- Open Access
- Total Downloads : 622
- Authors : P.Kumar , Dr. N. Mohan Das Gandhi
- Paper ID : IJERTV2IS110219
- Volume & Issue : Volume 02, Issue 11 (November 2013)
- Published (First Online): 13-11-2013
- ISSN (Online) : 2278-0181
- Publisher Name : IJERT
- License: This work is licensed under a Creative Commons Attribution 4.0 International License
Green Manufacturing in Foundry
P.Kumar 1 & Dr. N. Mohan Das Gandhi 2 1.Assistant Professor, Dept of Mechanical Engg,
Nehru Institute of Engineering & Technology, Coimbatore. Tamilnadu. India.
2. Principal, Kalaignar Karunanidhi Institute of Technology, Coimbatore. Tamilnadu. India.
Abstract
In this paper introduce a Green Manufacturing in foundry. A number of initiatives are being taken by companies in India in the areas of regulation and reduction of green house gases, discharge of pollutants and emissions, hazardous waste management, and energy conservation to pave the way for a cleaner and greener environment for sustainable development. Manufacturers are able to save costs on the final product by reducing energy and materials wastes. Beyond good business, a
green manufacturing program benefits the environment and creates value for the customer. Three major model of advanced green systems are Green Management System (GMS), Green Waste Reduction Techniques (GWRT) and Green Results (GR). This paper will target reducing traditional lean wastes along with energy and material wastes in metal casing facilities and study was undertaken to estimate the pollutants released from the foundries.
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INTRODUCTION
Green Manufacturing is generically defined as elimination of waste by re- defining the existing production process or system. We have all come across company examples that take their problem solving approach to the next level and develop innovative techniques towards effective solutions. Such solutions result in cost savings from reduced work handling, effluent control, process automation, etc. All these efforts are applications of green manufacturing.
Green Manufacturing addresses process redundancy, ergonomics and cost implications due to faulty methods of producing goods. Faster and cheaper are no longer the only two criteria in manufacturing a product or evaluating an existing process line. Several other factors such as materials used in manufacture, generation of waste, effluents and their treatment (or possible elimination), life of the product and finally, treatment of the product after its useful life are all important considerations.
Green Manufacturing organizations manufacturing products using materials and processes that minimize negative environmental impact, help in the reduction of green house gases (GHGs), conserve energy and natural resources, improve safety for consumers, communities and employees and at the same time increase profitability of their organizations as a whole.
Globalisation impacts and its associated demands in competitive environment have created a need for managers in manufacturing sectors to take decisive actions, responsive to environmental changes, and implement strategies that continually improve quality, capability and process efficiency. The efficiency in continually improving the quality of products and its processes could be seen in term of cost reduction, improvement of customer satisfaction as well as minimize the environmental
impacts. One key principle of Lean production is the reduction of wasted materials and labor in a continuously improving culture. To see if Lean companies naturally tend to be Green, known Lean manufacturers were surveyed to determine if they were transcending to a more Green state as a result of their commitment to Lean production. Variables in the study were numerous, including measures of Green Management System, Green Waste Reducing Techniques, and Green Results as first defined by Melnyk, et al. This makes a very powerful statement that Lean companies are embracing Green objectives and suggests that Lean manufacturers are transcending to Green manufacturing as a natural extension of their culture of continuous waste reduction, integral to world class Lean programs.
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LITERATURE SURVEY
Product Redesign
Product Redesign
The survey instrument developed and tested by Melnyk, et. al. [5] was adapted for use in this study. Consistent with the three main manufacturing system components, the survey has three sections (GMS, GWRT, and GR). The first section of the survey (GMS) addresses the status and maturity of the plants environmental management system implementation. The second section (GWRT) is comprised of fourteen questions regarding specific practices the plant undertakes to reduce environmental waste. The third section (GR) is comprised of ten questions that address the process and business results of Green manufacturing efforts in the plant. The survey questions align directly with the Green dependent variables shown in the Advanced Green System Model in Figure 1. Details of the survey construction and validation are beyond the scope of this short paper, but may be found in Bergmiller [1].
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PROPOSED MODEL OF ADVANCED GREEN SYSTEMS
Significant agreement amongst researchers shows there are three major components to a theoretical model of Green Operations Systems . Top management commitment comes in the form of Green Management Systems (GMS) with policies and procedures empowering employees to make decisions based on reduced environmental impact.This commitment is the beginning point in establishing Green organizations. GMS will support an organizational culture that identifies sources of environmental wastes and implements Green Waste Reduction Techniques (GWRT) designed to reduce the types and amounts of environmental wastes generated by the companys operations. The implementation of GWRTs leads to improvements in business metrics of Green Results (GR). The Advanced Green System Model [3], which is developed from several leading theories, is reproduced here in Figure 1,2 and 3. The figure shows the individual elements comprising the GMS, GWRT, and GR.
GREEN MANAGEMENT SYSTEMS
Environmental Management
Environmental Management
ISO14001Certified
ISO14001Certified
Figure 1: Green Management Systems
GREEN WASTE REDUCTION TECHNIQUES
Process Redesign
Process Redesign
Disassembly
Disassembly
Substitution
Substitution
Reduce
Reduce
Recycling
Recycling
Remanufacturing
Remanufacturing
Consume Internally
Consume Internally
Prolong use
Prolong use
Returnable Packaging
Returnable Packaging
Spreading Risks
Spreading Risks
Creating Markets
Creating Markets
Waste Segregation
Waste Segregation
Alliances
Alliances
Figure 2: Green Waste Reduction Techniques
GREEN BUSINESS RESULTS
Costs
Costs
Lead Times
Lead Times
Quality
Quality
Market Position
Market Position
Reputation
Reputation
Product Design
Product Design
Process Waste
Process Waste
Equipment
Equipment
Benefits
Benefits
Figure 3: Green Business Results
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CLEANER PRODUCTION SYSTEM
The Asian Productivity Organisation (APO) had introduced the concept of Cleaner Production (CP). CP is a strategy for enhancing productivity and environmental performance for overall socio-economic developments. Productivity provides the framework for Continuous Improvement (CI), while environmental protection provides the foundation for sustainable development.
Figure. 4 Cleaner Production System
The foundation of the CP concepts is to plan, examine, re-evaluate and maintain the production processes to highlight ways of improving productivity, while reducing its environmental impacts through four main actvities or also called as 4Rs (Reuse, Reduce, Recycle and Reproduce), or including other one more R (Recovery). CP means persistent used of industrial processes, raw materials and products designed from their inception to prevent pollution of air, water and land; in order to reduce waste, to minimize the risks of environment and human health, and to make efficient use of raw materials, such as energy, water and space.
Implementation of these concepts leads to another cycle of review or evaluation thus promotes continuous improvement (CI) activities (Parasnis, 2003). CI is a
win-win approach for simultaneously realizing improvements in productivity and environmental protections. Continuous improvement or kaizen activities on the products and processes create substantial opportunities for pollution prevention and waste minimization, product improvement as well as customer satisfaction (Florida, 1996). CP concepts are considered less costly to implement, operate and maintain over time because the CP activities can reduce costs of raw materials, energy, pollution control, waste treatment and clean-up, and continued regulatory compliance . Until the 1990s, the manufacturing sectors were managing its environmental problems almost exclusively through end-of-pipe solutions. By using the end-of-pipe approach, production departments are discharged from all waste responsibility and they avoided closely monitoring and changing the processing area. This research aims to investigate the level of production practices and its activities and implement cleaner production practices and its activities in the foundries.
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DATA ANALYSIS
MELT SAVINGS Never forget that every area of the foundry operation is fertile ground for green savings. Buying the right scrap can net energy savings even before melting materials are received at the foundry. Ferrous foundries have long been comfortable with receiving post consumer steel scrap that contains a moderate amount of surface rust, paint, adhering non-metallics, and other non- steel attachments. Sheared scrap can contain
5 8 % by weight of tramp non- metallic materials. Eliminating the non- metallic materials can yield significant savings.
Further melting savings can be achieved by cleaning gates an risers of sand by passing through a properly designed rotary drum, or for very clean returns, a quick sot blasting of the returns.
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REUSE OF WASTE HEAT Returning
to energy savings, one of the most significant areas for achieving energy reductions is in the reuse of waste heat from many foundry processes. The reuse of waste heat can often net energy savings of 15% to 25% or more. Utilize waste heat from melting operations for building heat, core drying, and/or shower water heating. With prober design, these systems can also use heat pump principles to utilize waste heat for air conditioning or chilling, to maximize the year round benefit of the facilitys investment.
SOME BENEFICIAL REUSE OPTIONS
Non-hazardous and non-dangerous spent sand has traditionally been used as "clean fill" in many parts of Washington State. However, "clean fill" opportunities have declined in recent years, making exploration and implementation of other applications essential. Spent foundry sand has been successfully used throughout the United States in various applications. Below are some recycling options for spent sand:
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Asphalt Concrete: Substitution of up to 15% spentsand for conventional asphalt concrete fine aggregate.
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Compost Additive: Bulking agent for composted yard waste, to produce topsoil or topsoil additive.
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Concrete: Substitution for regular sand in structural grade concrete, at low percentages.
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Bricks and Pavers: Encapsulation in a proprietary, high pressure, pozzolanic process that can encapsulate and chemically bind various waste materials in C-grade flyash (a fine particulate ash produced by coal-burning electrical power plants). The ambient-temperature process results in bricks that are cost effective and can be shaped to meet end-user requirements.
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Portland Cement: Cement kiln feed for Portland cement. A study by the American Foundrymen's Society indicates
that portland cement manufactured with up to 13% of spent foundry sand exhibited slightly higher compressive strengths than conventionally produced portland cement, without any degradation of key characteristics such as set time.
Mineral Wool Products: Potential silica source.
Flowable Fill: Substitution for regular sand in flowable fill, a mixture of sand, flyash, and water thatis mixed into a slurry and poured. Flowable fill is aself-leveling and self-compacting mix that hardens anddevelops strength over time, similar to concrete, and is commonly used as backfill for trenches (sewer, conduit, utility).
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CONCLUSION
Lean system infrastructure serves as a catalyst to the successful implementation of Green best practices and the achievement of corresponding Green Results. The evidence that plants with Lean systems yield higher Green Results. Structural Mortar and concrete can be manufactured with used foundry sand as a partial replacement of natural sand. A suitable recycling of the discarded foundry sand as building construction material could be suggested. The goal is to allow manufacturers to balance environmental concerns with profitability. Attractive incentives to individuals and industries and measures for clean technologies by the government is probably the only way to foster a vibrant green economy.
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REFERENCES
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Gary G. Bergmiller & Paul R. McCright., Lean manufacturers Transcendence to Green Manufacturing, Proceeding of the 2009 Industrial Engineering Research conference. 2009.
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Mohd Nizam Ab Rahman & Hernadewita, Cleaner Production Implementation Towards Environmental Quality Improvement ISSN 1450-216X Vol.30 No.2 (2009), pp.187-194 © EuroJournals Publishing, Inc. 2009.
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Amrinder Singh Chahal & Priyavrat Thareja 2011, Green Foundry Development Through
Casting Simulation and QFD, Indian Foundry Journal vol 57 No 8 August 2011.
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Biegel J.B. Production Planning and Inventory Control, Prentice Hall, New York.1968.
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Gandhi, N.Mohan Das, Selladurai, V., and Santhi, P. Green Productivity Index (GPI) of the Continuous Improvement (CI) in Foundry Casting, Emerald, India.2006.