1,721,225 research outputs found
An Approach for the Responsible Design of the Packaging Employed in Household Appliances
No full textThe packaging is responsible for the production of a great amount of waste in the world. Every product comes with different levels of packaging to protect the product during shipping, store the content in the warehouse, and show the product to customers in retail shops. Therefore, the designer of packaging is more and more involved in a responsible analysis while defining the package configurations for a product. This paper proposes an approach to support the packaging configurations considering life cycle data, analytical structural analysis, and parametric cost modeling. Rules, formulas, and specific standards are formalized into a Knowledge Base. As a case study, the methodological approach has been applied to design the packaging of a household appliance. The results show the possibility to reduce the cost and environmental impacts of packaging by a responsible approach
Virtual Prototyping Tools and Methods to Evaluate the Thermal Behaviour of a Li-Ion Battery for EV/PHEV
No full textA methodological approach for supporting the thermal design of Li-ion battery for customized electric vehicles
No full textAn important issue in the mechanical industry is the reduction of the time to market, in order to meet quickly the customer needs. This goal is very important for SMEs that produce small lots of customized products. In the context of greenhouse gas emissions reduction, vehicles powered by electric motors seem to be the most suitable alternative to the traditional internal combustion engine vehicles. The market of customized electric vehicles is a niche market suitable for SMEs. Nowadays, the energy storage system of an electric vehicle powertrain consists of several Li-ion cells arranged in a container called battery pack. Particularly, the battery unit is considered as the most critical component in electric vehicle, because it impacts on performance and life cycle cost. Currently, the design of a battery pack mostly depends on the related market size. A longer design time is expected in the case of a large scale production. While a small customized production requires more agility and velocity in the design process. The proposed research focuses on a design methodology to support the designer in the evaluation of the battery thermal behavior. This work has been applied in the context of a customized small production. As test case, an urban electric light commercial vehicle has been analyzed. The designed battery layout has been evaluated and simulated using virtual prototyping tools. A cooling configuration has been analyzed and then prototyped in a physical vehicle. The virtual thermal behavior of a Li-ion battery has been validated at the test bench. The real operational conditions have been analyzed reproducing several ECE-15 driving cycles and many acceleration runs at different load values. Thermocouples have measured the temperature values during the physical experiments, in order to validate the analytical thermal profile evaluated with the proposed design approach
A virtual prototyping approach based on DOE analysis to support the design of a centrifugal impeller
No full textA modular optimization method based on a multi-DOE approach proposed for a centrifugal impeller
No full textNowadays, design processes need of agile and flexible tools and methods to meet market needs and Ecodesign directive in the industry of household appliances. Virtual prototyping techniques are widespread in design processes and practices, in order to reduce the project development lead-time and the cost related to any real physical prototyping. The aim of this paper is the study of a generic modular approach to support the optimization process of simple mechanical parts using virtual prototyping tools and a multi-DOE solving analysis based on virtual experiments. The target is to increase flexibility in design phases. The research context regards the optimization of a blower for cooker hood applications, in order to improve the fluid dynamic efficacy indicator in accordance with EU Ecodesign directive regarding ventilation fans. The increasing of fluid dynamic efficiency is a way to reduce electrical energy consumption during blower operation. Particularly, this paper focuses on the design optimization of an impeller for kitchen hood. The research-work takes into account the optimization of the blade profile. Inlet and outlet fluid-blade angles have been analyzed and discussed. The methodology proposes the study of a set of geometrical parameters through an analysis based on DOE scheduling with virtual experiments. The proposed test case provides a study of two different fan wheel models for the same hood application. Three geometrical parameters have been considered. The DOE objective function fits the maximization of the fluid dynamic efficiency indicator, in order to reduce energy consumptions. A multi-DOE approach has been used to evaluate the best configuration set. Several CFD simulations have been conducted and the resultant impeller configuration has been also validated through physical tests
Analyzing the environmental sustainability of packaging for household appliances: A test case
No full textNowadays, packaging represents around 35% of the total municipal solid waste yearly generated. This paper aims at analyzing a methodology to support the redesign of a sustainable packaging for the household appliances. The approach considers the environmental impacts related to geometrical parameters and materials. In particular, here the test case is focused on the packaging for kitchen hoods. Through the proposed method, based on the use of virtual prototyping tools, an eco-design approach has been identified to analyze the main environmental impacts. A packaging redesign has been performed to reduce waste and increase the use of the components from the perspective of the circular economy. This study has been performed in accordance with the international standards ISO 14040/14044, by using a Life Cycle Assessment (LCA) from Cradle to Gate. The integration with a CAD tool has been considered to redefine the packaging shape, materials, and internal composition, keeping the same standard requirements (performance, security, etc.). LCA software SimaPro 8.5 has been used to carry out the life cycle assessment, and ReCiPe method has been chosen for the life cycle impact assessment (LCIA). A comparison has been proposed between a traditional packaging for household appliances and a new solution which integrates an interior part in molded pulp. The results show the possibility to cut down the environmental impacts of approximately 15% by a redesign with a molded pulp interior and avoiding EPS structures
Modeling and thermal simulation of a PHEV battery module with cylindrical LFP cells
No full textGenerally a part of electric vehicle diffusion is still based on marketing of cars and vans suitable for specific use like work vehicles. A flexible design methodology is required to support rapid prototyping and product customization in the market of tailored EV/PHEV. The research focuses the cooling simulation for a PHEV Li-Ion battery. The thermal analysis is based on the physical parameters of the single cell and on the experimental data. The proposed methodology concerns firstly an analytical approach which evaluates the average heat generated by a single cell during working condition. Then the proposed virtual prototyping analysis has been divided into two levels: the thermal simulation of one cell, and the CFD analysis of a battery module. This workflow has been applied to support the design of a battery pack for a prototypal ecological hybrid vehicle. That test case vehicle is a small van, used for the curbside collection, which has in parallel an internal combustion engine and an electric motor supplied by a LFP battery with small cylindrical cells. The analysis concerns one of the four module which constitutes the whole battery pack. The virtual model has been parameterized and the behavior of air cooling system has been evaluated through virtual tools
A virtual modelling of a hybrid road tractor for freight delivery
No full textThe market of the hybrid electric vehicles has been increasing for several years. Different commercial EV and PHEV solutions are available for passenger cars and light vehicles for freight deliveries. However, the market of heavy trucks still regards traditional ICE vehicles powered by diesel oil fuel. The recent interest for electric solutions have been pushing the development of the hybrid solutions, but only micro-hybrid systems are considered feasible for heavy truck applications. The proposed research aims to define a methodological approach with a virtual model in order to simulate the behavior of a hybrid heavy truck. The scope of this research is the feasibility analysis of a retrofit hybrid heavy truck. A real driving cycle has been used in order to obtain reliable results in terms of cost, energy consumption and gas emission. The layout of the hybrid system has been proposed as well as the sizing of battery and electric motor. A commercial tool has been used for the vehicle modelling and simulation. As a test case, an 18-ton truck has been analyzed with a 10-liter diesel engine. Firstly, the simulation of the diesel truck has been reproduced considering the real driving cycle data. Secondly, the simulation activity has been focused on the evaluation of the hybrid system behavior by investigating different battery sizes with the same boundary conditions related to the real driving cycle
Analytical thermal model for characterizing a Li-ion battery cell
No full textIn a scenario of small and customized production of electric vehicle, it is important to set methods and tools to evaluate the Li-Ion cells heat source in EV battery. The main problem of the new lithium batteries is represented by the need to keep the battery packs at uniform and constant temperatures and avoid peaks of temperatures which cause degradation of performance and safety problem. The main issue concerns the characterization of a thermal model to calculate the heat generated by electrochemical reactions in a single battery cell. In order to achieve this objective, electrical tests have been conducted to obtain the parameters such as voltage curves, open circuit voltage, and capacity for different type of Li-Ion cells and different rate of current in charge and discharge. During experiments, the use of an IR camera allows to acquire real temperature data under working conditions. These tests concern one cell per time, analyzed in natural convection condition at constant external temperature. The heat generation is evaluated solving the analytical thermal formula which depends on the current rate. The approach has been validated comparing the calculated temperature values with experimental data. The proposed methodology allows to determine the heat generated and temperature for different working condition
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