made remarkable progress. Meanwhile, the replacement of environmentally
friendly refrigerants and the trend of copper reduction in materials are
steadily advancing, exerting profound impacts on the industrial supply chain.
Relevant research indicates an obvious integration of two technical routes:
continuous improvement of hardware energy efficiency, and in-depth integration
of intelligent control technologies into systems. This dual transformation is
upgrading products from standalone units to system-level solutions, and shifting
business models from one-time equipment sales to long-term operation and
maintenance services. However, the intersection of technological development
also brings challenges, such as difficulties in implementing standards for
high-efficiency machine rooms, generalization deviations of AI algorithms in
actual building scenarios, and complex renovation demands in the existing
market. This paper also prospects the potential paths of technological
evolution.</description>
		<link>http://ijaers.com/detail/a-review-on-key-technologies-of-central-air-conditioning-compressors-heat-recovery-and-ai-driven-control/</link>
		<author>Tao-Ze Huang, Yan-Zuo Chang, Gui-Fan Chen, Chang-Bin Chen, Yu-Cong Luo, Huhao, Yan-Lin Zhang, Jia-Lin Liu, Wen-Min Wen</author>
		<pdflink>http://ijaers.com/uploads/issue_files/5IJAERS-0620266-AReview.pdf</pdflink>
                
		</item><item>
		<title>A Study on the Current Status of Green Energy Development in the Context of Dual-Carbon Goals</title>
		<description>Whether the green energy transition can be successfully implemented directly determines the realization of the dual carbon goals. This paper reviews relevant domestic research from 2010 to 2025, employing a framework of timeline technology classification problem dimension. The study period is divided into two phases the scale expansion phase from 2010 to 2020, and the system integration phase from 2020 to 2025. Within each phase, the analysis is further organized from three perspectives power generation technology, energy storage, and market mechanisms. The review reveals that before 2020, research primarily focused on reducing the costs of new energy and expanding its scale, with development largely driven by policy subsidies. Following the introduction of the dual carbon goals, scholarly attention shifted toward system level issues, including the integration of grid connected renewable power, the underutilization of installed energy storage capacity, and the coupling between electricity markets and carbon markets. Several controversies persist in the academic community, such as whether the phenomenon of storage built but not used is temporary or structural, what role nuclear power should play in the new energy system, and what standards should be adopted to measure energy system costs. In addition, existing research has several notable limitations slow data updating, an overemphasis on the power sector while neglecting industrial heat supply, the nascent stage of research on the impacts of extreme weather events, and the masking of inter provincial differences by aggregated average data. Future research should place greater emphasis on empirical analysis of high penetration renewable power systems, quantification of supply demand matching for long duration energy storage, the coupling mechanisms among multiple markets, and the enhancement of energy system resilience under extreme weather conditions.</description>
		<link>http://ijaers.com/detail/a-study-on-the-current-status-of-green-energy-development-in-the-context-of-dual-carbon-goals/</link>
		<author>Peng Wang, Yan-Zuo Chang, Jun-Gang Lai, Guo-Feng Li, Xu-Lin Ouyang, Xin-Fu Zeng, Peng-Cheng Shu, Hong-Rui Yang, De-Jiang Zhang</author>
		<pdflink>http://ijaers.com/uploads/issue_files/6IJAERS-0620267-AStudy.pdf</pdflink>
                
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